The specialised software dialux will enable the simulation of .... Classrooms,
tutorial rooms. 300. 19. 0.60. 80 .... point of view of evolution, the blue light
signals to ...
EDUCATION AND SCIENCE
EDUCATION AND SCIENCE
PRESENTATION AND RETAIL SHOP, SHOPPING MALL
INDUSTRY AND ENGINEERING, OUTDOOR WORKPLACE
OFFICE AND COMMUNICATION
HOTEL AND GASTRO
ARCHITECTURE, FACADE, CITY MARKETING AND VISUAL PRESENTATion
ROAD, PATH AND SQUARE
HOUSE, FLAT AND LIVING AREA
EDUCATION AND SCIENCE
HEALTH AND CARE
SPORT, LEISURE AND WELLNESS
The visual perception plays a decisive role when we acquire information about the world and how its regularities work. Before we are able to give the things their names and to understand the comprehensiveness of the relations the things are entering, we perceive them through our eyes. Appropriate lighting of the space the educational process is realised in is therefore one of the key factors which play a decisive task during the schooling. The light creates a positive communication atmosphere between the teacher and pupil; it is able to positively affect the concentration ability and performance efficiency of the students, to create such conditions in which both the students and the teachers will feel comfortably and especially is able to ensure the correct perception of the displayed objects and information. Correct lighting at school has a substantial influence on what relation the pupils and students will create to school and if they will like the educational process. The time when children learnt under the light of the paraffin lamps or incandescent bulbs belongs fortunately to the past today.
HEAD OFFICE OMS, spol. s r. o. 906 02 Dojč 419 Slovakia Tel.: +421(0)34/694 0811, 694 0877 Fax: +421(0)34/694 0888 e-mail:
[email protected] www.omslighting.com www.omselite.com
The scientific knowledge about the influence of the light on people and their visual and psychological well-being and the importance of correct space illumination the teaching process is realised in has been implemented to the educational premises at all levels during recent years. Appropriate lighting plays the same important role also for the games in the kindergartens, during teaching the alphabet in the first grades of the basic schools as well as during scientific experiments at higher educational levels. The modern school places increased demands on the lighting solutions today. The strict organisation of the space has made way for the requirement of flexibility. The pupils today do not spend the whole day solving individual tasks at their desks, they work in groups and the desks alter to working islands. The conventional wooden blackboards are replaced by the interactive ones; the paper and pen are replaced by the PC monitors. That is why the lighting solutions have to adjust to these changes. The objective of this publication is to provide comprehensive information about correct space lighting in the educational premises as well as the tools for assessing the quality of the individual lighting systems.
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EDUCATION AND SCIENCE
It is often simple to learn because people’s brains work as incredible sponges which are able to absorb knowledge without limits. But only when we succeed in keeping its cerebral cells open by appropriate education and motivation. Stephen Jay Gould
CONTENT LIGHTING AND HUMAN
CONTENT
8
ergonomics
10
Colour rendering index (CRI)
12
Glare prevention
14
Illumination level
16
Lighting uniformity
18
Harmonious distribution of brightness
20
emotion
26
Biological factor of illumination
27
Availability of daylight
27
Bluelight content
28
Daylight simulation
30
Illumination of room surfaces
32
Emotional lighting
34
ECOLOGY
36
Latest lamp technology
38
System efficacy of luminaire
40
Thermal output of lamp
41
Dangerous material content
42
Product life-time and maintenance costs
42
EFFICIENCY
44
Daylight sensor
46
Constant illuminance sensor
47
Presence detector
48
Calling of lighting scenes
50
ESPRIT
52
EXCEPTIONALITY
54
LIGHT in the SCHOOL
58
CLASSROOM
60
COMPUTER ROOM
68
LeCTURE THEATERs
72
Laboratory and workshop
74
SPORT facilitIES
76
teacher'S room
82
teacher'S OFFICE
83
library
86
Refreshment and canteen
88
corridors and communications
92
SAFETY AND EMERGENCY LIGHTING
kindergarten
96 98
external and parking areas
102
Selecting the right LIGHT SOURCE
104
LED for SCHOOL
106
PRODUCTS
114
4/5
LIGHTING AND HUMAN New order in lighting world When designing the lighting system for the educational premises of all levels the lighting designer has to respect the legal standards as well as many other im-
THE KEY
portant parameters which affect the quality of the overall lighting solution. The
IS
summary of these criteria has been presented by a non-standardised system until recently and it did not provide a sufficient overview. The six-point system of assessing the lighting quality – Lighting Quality Standard – developed by the company OMS is bringing a new order into the chaotic lighting world.
Living by rules is important. Respecting laws is relevant as well. The ancient conflict of our world is driven by patterns and order; otherwise we become adrift by chaos that is present in our civilisation to these days. Whether the former or the latter concept is the right one, is an eternal question. One thing is certain: we in OMS love the order much more than chaos. That is why we have created a brand new lighting quality standard to help the customers, buyers and competitors better understand and evaluate lighting devices and solutions.
We have chosen more than twenty objectively quantifiable criteria and we are using them to evaluate both individual light fixtures and complete lighting solutions for different types of spaces. Each criterion has got its value and the result is the LQS Index. The higher the index is, the better the lighting device or solution is for use in a given space. Simple and intuitive approach to the agenda is exemplified by the LQS Composer, a unique tool to evaluate each and every lighting product.
There is a six-part program behind the acronym LQS. The chapters are named Ergonomics, Emotion, Ecology, Until now there was no unifying system used in the world of light- Efficiency, Esprit and Exceptionality, or just 6 E’s. ing for evaluation of eiher light fixtures or lighting solutions, and If you imagine a house, the first four chapters are strong pillars every producer has got its own way for that. Consumers get lost representing criteria that are well-known in the world of lighting. in the vast array of criteria used, and comparing neither products The remaining two are the roof, a powerful superstructure on the top of these pillars. Together, they create an inseparable complex, nor solution was an option. OMS brings order to this chaos. We because the parts of the whole cannot be perceived indepenare prepared to help the LQS become a unified standard used dently, but only in their context. That is the basic philosophy of by the whole lighting sector. No overstatement, the LQS is an important step to the new level. Not just for our company, but for the LQS. Immerse in the 6 E’s and conceive the idea of living in a place where rules are crystal clear. the branch and the giant world of lighting.
LIGHTING AND HUMAN
ERGONOMICS
6
E efficiency
Examine the impact of light on the human eye.
Take the advantage of innovation in management and control of lighting.
The ability of a light source to reproduce colours of various objects realistically in comparison with ideal or natural light is the master rule in the world of lighting.
There is a lot of possibilities to choose the right interface for a desired effect of illumination. The decision should be made according to the type of space that is to be lit.
EMOTION Uncover the influence of light on human emotions. Strong scientific evidence proves the effect on mood and perception through features such as colour mixing, biologically effective lighting or illumination of room surfaces.
Ecology
esprit Realise that appearence matters and feels not ashamed when considering the design of luminaries. An object’s form of excellent aesthetic value becomes an important part of interior design in an architect’s perspective.
Exceptionality
Control energy consumption and environmental impact of light usage.
Consider every customer as a unique individual.
The ratio of energy converted to light is the measure of light source’s efficacy. This can be used for increasing product‘s life while reducing maintenance costs.
A customised solution adds more value and comfort. Trustworthy partners prepared for an unstable future of the market and the economic system‘s changes are a necessity in the world of lighting.
8/9
ERGONOMICS
Correct lighting in the classroom improves the capability of the pupils to concentrate and makes the educational process more cheerful.
Up to 80 % of all information is perceived through our vision therefore the visual perception plays a decisive role during the educational process. Correct lighting enables the student to perceive the objects and shapes correctly, to acquire information about the space and makes the orientation inside the space easier.
When designing modern educational premises the ergonomic solution of lighting represents one of the most important items. The lighting system which complies with the principles of ergonomics improves the performance efficiency and capability of the pupils, protects the eyes, reduces the risk of injuries and first of all – it makes the process of education more entertainment. The variedness of the educational activities places increased demands on the lighting variability. This fact results in the task of the lighting designer to design the lighting system in such a way that it will comply with every type of activity which will be carried out in the individual spaces. The basic quantities the ergonomics pays attention, to when creating optimal lighting conditions – the colour rendering index, glare prevention, the illumination level, the illumination of the task area and the surrounding of the task area, the lighting uniformity and harmonious distribution of brightness.
ERGONOMICS
10/11
The correct recognition of colours plays a decisive role in the process of learning on all educational levels. Ensuring their correct perception is therefore one of the lighting designer’s key roles. COLOUR RENDERING INDEX
Truewhite technology
light source being tested. The bigger the difference of the truthfulness of reproducing the colour is, the lower the value The correct recognition of of the colour rendering index colours plays a decisive role of the light source tested and in the process of learning its ability to depict truthfully and identifying things on all the objects´ colouring is. From educational levels. At the the practical point of view kindergartens it enables the the colour rendering index is children to call and allocate the colours; at higher educa- one of the most important tional levels it is important in aspects when selecting a light the framework of the artistic source. The European standard EN 12 464-1 determines the subjects but the subjects light sources with the colour of natural sciences as well. rendering index minimally 80 Therefore one of the key for the common classrooms, tasks of a designer when solving the illumination is to for classrooms where special ensure the correct perception subjects are taught and where the emphasis on the correct of colours. recognition of colours (e.g. art The influence of the light source lessons, chemistry, etc.) is laid, the luminaires with CRI 90 and on the appearance of the more are required. colour objects is expressed by the Colour rendering index (CRI) From the point of view of LQS which indicates how truthfully the individual light sources are the highest score is assigned to the light sources with CRI 90 able to copy the colouring of and more. the object compared to the natural daylight. The CRI value of a light source is expressed by the average of the values of the first eight indices R1 – R8 out of The emphasis on correct colour recognition in the educational fifteen colour samples illuminat- process is laid especially in the classrooms where teaching of art ed at first under the reference lessons takes place. The standard light source with the ideal value determines to use the light sources (CRI = 100) and then under the with CRI 90 for here.
Cree TrueWhite® Technology represents a patented method of generating a white light of high quality developed by the company CREE. It is a relatively simple and very effective method where a white light of high quality develops through combining the yellow and red LED module. By implementing this technology to the luminaires with diffuse optics we can acquire pleasant soft light with high colour rendering index – CRI 93, warm colour and excellent efficacy up to 111 lm/W. The Cree TrueWhite® Technology is proof that the LED sources are highly energy-effective and are able to generate light with the quality at the level of the conventional light sources. The company OMS utilises the Cree TrueWhite Technology e.g. for the luminaires GRUMIUM, CYGNUS, CASTOR and in the last product novelty SAIPH.
HIGH EFFICIENCY MIXING CHAMBER • Uniform, Clean Appearance • Soft, Brilliant Light
CREE TRUEWHITE® TECHNOLOGY • Unrivaled 90 CRI and 90-110 lm/W • Beautiful, High Quality Light • Consistent Colour Temperature
LQS VALUE Colour rendering index (CRI) CRI
LQS Value
>90
5
80-90
4
70-80
3
60-70
2
40-60
1
20-40
0
Comparison of colour rendering indices – CRI. Left: CRI 70. Right: CRI 93.
COLOUR RENDERING INDEX
ONE PIECE REFLECTOR • Smooth Visual Transition • Creates a Quiet Ceiling • Optimal Light Distribution
ROOM-SIDE HEAT SINK • Dramatically Improves Performance • Soft, Recessed Indirect Light • Pleasing Architectural Aesthetic
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SAIPH
142
GLARE PREVENTION
LQS VALUE Glare prevention Glare prevention
LQS Value
URG0,3
5
Em(wall)>75 lux with U0>0,3 Em(ceiling>50 lux with U0>0,3
4
Em(wall)>75 lux with U0>0,1 Em(ceiling>50 lux with U0>0,1
3
Em(wall)>50 lux with U0>0,1 Em(ceiling>30 lux with U0>0,1
2
Em(wall)>30 lux with U0>0,1 Em(ceiling>10 lux with U0>0,1
1
Em(wall)0,1 Em(ceiling0,1
0
the ceiling and when the luminaires are placed correctly it ensures also sufficient vertical illuminance of the walls. Such light conditions help orienting in the space and modulating the objects better which is important in the classroom especially from the point of view of safety. The pupils are able to identify the edges of the desks or other obstacles which represent potential danger of injury better and without problems. At the same time thanks to the diffuse light the cylindrical illuminance is improved and it is important for correct recognising of faces. At the minimal level of the cylindrical illuminance 150 lux the faces of the pupils and teachers can be recognised without any disturbing shadows and this fact contributes to creating a pleasant communication atmosphere. The results of the investigation and our experience show that this light solution represents the most ideal and comprehensive method for solving the illumination in the classrooms at all educational levels.
nance 300 lux. These illuminance levels can be achieved by using the suspended luminaires with the direct and indirect characteristic of the luminous flux distribution. The practical experiments carried out by scientists with a group of pupils show that the optimal ratio of the divided direct and indirect component of the luminous flux is 50:50. During these experiments the pupils were to carry out several visual tasks with various demands in the simulated light conditions, e.g. to read a book, to identify the numbers on the board, to copy an image, etc. and they themselves could control the ratio of the direct and indirect component of the luminous flux from the luminaire. The results showed that the most suitable light conditions for realising the visual tasks are when the utilised luminaires with the direct and indirect character of the luminous flux distribution direct 50 % of the light directly downwards to the working plane and 50 % of the diffuse light towards the ceiling.
The uniform brightness distribution in the room where teaching is under way is closely connected with the level of maintained illuminance. The current normative requirements resulting from the standard EN 12464-1 require the minimal illuminance level 300 lux for the classrooms, for the vertical surfaces 50 lux (with the recommended value 75 lux) and for the ceiling 30 lux (with recommended value 50 lux). The extensive investigations of lighting influence on the human eyes proved unambiguously that the stated normative values are insufficient and require The luminaire MODUL LAMBDA extensive examination with special emphasis on the uniform from the OMS portfolio meets these requirements. Thanks to distribution of brightness. its excellent luminous paramThese investigations show that eters it fulfils the requirements on the usage in the classrooms. for achieving the optimal light conditions with a uniform distri- The direct component of the bution of brightness we need to luminous flux emitted by this increase the illuminance of the lighting fixture is able even at vertical surfaces and the ceiling an approximately 2 metre dissubstantially. For the classroom tance from the working plane (desk) to ensure a sufficient space it is recommended to achieve the vertical illuminance illuminance level at the level of the wall surfaces 300 lux and of 500 lux. The indirect diffuse component directly illuminates the horizontal ceiling illumi-
HARMONIOUS DISTRIBUTION OF BRIGHTNESS
Also the selection of the materials used affects the harmonious distribution of brightness in the space. In general we recommend lighter colours. Dark walls, ceiling and furniture have lower brightness compared to the lighter materials and therefore they give a depressing impression.
For the correct modelling of the faces it is important to ensure in the classrooms sufficient cylindrical illuminance amounting 150 lux. The suspended luminaires with the direct and indirect characteristic of the luminous flux distribution which eliminate forming undesirable shadows and at the same time do not cause glare are the optimal solution.
The classical solution of the classroom lighting with recessed luminaires with a parabolic louvre ensures sufficient illumination of the workplace but the upper parts of the walls and the ceiling remain dark. Such illumination causes a feeling of a cave effect and makes the classroom optically smaller.
The sufficient illumination of the ceiling can be achieved by using the luminaire MIRZAM with the direct and indirect characteristic of the luminous flux distribution which is reached thanks to the specially shaped diffuser. The classroom then gives an impression of a lighter and larges space.
The suspended luminaires with the direct and indirect character of the luminous flux distribution which direct 50 % of radiation directly to the task area and 50 % towards the ceiling represent an ideal lighting solution for the classrooms. The required distribution ratio of the direct and indirect component of illumination is achieved by placing the luminaire in the distance of 0.3 to 0.6 metre from the ceiling.
20/21
MODUL LAMBDA MAX 125
MODUL LAMBDA
125
according TO EN 12464-1
Ceiling illumination Dark ceiling, only 100 lux causes cave effect which can even result in depressive claustrophobic feelings of the children.
Illumination on the working surface Direct illumination from the luminaires always gives only 300 lux on the table.
OUR recomMendation
Illumination level on the board
Vertical illumination
Cylindrical illuminance
Good illuminance of the board must fulfil 500 lux and 0.7 uniformity.
Vertical illumination on the wall, 100 lux, provides bad orientation in the room and high value of adaptation luminance.
Cylindrical illumination especially affects visual communication and the ability to interpret faces, events and objects. The standard requires a minimum illuminance of 150 lux in rooms with demands of good visual communication.
Illumination on the working surface Direct illumination from the luminaires always gives 500 lux on the table, to make the visual task easier.
Ceiling illumination
Vertical illumination
Indirect illumiantion on the ceiling, 300 lux, provides good ambient light and pupils who are more alert and perform better.
Vertical illumination on the wall, 300 lux, provides good ambient light and helps pupils feel more alert and better orientation in the room.
The extensive investigations of lighting influence on the human eyes proved that the stated normative values require extensive examination with special HARMONIOUS DISTRIBUTION OF BRIGHTNESS
emphasis on the uniform distribution of brightness.
22/23
Lighting requirements for interior areas, tasks and activities EN 12464-1 Type of area, task or activity
Em [ lux ]
UGR
U 0
CRI
Specific requirements
Nursery school, play school Play room
300
22
0.40
80
High luminances should be avoided in viewing directions from below by use of
diffuse covers.
Nursery
High luminances should be avoided in viewing directions from below by use of
300
22
0.40
80
Handicraft room
300
19
0.60
diffuse covers.
80
Educational buildings Classrooms, tutorial rooms
300
19
0.60
80
Lighting should be controllable.
Classroom for evening classes and adults education 500
19
0.60
80
Lighting should be controllable.
Auditorium, lecture halls
500
19
0.60
80
Lighting should be controllable to accommodate various A/V needs.
Black, green and white boards
500
19
0.70
80
Specular reflections shall be prevented.
Presenter/teacher shall be illuminated with suitable vertical illuminance.
Demonstration table
500
19
0.70
80 In lecture halls 750 lux.
Art rooms
500
19
0.60
80
Art rooms in art schools
750
19
0.70
90
Technical drawing rooms
750
16
0.70
80
Practical rooms and laboratories
500
19
0.60
80
Handicraft rooms
500
19
0.60
80
Teaching workshop
500
19
0.60
80
Music practice rooms
300
19
0.60
80
Computer practice rooms (menu driven)
300
19
0.60
80
Language laboratory
300
19
0.60
80
Preparation rooms and workshops
500
22
0.60
80
Entrance halls
200
22
0.40
80
Circulation areas, corridors
100
25
0.40
80
Stairs
150
25
0.40
80
Student common rooms and assembly halls
200
22
0.40
80
Teachers rooms
300
19
0.60
80
Library: bookshelves
200
19
0.60
80
Library: reading areas
500
19
0.60
80
Stock rooms for teaching materials
100
25
0.40
80
Sports halls, gymnasiums, swimming pools
300
22
0.60
80
School canteens
200
22
0.40
80
Kitchen
500
22
0.60
80
5,000 K < TCP 6,500 K.
VDU-work – See the chapter GLARE PREVENTION (page 14)
See the chapter SPORT FACILITY (page 76)
Em = average illuminance in lux (maintained value) UGR = UGR limit (direct glare limitation) U0 = lighting uniformity CRI = colour rendering index of light sources
Lighting requirements for interior areas, tasks and activities EN 12464-1
12/13
EMOTION
The human eye responds to large continuously illuminated surfaces and the white diffuse light reflected from the ceiling and walls in the best way.
The correct perception of the depicted information has a decisive influence on creating the pupils´ relation to school and learning. The correct and biologically effective light makes their learning simpler and more amusing.
BIOLOGICAL FACTOR OF ILLUMINATION AVAILABILITY OF DAYLIGHT As we have already mentioned in several areas, the scientific research has unambiguously confirmed the positive impact of the natural light on the feeling of the pupils´ visual and psychological well-being, their performance efficiency and the ability to concentrate. The requirement on the availability of the daylight in the spaces determined for education is therefore a rule. The task of the
artificial light is to fulfil an additional function to the daylight. The most important moment when planning the lighting for any space is its correct solution, the type of the luminaires is of secondary importance if the required result can be ensured. However, in general it is valid that the human eye responds to large continuously illuminated surfaces and the white diffuse light reflected from the ceiling and walls in the best way. As a matter of fact, this type of lighting simulates the properties of the daylight most truthfully.
The scientific research during last decades has deeply changed the view at the task of lighting and its effect on people. The light is able to substantially affect not only the ability to perceive but also to change the mood, to arouse the feeling of comfort or vice versa discomfort and to control the human circadian rhythm. All this knowledge has extended the perception of the task of the artificial illumination due to the simple need to illuminate the space by a new dimension – to be biologically effective. When designing the lighting solution at schools it is inevitable to take both requirements equally into account. LQS approaches the lighting of space in a holistic way. It perceives the solution as a whole with the goal to copy the properties of the natural light as trustfully as possible.
EMOTION / BIOLOGICAL FACTOR OF ILLUMINATION / AVAILABILITY OF DAYLIGHT
26/27
Revealing the third type of photoreceptors in the The correct proportion of the blue light in the light spectrum from an artificial source is able to stimulate the performance efficiency and to positively affect the feeling of the students´ as well as teachers´ psychological well-being.
human eye sensitive to the blue part of the light spectrum enabled the developing of biologically effective luminaires. modul ray
123
LQS VALUE Biological factor of illumination Biological factor of illumination
LQS Value
availability of daylight
0/1 (No/Yes)
blue light concent
0/1 (No/Yes)
daylight simulation
0/1 (No/Yes)
dynamic lighting
0/1 (No/Yes)
tunable white
0/1 (No/Yes)
BLUELIGHT CONTENT Revealing the function of the third type of photoreceptors in the human eye being able to affect the production of melatonin, a hormone managing the circadian human cycle belongs among the discoveries of modern science. These receptors are sensitive to that part of the light spectrum with the wavelength of approximately 464 nanometres, i.e. the blue light. This knowledge has become the basis for the manufacturers of the luminaires which through appropriate proportioning the spectrum’s blue part of the artificial illumination and its leading directly to the human eye are able to affect the activities of the individuals effectively. As a matter of fact, from the point of view of evolution, the blue light signals to the human organism if it is day ficiency and affect positively the or night. psychological well-being of the pupils. When implementing the In the spaces with a limited biologically effective luminaires access of daylight, the presence with the blue light component, of the blue light is a key factor it is necessary to take into acwhich significantly contributes count the age of the students to the psychological and visual as the melatonin production well-being of the pupils. Its fluctuates according to their shortage stimulates production hormonal maturity. At an early of melatonin which signals to age, especially in children in the human organism that there the pre-school age melatonin is is time for rest and induces an created also during the morning increased need of sleep. The hours. The proportion of the absence of the blue light in the blue light in the light spectrum spectrum can lead to reduced is subject to changes during the performance efficiency and day – an appropriately planned disrupting the circadian rhythm light solution is able to respond of the human organism. On to this situation by simulating the contrary, its appropriate the daylight. proportion in the light spectrum of the artificial light source can stimulate the performance ef-
Biological factor of illumination
Influence of daylight on the human body 3 a.m.
6 a.m. noon 6 p.m. midnight
MODUL SPIKER It is a LED luminaire with two modules. The bottom module directs the luminous flux directly downwards and ensures optimal illuminance of the workplace. The backlit side diffuser is a source with specially adapted spectrum to support the bluelight content. Its vertical displacement ensures optimal luminance levels in the field of vision and at the same time a higher level of the vertical illuminance. The luminous flux flowing out of the luminaire in a specific direction helps, together with vertical surfaces of the room, direct a certain part of the luminous flux to the human eye in the required angle. It is able to directly affect the receptor in the eye sensitive to light (the so called third photoreceptor) that controls the internal biorhythm of people and in this way it is able to optimise their performance efficiency during working hours. The luminaire design itself, suitably selected light sources and appropriate directing the luminous flux create a concept of the so called biologically effective lighting.
9 a.m.
6 a.m. noon 6 p.m. cortisol level
midnight 6 a.m. melatonin level
The human organism produces the hormone cortisol during the morning hours which increases the concentration and performance efficiency of the organism. Its concentration in the blood reaches its maximum at about 9 a.m., then it gradually decreases during the rest of the day. Melatonin, also called a sleep hormone, is produced by the human body during the night and its concentration in the human organism culminates at about 3 a.m. 0° ~ 30° No effect 30° ~ 45° Insufficient effect 45° ~ 90° Optimal effect 90° ~ 180° Undesirable effect - risk that glare can develop
The third type of the photoreceptors in the human eye is sensitive to that part of the light spectrum with the wavelength of approximately 464 nanometres, i.e. the blue light. These photoreceptors affect the creation of melatonin, a hormone managing the circadian rhythm of people.
Modul RAY The basic attributes of the unique luminaire Modul RAY are an innovative and compact design as well as the mechanical structure. The luminaire can be dimmed, if necessary, and can be fitted by various types of sensors and tools of intelligent management.
modul spiker
122
Melatonin Melatonin makes us feel drowsy, slows down bodily functions and lowers activity levels to facilitate a good night’s sleep. It also ensures that a large number of metabolic processes are wound down. Body temperature falls; the organism, as it were, is put on the back burner. In this phase, the body secretes growth hormones that repair cells at night. Cortisol Cortisol is a stress hormone, produced from around 3 a.m. onwards in the adrenal cortex. It stimulates metabolism again and programmes the body for day-time operation. The first light of the day then stimulates the third receptor in the eye and suppresses the production of melatonin in the pineal gland. At the same time, the pituitary gland makes sure the body secretes more serotonin.
Modul SPIKER From the point of view of the design the Modul SPIKER represents an interesting and biologically effective luminaire. The direct light from the LED sources placed in the bottom part of the structure is completed by a microprismatic refractor which changes the direct light to soft and diffuse one. The side optics is designed to direct the blue spectrum of the light to the human eye under an optimal angle and to affect the third photoreceptor responsible for the operation of the human circadian rhythm. The positive biological effect of this luminaire arrives especially at very cold light with the correlated colour temperature from 6,500 to 8,000 K.
Serotonin Serotonin acts as a mood-enhancing, motivating messenger. While the level of cortisol in the blood falls during the day in a counter-cycle to melatonin, serotonin helps us achieve a number of performance peaks. When daylight fades, the internal clock switches to night. However, if our body does not get enough light during the day, it produces only a low level of melatonin. As a result, we sleep badly, we wake feeling unrested, we are tired during the day and lack energy and motivation. Insufficient exposure to stimulating light during autumn and winter can turn the process into a downward spiral. At that time of year, some people develop seasonal affective disorder (SAD). Their internal clock misses its cues because the hormonal balance in the brain is upset.
28/29
The daylight is not naturally monotonous. It changes its properties not only in dependence on the season of the year, but also in dependence on the cloudiness during the day. Its intensity and correlated colour temperature change during the day. Daylight simulation
Concept “Brilliant Mix” The system Brilliant mix implemented to the OMS As we have already mentioned product CAPH was developed by the company OMS in colin several areas the scientific laboration with Osram Opto research has proved that the semiconductor (Regensburg, daylight is the most natural Germany) and Mazet (Jena, type of light for people. This Germany). The Brilliant mix knowledge results in our atis a demonstration of what tempt to adapt the artificial light to its properties as much white light of high quality as possible. Through changing OMS is able to produce. the lighting intensity and the correlated colour temperature The principle of Brilliant mix of the light as well, we can is based on mixing three LED achieve improving the visual colours (“blue” white, “green” well-being of the pupils and in EQ-WHITE and “red” amber) in this way to create conditions one luminaire and the result is a where they enjoy learning. white colour with a high colour rendering index. By adding/ The daylight simulation function taking away individual channels is one of the tools through which it is simultaneously possible to change the correlated colour we can achieve this effect. It is temperature of the white light based on the fact that the daylight is not naturally monotonous. in a wide range (2,700 - 6,500 K). It It changes its properties not only is important that every adjusted in dependence on the season of colour temperature has a durathe year, but also in dependence bly high CRI of more than on the cloudiness during the day. 90 and a relatively high efficacy Its intensity and correlated colour (lm/W). The whole concept is completed with electronics temperature change during the which are able to control each day. All these factors affect our perception of the space and ob- channel independently and a jects inside of it. The goal of the colour sensor which permadaylight simulation in the schools nently evaluates the CRI and is to achieve such an intensity of CCT data. If the values differ from those being selected, the the correlated colour temperature which copies the properties sensor gives the electronic a command for correction. In of the daylight as truthfully as possible. The daylight simulation this way permanent monitoring of the light quality during the is often implemented together whole LED life cycle is ensured. with the daylight sensor which Using the concept Brilliant assesses the lighting intensity mix we can achieve that all in the room during the day and luminaires installed in one room according to this it increases or decreases the performance of the have the exact same CCT value luminaires in the lighting system permanently. so that the constant illuminance of the space in compliance with the standard during the whole working hours can be ensured.
caph
12:00
Good morning Cool, fresh light raises the energy level of students coming into the school and provides a good start to the day. lighting level (lux)
900
800
700
600
500
Biological factor of illumination
8:00
The goal of the daylight simulation is to achieve such a light intensity and colour that copies the properties of the daylight as truthfully as possible.
8:00
cool light (6500 K) warm light (3000 K)
13:30
Lunch time A short rest helps the students to recharge out batteries. The light level decreases and the warm light facilitates relaxation.
17:30
Post-lunch dip After lunch students usually feel sleepy. The light level rises again and changes to cool white to counter the „post lunch dip“.
Happy hour Just before the end of the school day a change to cooler white light provides an alertness boost ahead of the journey home.
13:30
12:00
8:00
10:00
12:00
17:30
14:00
16:00
18:00
30/31
141
If there is too big of a difference between the luminance levels in the individual parts of the space, it takes the human eye a few minutes until it adapts to this new luminance. ILLUMINATION OF ROOM SURFACES When designing the lighting system of the educational premises it is necessary to take into account the importance of the sufficient illuminance of the vertical as well as horizontal surfaces. The vertical illuminance supports better orientation in the space and creates better conditions for problem-free perception of objects or faces. The problem of the majority of the school premises consists in the fact that in the existing lighting systems solutions created by ceiling surfaced luminaires with the direct characteristic of radiation still dominate.
LQS VALUE Vertical illumination Vertical illumination
LQS Value
Evavg > 0,5 Ehavg (Wall LG7) Evavg >150 lx
5
Evavg > 0,5 Ehavg (Wall LG7)
4
Evavg > 0,4 Ehavg
3
Evavg > 0,3 Ehavg
2
Evavg > 0,1 Ehavg
1
Evavg < 0,1 Ehavg
0
the adaptation state of vision. If there is too big of a difference between the luminance levels in the individual parts of the space, it takes the human eye a few minutes until it adapts and due to this fact the eye-pupil is increasingly overstrained and the eye fatigue develops.
To prevent it, it is necessary to design the lighting system in such a way that we create a homogeneous light environment without any distinctive differences of the luminance intensity in the whole panoramic field of vision of the students and the teachers as well. In this way we will create conditions where the eye is not forced to carry out any adaptation to new luminance after each change of the view. Here the need of adequate and uniform illuminance Although this solution is sufof all vertical surfaces in the ficient for lighting the workstudents´ or teachers´ fields of ing plane, however, it has not sufficient potential for adequate vision comes to the foreground. lighting the walls and ceiling. In For the teacher’s visual the framework of this lighting well-being it is necessary to solution the walls and ceiling illuminate the back wall of the remain dark which causes the room which is his/her field of so called cave effect which vision sufficiently. To prevent any can even result in depressive big differences of luminance, claustrophobic feelings of the children. The pupils need a suffi- it is necessary to achieve the ciently and uniformly illuminated illuminance of the back wall space for the feeling of the psy- minimally 300 lux. The board or other presentation surfaces that chological and visual comfort. are placed in the field of vision The requirement on uniform illuminance of the space without of the students and together with the desks represent a task any distinctive light transfers area from the point of view of results from the nature of the the standard have to comply teaching process itself. with the requirement on the uniform luminance distribution During the lessons the pupils in the educational spaces. The permanently move their view angle of vision is changed from from the desk to presentation surfaces or the teacher. During the desk to the board during the active utilisation of the presentathis process the vision adapts through an automatic change of tion surfaces in the educational the pupil diameter and it regu- process. For the eye not to be lates the luminous flux falling to strained by a forced adaptation to a changed luminance level, it the retina. This reflex is called
Illumination of room surfaces
MODUL LAMBDA MAX 125
MODUL LAMBDA
The luminaire MODUL LAMBDA II ASYMMETRIC from the OMS portfolio represents a suitable solution. It is a luminaire with the asymmetric radiation curve whose optical system was designed to fulfil the strict normative requirements for the The standard EN 12464-1 determines the illuminance level educational premises. The optimal light conditions with the 500 lux with the uniformity of 0.7 for the board. This require- required illumination levels of vertical and horizontal surfaces ment can be met by using the asymmetric additional luminaire can be achieved in two ways. The first option are recessed placed in the distance luminaires with the direct and of 0.85 – 1.3 metres from the indirect characteristic of the presentation surface. luminous flux distribution which thanks to the specially formed is necessary to ensure the corresponding vertical illuminance of the presentation surface and adequate luminance uniformity on the presentation surface and in its immediate surrounding.
diffuser are able to direct part of the emitted light directly to the ceiling. The other option is represented by the suspended luminaires with the direct and indirect characteristic of the luminous flux distribution which direct part of the light directly to the working plane and the second indirect diffusion part directly to the ceiling. For this lighting solution it is recommended to place the luminaires in such a way that the proporBy a correct ratio of the illuminance of all surfaces in the tion of the direct and indirect room we can prevent both the psychological and eye fatigue part of the luminous flux is and damaging the human sight as well. 50:50.
125
Relative ceiling illuminance: min 30 % of workplace illuminace Relative wall illuminance: min 50 % of workplace illuminace
LQS VALUE Ceiling illumination
Workplace illuminance 100 %
32/33
Ceiling illumination
LQS Value
Ehavg > 0,3 Ehavg (Ceiling LG7) Ehavg > 75lx
5
Ehavg > 0,3 Ehavg (Ceiling LG7)
4
Ehavg > 0,2 Ehavg
3
Ehavg > 0,15 Ehavg
2
Ehavg > 0,1 Ehavg
1
Ehavg < 0,1 Ehavg
0
With emotional lighting the light solution is strengthened by a potential to create various light scenes that are able to induce a relaxation, working or motivation atmosphere.
EMOTIONAL LIGHTING The emotional lighting provides large opportunities in various types of interior from the point of view of its utilisation. The emotional lighting finds its place in the schools e.g. where we solve the illumination of the relaxation zones (clubrooms, lounges, etc.) or in the lecture halls or rooms determined for the multimedia presentations. From the technological point of view it provides a large space for utilising the RGB LED technology enabling the mixing of colours from red to blue. Using the RGBW by adding the white colour it is possible to achieve more intensive colour saturation along the whole colour spectrum. The light solution is thus strengthened by a potential to create various light scenes that are able to induce a relaxation, working or motivation atmosphere. This category includes two different types of lighting: the accent and ambient ones.
LQS VALUE
Accent lighting finds its place in cases where we want to emphasise the extraordinariness of the object or to draw attention to an important detail. At schools it is used e.g. in the corridors, for illuminating the information boards and boards or awards and diplomas which the pupils of the school acquired. Its effectiveness is based on the ability of the human eye to perceive the contrast of phenomena; therefore the extraordinariness of an object is highlighted by increased luminance which is in the ratio 3:1 to the average luminance in the space.
arcline optic led rgb
151
dowNLIGHT mira
139
dowNLIGHT PROXIMA 138
Ambient lighting completes the atmosphere of the space where it is used and gives it the necessary mood and character. The RGB and RGBW technologies are often part of this lighting and enable colour solutions of the lighting scenes. It often finds its place in the lounges and lecture rooms of the schools and educational premises.
LQS assesses the space according to the fact if the emotional lighting is or is not part of the lighting solution. The spaces with the emotional lighting are assessed by the full score of 5 points; the spaces without this type of lighting obtain 0 points.
Ambient lighting Ambient lighting
LQS Value
Yes
5
No
0
LQS VALUE
LQS VALUE
RGB colour mixing
Accent lighting
RGB colour mixing
LQS Value
Yes
5
Yes
5
No
0
No
0
Accent lighting
EMOTIONAL LIGHTING
34/35
LQS Value
ECOLOGY
Together with awareness of the limited character of the energy sources that causes the permanent increase of their prices, taking into
The ecology and ecological solutions respecting the fragile equilibrium of the
account the ratio of the luminaire
environment are important topics which have become key values across the whole
or light source effectiveness and the
industrial spectrum during the last decades. The manufacturers of the luminaires
energy consumed the trend is coming
and light sources are no exception in this area.
to the foreground.
Also in this line of business the demands on efficient utilisation of energy, the recyclability and long life of the products constantly rise. In the area of manufacturing the luminaires and the light sources, the effectiveness of the light sources, the effectiveness of the luminaires and their impact on the environment are more and more emphasised. These are categories which, besides the ecological approach, contain a substantial potential for energy savings and in this way also reducing the operating costs. For the developers and architects of the school buildings just this factor is the source of the strongest motivation when designing the light systems.
ECOLOGY
36/37
The main indicator for selecting an optimal lighting solution in a school is the efficacy of the light source.
LATEST LAMP TECHNOLOGY The times when the whole world applauded Thomas Alva Edison for the discovery of the light bulb are irrecoverably over. Although he made his mark on history forever as the inventor of artificial light, other scientists and inventors came after him and they shifted and are still shifting the development by leaps and bounds ahead.
LQS VALUE Latest lamp technology Latest lamp technology
LQS Value
> 100 lm/W
5
> 90 lm/W
4
> 80 lm/W
3
> 70 lm/W
2
> 60 lm/W
1
> 50 lm/W
0
With the knowledge about the limitedness of the energy sources which causes permanent increase of their prices, the trend taking into account the ratio of effectiveness of the luminaire or the light source and the consumed energy is coming to the foreground. As late as three years ago, the metalhalide lamps especially met these requirements but even they are retreating in favour of the light emitting diodes – LED. Compared to the conventional sources the LEDs achieve better parameters in each respect: they are more effective, they emit a negligible amount of heat, they place lower demands on the consumption of electrical energy, they do not contain mercury and so they are more ecological. In the area of manufacturing the light sources just LEDs represent a category which currently progresses most quickly. Up to 90 % of all innovations today take place in the category of the LED light sources. Of course, the development and production of the conventional light sources has not been stopped but they progress more slowly. However, also here
Latest lamp technologY
mercially available; however, in the lab conditions the value of 254 lm/W has already been achieved. The higher price of LED luminaires is the reason why they have not replaced lighting fixtures with conventional light sources in spite of the fact they are obviously of higher quality. But also this factor is to The main indicator for selecting be viewed in a wider context. Although the initial costs for an optimal light source which purchasing of LED luminaires a designer of the light system will always be higher, the in a school has to follow is the return on investment in the efficacy of the light source. form of energy savings during Its value shows with what the whole luminaire life time effectiveness electric power is and practically no maintenance changed into light, i.e. how costs make the LED luminaires much of luminous flux (lm) is produced from input power (W) extraordinary commercially interesting. From this point of delivered to a light source. The view the retrofits where we only unit is lumen per watt (lm/W). change the conventional light The LED light sources achieve the best parameters also in this source for a more modern type category. Currently the LED chips prove to be only temporary and from a long-term point of view with efficiency of 160 lm/W it is also a loss-making solution. at cool white CCT, are comit is valid that the trend leads especially to manufacturing more effective and economical types of the existing light sources. The original types are replaced by the eco and long-life fluorescent lamps or metal-halide lamps with ceramic burner of the second generation, etc.
efficacy of light source LED High-pressure sodium lamps Metal halide lamps Linear fluorescent lamps Compact fluorescent lamps Mercury vapor lamps Low voltage halogen lamp Incandescent lamps
0
20
40
60
80 100
120
140
160 180
200
220
240
lm/W (without ballast losses)
38/39
The materials used for the production of a luminaire have the biggest impact on its efficiency.
dowNLIGHT VISION led
140
SYSTEM EFFICAcY OF LUMINAIRE
THERMAL OUTPUT OF LAMP
The luminaire efficacy factor determines how effectively the lighting fixture itself is able to direct the light from the light sources with the smallest possible losses on the surfaces of the optical system. The light output ratio (LOR) expresses the ratio of the luminous flux flowing from the luminaire and the sum of the luminous fluxes of all light sources in the system.
The light spectrum visible for the human eyes is between the ultraviolet (UV) and infrared (IR) spectrum. In spite of the fact that the human eye is not able to catch the infrared light, it perceives it as radiant heat. Every object that is exposed to such radiation is constantly strained. However, the majority of the light sources used radiate this part of the spectrum in various extents. The lower the value of the radiated IR is, the more effective the light source is. From this point of view, on the bottom of the scale as the least efficient, there are the usual incandescent lamps which change up to 95 % of energy into heat and only remaining 5 % into visible light.
Lumen output of luminaire LOR = –––––––––––––––– % Lumen output of lamp This value can be divided into the upward and downward ratio that expresses how many percent of the luminous flux from the luminaires leads to the upward and downward space (i.e. over and under the luminaire). This is of special importance for those spaces which place high demands on the illumination of the ceiling.
LQS VALUE System efficacy of luminaire System efficacy of luminaire
LQS Value
> 80 lm/W
5
> 70 lm/W
4
> 65 lm/W
3
> 55 lm/W
2
> 40 lm/W
1
> 30 lm/W
0
The materials used for luminaire production have the biggest influence on its efficiency. The optical materials enable changing the distribution of the luminous flux of sources, diffusing the light or changing the spectral composition. They are divided into reflective and transparent ones. Aluminium, using various surface finishes, creates the predominant part of the reflective materials. The most often used transparent materials are glass and plastics. Aluminium, glass, plastics, steel have different reflectance and capability to absorb light. However, in general it is valid that the more effective the
materials used in the optical system are, the lower the losses on these surfaces will be as well as the luminaire efficiency being higher. Lumen output System of luminaire lm efficacy = ––––––––––––––– [–––] of luminaire Installed power W of luminaire Besides the used material themselves the luminaire efficacy is also affected by the design or the shape of the optical system. A correctly designed luminaire
reflects the largest amount of light to the surroundings at minimal losses. The optimal mathematical and physical geometrical shapes of the lighting fixture can be calculated by modern computer systems, e.g. LIGHTOOLS. The DW VISION LED achieves the efficacy of the luminaire of up to 103 lm/W thanks to its integrated Fortimo LED module system. The Fortimo LED modules represent the latest generation of the LED sources
System efficACY of luminaire / Thermal output of lamp
which are able to increase the efficacy of the lighting system without changing its dimensions, shape or luminous flux of the system. The Fortimo LED modules are a source of the white, effective light with CRI 80. The luminaire DW VISION LED fulfils the conditions of the standard for lighting of schools EN 12464-1. LQS assigns the highest score the luminaires with efficacy of more 80 lm/W.
In the schools with air-conditioning the light sources with a high IR radiation percentage are a sufficiently big load for the electric power consumption. The heat from the non-effective sources heats the air continually in the closed space cooled by the air-conditioning – this fact is connected with the need for a higher performance of the air conditioning. It is approximately valid that for 2.5 W of the luminaire energy 1 W of the air-conditioning energy is used, i.e. if the energy consumption of the lighting system increases, the energy consumption for the air-conditioning operation grows in direct proportion, too. The owners of schools illuminated by outdated light sources is burdened by increased costs not only for the energy needed for the operation of the light system but also for the air-conditioning. From this point of view the installation of luminaires with light sources creating the minimal percentage of the IR radiation is considered the most economical. These requirements are currently reliably fulfilled by the latest LED light sources that radiate only a negligible amount of the IR radiation.
It is approximately valide that for 2.5 W of the luminaire energy 1 W of the air-conditioning energy is used, i.e. if the energy consumption of the lighting system increases, the energy consumption for the air-conditioning operation grows in direct proportion, too.
LQS assesses with the highest number of points those light systems which on average do not exceed 15 % proportion of the IR radiation in the overall radiated spectrum. This assessment is fulfilled especially by the LED light sources.
40/41
LQS VALUE Thermal output of lamp Thermal output of lamp
LQS Value
< 15 % proportion of IR radiation
5
< 26 % proportion of IR radiation
4
< 28 % proportion of IR radiation
3
< 31 % proportion of IR radiation
2
< 60 % proportion of IR radiation
1
> 60 % proportion of IR radiation
0
The designers of the lighting system
COMPARING TOTAL COSTS FOR ILLUMINATION (TCO) TOTAL COSTS OF OWNERSHIP
for schools should also take in account the ecological potential of the light sources when they select them.
The vision of danger in connection with luminaires and light sources for common people is connected with the risk of cutting by a broken bulb. As a matter of fact, the risks connected with using some types of the light sources are much more serious and can have an impact on the people’s health as well as on the quality of the environment. The reason is the mercury content, a heavy metal with high toxicity, which is an inevitable part of the fluorescent lamps and metal-halide lamps. In spite of extensive scientific research, until now we have not revealed a material which would replace the task of mercury in the light sources. The solutions which would not represent any risk from the point of view of safety are extremely costly and therefore unsuitable for the mass market.
LQS VALUE Dangerous material content
LQS Value
mercury content 0 mg
5
mercury content < 0,5 mg
4
mercury content < 1,5 mg
3
mercury content < 2,4 mg
2
mercury content < 5 mg
1
mercury content > 5 mg
0
PRODUCT LIFETIME AND MAINTENANCE COSTS When designing a lighting system of a school building one of the key factors the architect and developer should take into account is the lifetime of the light source and the costs for its maintenance.
These light sources wear off rapidly when they are frequently switched on and off. Therefore their placement e.g. in a corridor with an installed movement detector (most frequently due to saving of electric power) is not the best solution, just because of the shortened life span. The user of the space is then burdened by the costs not only for the purchase of The designers of the lighting the replacement light sources system for schools should also but also for activities connected take into account the ecological with maintenance and service potential of the light sources of the lighting system. Further when they select them. The indirect costs aroused by the new types of the fluorescent need to make the space of lamps marked “eco” contain the school building accessible a smaller proportion of The task of mercury in some during maintenance operations mercury than the older types. types of the light sources reand not to restrict the everyday mains thus irreplaceable. When However, from the point of operation of the individual the luminaire is switched on, a view of safety the LED light workplaces are connected with sources are undoubtedly consid- a more frequent replacement discharge arises during which ionisation of the mercury atoms ered the least dangerous of the light sources. develops and they subsequently option. emit ultraviolet radiation. This Compared to the incandescent radiation excites the phospho- LQS assesses the light sources lamps the LED light sources according to the mercury rus molecules spread on the represent at the first sight a internal side of the fluorescent content and the highest score more costly solution. Their price – 5 points are assigned to the lamp and during their return compared with the conventionlight sources with zero content al light sources is really higher; to the original state they emit of mercury. photons of visible light. however, their utilisation in the lighting system is profitable The risk connected with the for several reasons. Their first light sources containing merand the biggest advantage cury does not consist in their is the extremely long life-
time reaching more than 50,000 hours and it represents at 11 hours operation time 250 days during the year approximately 18 years. In the case of LED the end of the lifetime is given by the decrease of the light output on to 70 % (in some cases 50 %). At the same time they are light sources which show an extremely low failure rate, only two LED sources pre million pieces produced. The regular costs for their replacement and maintenance are thus removed. By adding the functionality lighting management system into the lighting system we can reduce the need of the manual control which is also considered a certain type of maintenance. The long lifetime and minimal demandingness in the area of maintenance in combination with energy economy make the LED light sources an ideal solution when designing the lighting system in the school building.
CLASSIC ASN OPAL LINE RANGE 100 LED LINE RANGE 100 LED
When taking into account all relevant criteria, LQS assigns the highest score for the parameter “product lifetime” and the “costs for maintenance” just to those light sources with the lifetime of or higher than 50,000 hours.
FD (T8)
LED CRI 80
LED CRI 80
power consumption
58
59
59
W
number of light sources in luminaire
2
1
1
pc
control gear
CCG
ECG
ECG
type of lighting control
none
none
light sensor
lifetime of light source
15 000
50 000
50 000
140
59
59
W
10 000
4 700
4 700
lm
power consumption of luminaire luminuos flux LOR
50
100
100
%
5 000
4 700
4 700
lm
number of luminaires
20
20
20
pc
average time when luminaire switch on between 6.00 – 18.00
10
10
10
hour hour
average time when luminaire switch on between 18.00 – 6.00
0
0
0
number of days in week when luminaire switch on
5
5
5
day
0.18
0.18
0.18
€/kW/hour
purchase price of luminaire
50
200
220
€
purchase price of light source
2
0
0
€
price for electrical energy
purchse price of service hour time needed for the exchange of one source
30
30
30
€
0.25
0.25
0.25
hour
COOLING ENERGY cooling system usage factor cooling efficiency
50 %
50 %
50 %
2.5
2.5
2.5
Wh/Wc
purchace for initial instalation
1 080.00
4 000.00
4 400.00
€
Number of maintenance required per 12 years Maintenance fee
2
0
0
230.00
0.00
0.00
€
power consumption of luminaire
140.00
59.00
28.00
W
power consumption of cooling system
28.00
11.80
5.60
W
completly power consumption of room
3 360.00
1 416.00
672.00
W
33.60
14.16
4.84
kWh
consumption of el. energy for
day
730.00
307.64
105.12
kWh
year
8 760.00
3 691.71
1 261.44
kWh
production of emission CO2 per year
5 606.40
2 362.70
807.32
kg
price for el. energy per
day month year
6.05
2.55
0.87
131.40
55.38
18.92
€ €
1 576.80
664.51
227.06
€
difference between input costs
2 920.00
3 320.00
saving difference per year
-912.29
-1 349.74
€
saving CO2 per year
-3 243.70
-4 799.08
kg
payback excluding maintenance
3.2
2.5 Years
payback including maintenance
3.3
2.5 Years
POWER consumption of lighting installation Production of CO2 kW
140 000 120 000 100 000 80 000 60 000 40 000 20 000 0 0 1 2 3 4 5 6 7 8 9 10 11 12 years Classic ASN OPAL
Dangerous material content/ Product lifetime and maintenance costs
hour
luminaire light output
Hg
(daylight sensor)
type of light source
month
Hg
Dangerous material content
common usage. It arises when they are broken during handling or they are not disposed in compliance with legislation which defines the method how the used and damaged light sources containing toxic substances are to be removed. In the first case there is a threat that the mercury vapours can leak to the air which in dependence of the number of disrupted sources, the size of the room and method of airing can cause the students shortterm health problems (nausea, anxiety). In the second case, when disposing the toxic waste inadequately, it represents a long-term risk of soil contamination, as the heavy metals do not decompose and become a permanent art of the environment.
Hg
DANGEROUS MATERIAL CONTENT
Line Range 100 LED Line Range 100 LED (daylight sensor)
70 000 60 000 50 000 40 000 30 000 20 000 10 000 0 0 1 2 3 4 5 6 7 8 9 10 11 12 years Classic ASN OPAL
25 000
Line Range 100 LED Line Range 100 LED (daylight sensor)
LQS VALUE
operating costs and payback time
kg CO2
€
€
Product life-time & maintenance costs
20 000 15 000 10 000
5 000
0 0 1 2 3 4 5 6 7 8 9 10 11 12 years Classic ASN OPAL
Line Range 100 LED Line Range 100 LED (daylight sensor)
42/43
TProduct life-time & maintenance costs
LQS Value
>_ 50000
5
> 24000
4
> 19000
3
> 12000
2
> 10000
1
>_ 2000
0
EFFICIENCY The task of the modern technologies in the lighting systems is to provide the user with maximal comfort for their control. However, in the schools they simultaneously create a potential for substantial savings.
The technological progress today enables taking benefits of a high-quality illumination of the space and at the same time to saving time, energy and maintenance costs. Through the intelligent forms of the lighting management system the operation of a school can be more effective than any time before. At the same time the modern technologies enable changing the lighting intensity and the colour of the light in the individual spaces and so to offer varied atmospheres or emotions and currently all of that can be controlled only by one touch on the display of the smartphone.
EFFICIENCY
44/45
Daylight sensor
141
LQS VALUE Daylight sensor Daylight sensor
LQS Value
Yes
2
No
0
The core of the system itself is the luminance sensor which reads the light conditions at the scanning plane. The advantage is that the daylight and the artificial light complete each other, i.e. when the day illumination decreases, the artificial one increases and vice versa. This property ensures that in the given space there is always as much light as necessary. This regulation method can be carried out continuously or by jumps, here the luminaires dim down to the value of 10 %. In larger spaces we use several sensors which asses the mutual resulting value by averaging. The management of the luminaires based on the lighting intensity is realised fully
LQS considers the daylight sensor the most effective technology from the point of view of saving energy and assesses the spaces with the daylight sensors by 2 points.
Constant illuminance sensor
The requirements on the adequate
The task of this sensor type is to ensure the constant illuminance independently of the conditions of luminaires in the lighting system. The essence of this type of management results from the fact that the light properties of the luminaires deteriorate during the installed life, the optical parts are polluted or some of the luminaires in the lighting system are damaged.
lighting intensity of the workplace can be achieved by installing the daylight sensor.
The constant illuminance sensor behaves in the space as a sensor of the lighting intensity and in this way it artificially adjusts (increase or decreases) the luminous flux of the luminaires. For the sensor to be able to fulfil its function it is necessary to count on its installation already when designing the lighting system which has to be over-dimensioned already at the beginning of the design. The economy of this solution can look controversial at first sight. However, the reality is that savings are really achieved as during the first years of the over-dimensioned lighting system operation the individual light sources do not run at full power. The system is adjusted to 100 % output after the signs of wear began to be evident. In this way the constant lighting intensity of the whole scanned space is guaranteed. From the point of view of improved economy this solution can be realised by combining the constant illuminance sensor with the daylight sensor. Both sensors in this combination are able to utilise the potential of the natural light falling to the space through the windows in full extent and to adjust the intensity of the artificial light. The combination of several types of the lighting management systems enables to make use of the natural light potential in full extent and to adjust the output of the lighting systems to it – this will prolong its life span and maximise the savings of energy.
luminous flux 100 %
80 %
Area Sp (saving) end of light source lifetime
0 % L
14:00
The light conditions change in dependence on the hour of the day, weather and the season of the year. The task of the artificial light is to balance these differences and to complete or fully replace the natural light when its availability is limited.
18:00
16:00
10 % of power consumption
30 % of power consumption
100 %
Energy consumption
GACRUX
of mirrors and radiation sources which negatively affect the scanning process. It is ideal to place the scanner over the task area which places the largest demands on the constant illumination.
automatically and besides saving energy it also increases the user’s comfort. Its effectiveness Daylight has decisive importance for the health and well- is higher the more daylight falls being of people. Its shortage to the given space. When installing the daylight sensors the has not only influence on the quality of vision but also scanned zones must not overlap. It is also unsuitable to place the performance efficiency the sensor in the reflection zone and concentration and can even cause disruption of the circadian rhythm. Therefore it is important to create such an environment at school which is able to copy the daylight properties as truthfully as possible. Although the majority of the rooms in the school has minimally one wall with windows, the availability of the daylight is never so optimal that it can do without a lighting system of high quality. The light conditions change in dependence on the hour of the day, weather and the season of the year. The task of the artificial light is to balance these differences and to complete or fully replace the natural light when its availability is limited. The requirements on the adequate intensity of the workplace lighting can be achieved by installing the daylight sensor.
70 % of power consumption
1st luminaire
Sensor
energy consumption according to lighting intensity
0 % 7:00
20:00
8:00
9:00
10:00
The intensity of daylight
11:00
12:00
13:00 14:00
Light measurement
15:00
16:00
17:00 18:00
19:00
20:00 21:00 22:00
When designing a lighting system, it is always over-dimensioned by minimally 20 %. In this way at the end of the life span the required illuminance intensity is still achieved. Using the constant illuminance sensor we can achieve 20 % energy savings during the first years of the lighting system lifespan.
100 % of power consumption
2nd luminaire
3rd luminaire
daylight and artificial light daylight
Sensor
4th luminaire
Light measurement
When installing the sensors it is important to pay attention for the zones scanned not to overlap and to be placed in sufficient distance from radiation sources which negatively affect their detection ability.
The energy consumption of the lighting system in dependence of the daylight availability achieves the maximum values early in the morning and during evening hours.
Daylight sensor / Constant illuminance sensor
46/47
LQS VALUE Constant illuminance sensor Constance illuminance sensor
LQS Value
Yes
1
No
0
The presence detector can be used for both the indoor and outdoor applications with different sensitivity and assembly height. DoWnlight MIRA
139
PRESENCE DETECTOR In a school building there are spaces which do not require permanent lighting. They are rooms or communication zones without permanent occurrence of persons. These spaces represent a distinctive potential from the point of view of energy savings. A suitable type of management for this type of spaces is the presence detector which manages the luminaires to light only when somebody occurs in the given space and thus when the lighting is really necessary. It is automatic management fitted with a sensor responding to the heat of the moving persons in the detection area. The passive infrared technology with built-in scanners in the sensor which respond to the heat radiation emitted by the human body and transfer it to an electric signal ensure the scanning of the space. The sensor subsequently assesses the information and switches on the illumination. The scanner itself does not emit any radiation and therefore we can speak about the passive infrared sensors (PIR).
The presence detector can be used for both the indoor and outdoor applications with different sensitivity and assembly height. For an ideal coverage of the space it is ideal for the sensors to overlap their scanning areas (partially). It is important not to install the sensors close to the luminaires with strong IR radiation, the air-conditioning or heating units and other sources of the IR radiation – it could affect their functionality. When they are installed appropriately, the sensor will respond immediately after somebody enters the scanned zone. When the system is managed by movement the function of delay for dimming can be used and it means that the luminous flux does not change immediately after the movement fades but after passing the adjusted time when there is no movement. This time is determined according to the type of the space and the frequency of the assumed movement. Dimming can be transferred either to a certain level (e.g. 10 %) of the luminaires´ luminous flux or dimming up to the value of 0 %. The luminous flux level 10 % is
DW MIRA
The presence detector switches on the luminaires in the selected spaces when somebody occurs there and thus when the illumination is really necessary.
used due to the safety reasons. The space, though without any movement, should not be fully dark due to the safety reasons but also because of the security cameras, prolonging the life span of the light sources. The presence sensor can be installed as an independent action element (which controls the lighting system) or it serves only as an input element which gives information for the assessment of the supervising control unit or system. From the LQS point of view the presence detector is an extraordinarily effective method how to improve the effectiveness of the lighting system and to optimise the energy consumption therefore the spaces with this element of the lighting management are assigned the score 1.
100 % movement
0 %
time
100 % movement
10 %
time
When there is nobody in the space being detected. The presence detector switches off the lighting.
100 %
LQS VALUE Presence detector Presence detector
LQS Value
Yes
1
No
0
movement
10 %
delay time
time
When a person enters the room the presence detector responds to the infrared radiation the human body emits and switches on the lighting.
The presence detector can be adjusted in such a way that the lighting in an abandoned space will not switch off immediately after departure of the last person but gradually.
100 % movement
delay time
transition time
10 %
Presence detector
0 %
time
100 %
10 % 0 %
48/49
The modern technologies enable to control the lighting through a tablet or smart phone.
GACRUX
141
CALLING OF LIGHTING SCENES
the corresponding lighting scene enables switching on the asymmetric additional lighting, The lighting system manage- dimming it during projection or ment based on the change of switching off the main lighting in the room. The control is the firmly adjusted lighting carried out by a built-in panel scenes has a wide implementation in the educational or by remote controls – we recommend using the controls premises. Under a lighting on the wave basis especially scene we can understand in the structured spaces. The a summary of several adelectromagnetic waves which justed factors which can be controlled by pushing a but- are emitted are able to pass though materials which create ton. Here belong e.g. – the lighting intensity (e.g. 100 %, an obstacle between the sender 75 %, 50 %, 25 %, 0 %), co- and receiver and this fact lour of the light, RGB scenes, enables being built in a receiver. The modern technologies calendar or the simulation currently enable managing the of the daylight. By arouslighting through smart phones ing a change of the lighting or tablets. By creating a specific scene we can adjust the application we can control the illumination to the needs of lighting system in the whole the education. premises of the school with only In the school buildings this type one touch. Through the wireless communication the sender of the lighting management emits a signal to the controller, finds its place especially in the it assesses it and through the spaces where various educational activities take place, e.g. control unit is sends the inforin the classrooms or in the lec- mation directly to the luminaire ture theatres. By implementing or a group of luminaires which this function it is possible, with can be remotely switched off, the simple control of a button, switched on. The user can also increase or decrease their to switch on, dim or switch radiation intensity or the colour off part of the illumination according to the individual need. temperature. During the tests it is possible to switch on only the main lighting through the adjusted scene. During lectures and lessons LIGHTING SCENE 1: LIGHTING SCENE 2: where the presentation surfaces During presentation the general light- During tests the general lighting are utilised, the selection of ing and the lighting of the presenta- lights at 100 %. tion surface lights at 100 %.
control panel
control components
OMS CPS The Central Power Source (CPS) developed by the company OMS belongs to the latest types of control. It is an innovative system with a centralised source of feeding for the LED luminaires. The CPS system is equipped with an intelligent communication interface between the central system (MASTER) and connected luminaires (SLAVE) which communicate with each other directly in the safe power supply 48 V DC system. Centralising the power supply source brings advantages in the form of a lower price for the LED luminaires which can be used without an electronic control gear, their smaller dimensions and also lower number of conductors is necessary. Thanks to the web interface implemented directly in the OMS CPS it is possible to control, follow and adjust the luminaires to various scenes practically from any “web place”. The DALI interface for ensuring the compatibility with older systems is also available. A big advantage of this control system with maximum load 2.4 kW is that during its installation the conductors and wires of the existing installation can be used. Standard DALI installation. DALI Control Unit DALI Link
2 DALI Power Supply
LIGHTING SCENE 3: During presentation with an overhead projector the general lighting is dimmed and lights at 10 %.
LIGHTING SCENE 4: During lectures the general lighting and the lighting of the presentation desk used by the lecturer light at 100 %.
Power link
3
230 V AC
Installation using OMS CPS system. LAN
lighting DALI
LQS VALUE Calling of lighting scenes Calling of lighting scenes
LQS Value
Yes
1
No
0
1-10 V
iPad, iPhone, Android
Wireless Access Point
Calling of lighting scenes
Controller
Control unit
Lighting
CPS
2
48 V DC
230 V AC
50/51
DOWNLIGHT VISION LED
140
DOWNLIGHT AVIOR MOTION
138
ESPRIT People love flawlessness. Therefore the lighting producers do not take only their light and technical properties into consideration but also their overall design. Where an attractive look is combined with modern technology also inanimate
PARASIT by Eliška Dudová
objects acquire a new dimension. Let us call it esprit.
The designer´s assumption is the need of individualisation in lighting for the future – interactivity and for enabling consumers to enjoy more exciting experiences with lighting scenes. The concept of luminaire is designed to offer functional, a wide range of lighting scenes.
To breathe spirit into the inanimate objects is the basic ambition of the current industrial design. In the area of luminaire manufacturing it means the effort of the luminaire designers for an innovative connection of shapes and functionality. Today the modern materials and technologies enable countless numbers of variations which can be modified according to the client’s vision. The new, design dimension of the luminaire production has also been revealed by the designers and users of the school buildings. They do not only emphasise the functionality when selecting the lighting fixtures but alsow the ability to add interest to individual parts of the interior, to contribute to their specific atmosphere or to represent. Although there are no quantifiable criteria for assessing the quality, it is important to respect a few rules in the creative process. They are as follows: overall impression of the luminaire, luminaire appearance in the room, detailed solution, surface finish, material of construct parts, functional elements. The company OMS has responded to the design demands for the space illumination by creating an in-house department of research and development in the framework of which the “court” designers in collaboration with technical departments and the students of the Academy of Fine Arts and Design in Bratislava, specialisation industrial design, are working on the development of new design luminaires using the latest technologies. The result of this collaboration is series of the design and highly functional luminaires falling into the category of futuristic visions.
ESPRIT
OLED by Ján Štofko
REAL SKY by Ján Štofko
The OLED technology indicates a great potential to change completely our view at the lighting system. Who would not like to sketch a shape of a optical part on a tablet?
REAL SKY ceiling is unique futuristic concept, that moves the daylight inspiration step ahead. These organic flowing light waves will create spectacular sky experience above your heads. LED light sources,together with the moving grid behind the elastic ceiling, are programmed to create various sceneries and moods. This high-end solution is suitable for the most ambitious clients with the passion for unique interiors.
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EXCEPTIONALITY
Our company has long-run know-how and an above-standard technical background at our disposal. It is able to respond flexibly to all customer needs and to offer them full support when solving the illumination.
“No man is an island unto himself”, the master of literature Ernest Hemingway wrote. In business this simple truth is valid twice as much. The key to success of
PROJECT
(pre-installation services)
any manufacturing enterprise today is not only high quality products and modern technologies. It is first of all satisfied customers. The company OMS approaches every customer individually and offers him/her exceptional lighting solutions as well. Today offering the market a quality product is by far not enough. During recent years the customers have become more and more demanding and, more than a quality product, they are looking for complex solutions. This is also valid for the customers in the segment of lighting. Today their requirements are not satisfied only by a simple purchase of a luminaire. They are looking for opportunities how to save, to achieve an adequate return on investments and to make profit resulting from the usage of the latest technologies. Our company has long-year know-how and an above-standard technical background at our disposal. Thanks to this fact it is able to respond flexibly to all customer needs and to offer them full support in all phases when solving the illumination: from working out a project, through its
SERVICE
(after-installation services)
realisation, installation of lighting up to the service and customer adjustments. The key word in the time period when we face permanent rise of energy prices is the economy of solutions. Therefore every new project starts with the energy audit of lighting which provides the basic material and values for the energy certification of the building. Its goal is to acquire a sufficient amount of information concerning the state and efficiency of the existing lighting system, to identify the potential for energy saving and to suggest concrete measures how to achieve them and to reduce the energy demandingness of the spaces audited. Based on the audit of the lighting system the experts of our company prepare recommendations for our client where they quantify the extent of possible savings and prepare a concrete proposal how to achieve them.
PROJECT
Energy audit of lighting
Lighting measurements
Complete lighting project
Measuring the energy consumption
Lighting design
INSTALLATION
Luminaires / management
Installation
EXCEPTIONALITY
INSTALLATION
Adjustment
Selecting the luminaires and accessories
Lighting calculation
Electroproject
Design of emergency lighting
Complete lighting management system
SERVICE
Energy certification of buildings and lighting
Operational service
Electroproject issue of fact
Emergency lighting
Programming the system
54/55
We provide complex service when designing both interior and exterior lighting. Where others see obstacles we see solutions. Our department Lighting Solutions has necessary knowledge and technical means for lighting measurements at our disposal. It will carry out the technical inspection of the installation, measurement of lighting intensity and illuminance in the client’s premises and will evaluate up to what level the quality complies with the legal requirements and standards. Through measuring the energy consumption of the existing lighting system it will identify the place of insufficient efficiency and losses and will work out a complete lighting project for the customer that is tailor-made to the their needs and requirements on energy saving. Together with the clients we work out a design of the overall solution of the space illumination and provide them support when they select the luminaires. Our company has a wide portfolio of luminaires at our disposal that we are able to customise if necessary according to client’s specific requirements. By high-level software we will calculate the optimal parameters of a new lighting system and work out an electro-project whose part is also the lighting system’s
EXCEPTIONALITY
We have been providing complex services for designing the interior and exterior illumination for almost 20 years. Where others see obstacles, we see a lighting solution. Our philosophy is not based only on simple following the trends. We have decided Our long-run experience, strong to be trendsetters in our sector. A great number of customers in technical background and em- more than 120 countries worldwide prove that we are success. phasis on the research and development of new technologies enable us to provide the clients with full support when they are selecting the most effective lighting management system. Besides the standard tools including the daylight, presence and constant illumination sensors we offer our own lighting management system through the intelligent system Central Power Source developed by the engineers of our company. As a modern enterprise we have also been able to respond to the trend of managing the lighting systems through iPad, Android and smartphones. Our programmers and designers programme applications tailormade for every client. In the after-project phase we provide services of Energy Certification of Buildings which documents the energy demandingness of the building with the new lighting solution. electric connection scheme and programming the lighting management systems.
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Light in the school SPORT FACILITY OUTDOOR SPORT FACILITY teacher room
TABle COMPUTER ROOM
Stock rooms
Laboratory and workshops
library
lecture theaters
corridors and communications
CLASSROOM
OUTDOOR PARKING DINNIG ROOM refreshment and canteen
entrance hall
CLASSROOM Reception
TABle
kindergarten 58/59
For ensuring the performance efficiency and visual wellbeing of the pupils we recommend to maintain in the classes the minimal illuminance level 500 lux. Classroom The modern teaching process places high demands especially on the visual perceptions. The correct lighting of the space where the teaching process takes place has a decisive influence on the pupils´ performance efficiency and their capability to concentrate. A strict organisation of the working space in the classrooms belongs to the past. The layout of the desks changes in dependence on the needs of the teaching process and enables the pupils to carry out both the individual and group tasks. Therefore the basic requirement which is currently laid on the lighting system in the classroom is the uniform lighting ensuring the users the same good light conditions for every activity. The layout of the desks plays an important role from the point of view of ergonomics. It is recommended to place them rectangular to the window for the daylight to fall on the working plane laterally. This solution prevents the undesirable glare and lower sharpness of vision. The European standard EN 12464-1 determines the minimal illuminance level 300 lux for the task area (i.e. the desk), for the classrooms for evening classes and spaces determined for education of adults the minimal illuminance value 500 lux. However, our experience from practice has shown that the normative requirements are insufficient and therefore for ensuring the optimal performance efficiency and the visual well-being of the pupils
Classroom
we recommend to maintain the minimal illuminance level of the working plane 500 lux also in common classrooms. Our experience and research shows that the required illuminance of all surfaces in the classroom can be achieved with luminaires with the direct and indirect characteristic of the luminous flux distribution that lead 50 % of the direct light to the working surface and 50 % of the diffuse light upwards to the ceiling. Through this solution we achieve the optimal illuminance of the working plane 500 lux, the vertical illuminance of the walls 300 lux and the illuminance of the ceiling 300 lux. The indirect diffuse component of the light simultaneously enables modelling the objects better; it ensures the cylindrical illuminance of the faces and in this way their recognition and reduces the rise of sharp shadows deteriorating the visibility. This lighting solution also fulfils the requirement for harmonious distribution of brightness in the classroom space. The variedness of the working tasks and the need of an interaction between the pupils and teachers or the board force the students to pass their vision from one to another object. The unequal distribution of brightness places higher demands on the eye’s adaptation ability which adapts to the average, the so called adaptation luminance. It causes rapid fatigue, loss of concentration and reduction of performance efficiency. When planning the lighting system it is important to create homogeneous light environment without any distinctive differences of the brightness intensity. Almost all classrooms
MODUL LAMBDA DIR-INDIR PARV2 2x54W 120
120
200 150 100
105
MODUL LAMBDA
105
90
90
75
75
60
60 cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
The luminaires with the direct and indirect characteristic of the luminous flux distribution which leads 50 % of the direct light to the working plane and 50 % to the ceiling represent the ideal lighting solution for ensuring the required illuminance level in the classrooms.
have a wall with windows. The availability of the daylight is also in this type of space desirable. Therefore the artificial light in the classrooms should be controllable to complete the daylight when necessary. That is why the usage of the daylight sensor should be considered. At the same time it is necessary to prevent the undesirable glare and to fit the windows with a system of blinds or curtains. From the point of view of savings these classes currently
represents an unused potential. The expenses for lighting represent up to 40 % of the costs necessary for the performance of the school building. Through replacing the old luminaires with new ones and installing the elements of the lighting management system (e.g. the daylight sensor completed with the presence sensor) the saving of energy up to 75 % can be achieved.
The recessed luminaires with louver with the direct characteristic of the luminous flux distribution are not suitable for the classrooms. We will not achieve the sufficient illuminance of the ceiling.
The suitable light conditions with sufficient illumination of the vertical surfaces and ceiling can be achieved by recessed luminaires with a specially shaped ejected diffuser.
The linear suspended luminaires with the direct and indirect characteristic of radiation will ensure the required illuminance of the working plane and sufficient vertical illuminance of the surfaces. The most ideal solutions are those luminaires which lead 50 % of the luminous flux directly to the working plane and 50 % of the indirect components are led to the ceiling.
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125
CLASSROOM
Indirect LG
Gacrux
Lambda
ERGONOMICS
Modul Box Max
Indirect LG
i
SCHEME SCHEME
COMPONENTS COMPONENTS
Accent lighting
INDIRECT LG PV L1PAR-V2 FDH G5 3x24W
enhance visual properties of an illuminateobject.
Availability of daylight
RELAX PV POLISHED ASYMMETRIC REF FDH G5 2x28W
bringing natural conditions into interior by maximizing the use of daylight, thus minimizing operating costs.
Switch
Switch
Modul Box Max
ERGONOMICS
i
EMOTION
EMOTION
i
i
Vertical illumination Ceiling illumination Biological factor of illumination Availability of daylight Bluelight content (Tc>6500K) Daylight simulation Dynamic lighting Tunable white Accent lighting RGB colour mixing Ambient lighting
Vertical illumination Ceiling illumination Biological factor of illumination Availability of daylight Bluelight content (Tc>6500K) Daylight simulation Dynamic lighting Tunable white Accent lighting RGB colour mixing Ambient lighting
ECOLOGY
ECOLOGY
i
EFFICIENCY i Presence detector
BENEFITS BENEFITS BENEFITS
normal movement of
enhance visual properties of an illuminated object.
R8 Photo cell dimmin
Availability of daylight
Tue
Wed
Working hours / day:
7
Thu
Fri
Sa
Working hours / night:
Sun
Power consumption
2790
[kWh/year]
Power consumption with LMS
2790
[kWh/year]
LENI
1
[kg/year]
0 41.03
EM
0 % EC
EF
ENERGY SAVING
G
2.36
GACRUX PV PRISMA LED 3900lm/840 1x52W
Daylight simutation
lighting installation with impact on well being of humans, installation contains of light management system that is slowly changing colour temperature during a day, thus simulating natural conditions in interior. lighting installation with impact on well being of humans, installation contains of light management system that is slowly altering light level during a day, thus simulating natural conditions in interior.
Push button
EFFICIENCY i Presence detector
R3 Auto ON/Dimmed
Constatnt illuminance sensor Daylight sensor Calling of lighting scenes
Mains (230V)
Push button
Data line
Sensor Remote controler
Mon
Tue
Wed
Working hours / day:
normal movement of R8 Photo cell dimmin
7
Thu
Fri
Working hours / night:
Sa
Sun
Power consumption
2008
[kWh/year]
Power consumption with LMS
745
[kWh/year]
CO2 savings
770
[kg/year]
LENI
10.96
1
[kWh/year.m2]
A ER
Remote controll
Tunable white
lighting installation with impact on well being of humans. Luminaires in installation are equipped with two white colour temperatures, warm and cold. It is possible to change the proportion between them and mix the requsted colour temperature.
i
Latest lamp technology LED System efficacy of luminaire Thermal output of lamp Dangerous material content Product life-time and maintenance costs
Working days:
RELAX ASYMMETRIC 1x47W LED
Dynamic lighting
[kWh/year.m2]
ER
COMPONENTS COMPONENTS COMPONENTS
bringing natural conditions into interior by maximizing the use of daylight, thus minimizing operating costs.
Working days: Mon
SCHEME SCHEME SCHEME
Accent lighting
R3 Auto ON/Dimmed
Constatnt illuminance sensor Daylight sensor Calling of lighting scenes
CO2 savings Mains (230V)
Lambda
Colour rendering index (CRI) Glare prevention Illumination level (task area) Illumination level (surrounding of task area) Lighting uniformity Harmonious distribution of brightness
Latest lamp technology classic System efficacy of luminaire Thermal output of lamp Dangerous material content Product life-time and maintenance costs
BENEFITS BENEFITS
Gacrux
Colour rendering index (CRI) Glare prevention Illumination level (task area) Illumination level (surrounding of task area) Lighting uniformity Harmonious distribution of brightness
EM
63 % EF
ENERGY SAVING
EC
4.04
Power supply for the DALI line
Constatnt illuminance sensor
reduce the use of artificial light in the early life lighting system
Daylight sensor
sensor reduce the use of artificial light in interiors when natural daylights is available
Calling of lighting scenes
lighting system allows to program several lighting scenes, which can be launched anytime by using of different user interfaces.
Using a luminaire with the direct and indirect characteristic of the luminous flux distribution ensures a sufficient illuminance level. The indirect component of the light led upwards illuminates the ceiling at the same time. This fact has a positive effect on the psychological and visual well-being of the pupils. In this way we induce the impression of daylight and it positively reflects on the students´ concentration. By a correct layout of luminaires with a wide illuminance curve we can achieve high
values of the vertical lighting. This is very important from the point of view of the children’s safety. The lighting system utilises here the conventional technology of the light sources - the fluorescent lamps. That is the reason why we achieve the below-average values in the chapter ECOLOGY, especially in the part system efficacy of the luminaire where the effectiveness of the light source achieves only 45 lm/W. On the market there are solutions that are able to improve the lighting quality substantially
Classroom / LQS COMPOSER
and first of all to reduce the energy intensity of the lighting system. The saving potential reaches the value of 80 % here. The lighting system used has too large of energy consumption and from the point of view of energy economy we assess it with the mark G.
The used recessed luminaires do not disrupt the ceiling design and represent a simple but effective solution by which we also achieve the sufficient illuminance level. The diffuse characteristic of the light suppresses the occurrence of undesirable shadows which would deteriorate the visibility especially when we are writing. Thanks to the usage of microprism we reach a very low glare factor UGR 19 which is very important especially from the point of view of safety and the psychological as well
Combined motion and illuminance sensor
as visual comfort of the pupils. The correct layout of the luminaires ensures sufficient vertical and cylindrical illuminance. The sufficient illumination of the walls increases the ability of the students to orient themselves in the space and makes recognising the space and objects easier. Correct modelling of the objects (e.g. the edges of the desks) improves the pupils´ safety. By implementing the functionality daylight simulation we have created optimal conditions for concentrated work and problem-free
perception of the information for the students and teachers. In the chapter ECOLOGY we achieve above-average values in all parameters. Utilising the LED light sources and the latest technologies of the luminaires is assessed by the highest score. The system contains the lighting management system in the form of the constant and daylight sensor. The high availability of daylight enables to reach the savings of energy consumption up to 63 %. In the total assessment of effectiveness according Energy
Performance of Building we belong among the most effective class A. The resulting LQS value confirms that the lighting system achieves the above-average quality.
62/63
The correct luminance level on the presentation surfaces will create contrast conditions which will enable the pupils to perceive the depicted information from every angle of vision. Table and presentation area
by the forced adaptation to the changed luminance level, it is necessary to ensure correct vertical lighting of the presentation surfaces and uniform distribution of brightness on the presentation surface and its surrounding (maps, flipcharts). The correct luminance level will create optimal contrast conditions which will enable the pupils to perceive the information of the presentation surface from every angle and ensure sufficient visibility of the depicted information also for the students sitting in the last desks. Due to the fact that the board is an aid which is not utilised permanently in the teaching process, it is desirable for the illumination of the presentation surface to be controllable and could be switched off independently.
Correct and sufficient vertical lighting of the board and presentation surfaces is a guarantee of correct perception of information and at the same time it protects the pupils against inadequate fatigue. The boards, white-boards, flipcharts and projection screens currently belong among the standard outfit of the classrooms. Their utilisation in the educational process does not principally differ; however, the method of their illumination is different. The standard EN 12464-1 recommends the average vertical illuminance 500 lux and it states a minimal value of 0.7 for the lighting uniformity. If the board is movable or has wings, the stated values have to be fulfilled on the whole presentation surface. For illuminating the presentation surfaces we most frequently use the asymmetric luminaires placed 0.85 to 1.3 metres from the presentation surface. When we solve the illumination of the board the colour and type of material of the presentation surface play an important role. Our experience from practice shows that pupils perceive information depicted on a blackboard written with white chalk better. The black surface has low reflectance and the contrast between the white and black colour creates better conditions for the visual comfort. However, the reality is that the modern schools more and more frequently
use the white glossy board. They place higher demand on the illumination as they are surfaces with higher reflectance and therefore they represent a higher risk for the rise of undesirable reflections which cause deteriorated visibility of the information depicted. A cor-
rect layout of the luminaires can prevent this problem. The different properties of the black and white presentation surfaces require for the designer to create a lighting system always for a particular space and type of board which located there. When using the presentation
surfaces actively the pupils and teachers change their angle of vision when they transfer their look from the desk to the presentation surface and this can cause vision fatigue when the luminance is distributed in the room incorrectly. For the eye not to be strained permanently
0.85 – 1.3 m 0.5 – 0.7 m
For illuminating the presentation surfaces we use most frequently the asymmetric luminaires placed 0.85 to 1.3 metres from the presentation surface.
TABLE AND PRESENTATION AREA
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LINE RANGE ASYMMETRIC
132
MODUL LAMBDA
125
In the computer room it is very important to prevent undesirable glare and reflection on the screens.
COMPUTER ROOM The computer competence is assigned such a great importance today as the knowledge of foreign languages or natural sciences. Therefore today computers are an inseparable part of the educational process. The rooms where the lessons on the PC screens take place have increased demands on the illumination of the space. Besides the main lighting it is important to think about the correct vertical illumination of the walls and ceiling of the computer room. The package with recommendations of the British designers – Lighting Guide 7 (LG 7) – states the ratio 50 % for the illumination value of the vertical surfaces compared with the working plane, for illuminating the ceilings 30 % of the working plane illuminance. The suspended linear luminaires with the direct and indirect radiation of the luminous flux are an ideal solution for this type of space.
light sources and correct layout of the luminaires. In the rooms with availability of daylight it is due to the same reason to fit the windows with systems of curtains or blinds. The minimal shielding angles of the light sources and the value of the psychological glare admissible for the computer rooms are adapted by the European standard EN ISO 9241-307. The interactive teaching process in the computer rooms where the vision is permanently transferred from the PC monitor to the teacher and vice versa requires a uniform distribution of brightness in the room. Too much of a contrast luminance
in the individual levels of the space could represent a burden for the eyes and could cause fast fatigue of the pupils. If the computer room is equipped with a projection screen and an overhead projector and the teaching process is realised through multimedia presentations, it is important to dim the lighting to the required intensity or to switch off completely part of the lighting system.
123
LINE RANGE ASYMMETRIC
132
hellos as
134
As the computer rooms are spaces without a permanent occurrence of persons, it is suitable to consider some tools of the lighting management system due to energy savings.
Compared with other classrooms in the computer room it is very important to prevent undesirable glare and reflection on the screens. The optimal conditions can be achieved by the sufficient shielding of the
The recessed luminaires with louvers – see the figure 1 – do not provide sufficient illuminance of the vertical surfaces and ceiling. At the same time they represent a risk of arising undesirable reflections on the screens due to the indirect glare. The recessed or suspended luminaires with the direct and indirect characteristic of radiation with diffuse surface or microprism represent an optimal solution.
COMPUTER ROOM
MODUL quark II
68/69
COMPUTER ROOM
Indirect LG
Gacrux
Lambda
ERGONOMICS
Modul Box Max
Indirect LG
i
Colour rendering index (CRI) Glare prevention Illumination level (task area) Illumination level (surrounding of task area) Lighting uniformity Harmonious distribution of brightness
EMOTION
Gacrux
Lambda
Modul Box Max
ERGONOMICS
3 8 2
EMOTION
i
SCHEME SCHEME
COMPONENTS COMPONENTS MODUL LAMBDA DIRINDIR PAR-V2 FDH G5 1x49W
Availability of daylight
bringing natural conditions into interior by maximizing the use of daylight, thus minimizing operating costs.
Vertical illumination Ceiling illumination Biological factor of illumination Availability of daylight Bluelight content (Tc>6500K) Daylight simulation Dynamic lighting Tunable white Accent lighting RGB colour mixing Ambient lighting
ECOLOGY
ECOLOGY
i
R3 Auto ON/Dimmed
Constatnt illuminance sensor Daylight sensor Calling of lighting scenes
COMPONENTS COMPONENTS MODUL BOX MAX MICROPRISMA CDP LED DIR/INDIR 73W 5300lm 4000K 80RA
bringing natural conditions into interior by maximizing the use of daylight, thus minimizing operating costs.
R8 Photo cell dimmin
Daylight simulation
Power consumption
1268
[kWh/year]
lighting installation with impact on well being of humans, installation contains of light management system that is slowly changing colour temperature during a day, thus simulating natural conditions in interior.
Power consumption with LMS
1141
[kWh/year]
Dynamic lighting
Wed
Working hours / day:
CO2 savings LENI Mains (230V)
SCHEME SCHEME
Availability of daylight
normal movement of
Working days: Tue
7
Thu
Fri
Working hours / night:
77 16.78
Switch
Sa
Sun 1
[kg/year] [kWh/year.m2] ER
10 %
EM
B
lighting installation with impact on well being of humans, installation contains of light management system that is slowly altering light level during a day, thus simulating natural conditions in interior.
Tunable white EF
ENERGY SAVING
i
Latest lamp technology LED System efficacy of luminaire Thermal output of lamp Dangerous material content Product life-time and maintenance costs
BENEFITS BENEFITS
EFFICIENCY i Presence detector
Mon
Switch
i
Vertical illumination LG7 Ceiling illumination Biological factor of illumination Availability of daylight Bluelight content (Tc>6500K) Daylight simulation Dynamic lighting Tunable white Accent lighting RGB colour mixing Ambient lighting
Latest lamp technology ECO System efficacy of luminaire Thermal output of lamp Dangerous material content Product life-time and maintenance costs
BENEFITS BENEFITS
i
Colour rendering index (CRI) Glare prevention Illumination level (task area) Illumination level (surrounding of task area) Lighting uniformity Harmonious distribution of brightness
EC
2.58
lighting installation with impact on well being of humans. Luminaires in installation are equipped with two white colour temperatures, warm and cold. It is possible to change the proportion between them and mix the requsted colour temperature.
Daylight sensor
sensor reduce the use of artificial light in interiors when natural daylights is available
EFFICIENCY i Presence detector
R3 Auto ON/Dimmed
Constatnt illuminance sensor Daylight sensor Calling of lighting scenes
normal movement of R8 Photo cell dimmin
Working days: Mon
Tue
Wed
Working hours / day:
7
Thu
Fri
Working hours / night:
Sa
Sun 1
Push button
Remote controll Mains (230V)
Push button
Data line
Sensor
Power consumption
1334
[kWh/year]
Power consumption with LMS
659
[kWh/year]
CO2 savings
412
[kg/year]
LENI
9.7
[kWh/year.m2]
A ER
Remote controler
Power supply for the DALI line
EM
51 % EF
ENERGY SAVING
EC
3.66
Combined motion and illuminance sensor
Calling of lighting scenes
lighting system allows to program several lighting scenes, which can be launched anytime by using of different user interfaces.
The luminaires used with the direct and indirect characteristic of the luminous flux distribution ensure the required level of the illuminance and at the same time they illuminate the ceiling sufficiently. Thanks to the combination of the direct and indirect light there are good conditions for good modelling of the objects (e.g. monitor, desk, mouse). This type of luminaires also achieves an excel-
lent lighting uniformity. The lighting sumption. The resulting LQS value – system used achieves the above2.58 – expresses the standard quality average levels of illumination on the of the lighting system. walls (approximately 264 lux) and ceiling (300 lux). From the ecological point of view the system is fitted with a more effective fluorescent lamp (type T5 – energy saving). Thanks to which it reaches the same luminous flux as the classical fluorescent lamp FDH T5, however, at a lower con-
COMPUTER ROOM / LQS COMPOSER
The luminaires used with the direct and indirect distribution of the luminous flux ensure the required level of the illuminance and at the same time they illuminate the ceiling sufficiently. Thanks to the combination of the direct and indirect light there are good conditions for good modelling of the objects (e.g. monitor, desk, mouse). This type of luminaires also achieves an excellent lighting
uniformity. Thanks to the microprism used, the luminaire shows a very low level of the glare – UGR 15 and it is an ideal illumination for the computer rooms. The luminaire also fulfils the requirements of the standard EN ISO 9241-307 for the VDU workstation applications that determines that there must not be higher luminance than 1,500 cd/m2 in the angle of 65°. By implementing the functionality
daylight simulation we have created optimal conditions for concentrated work and problem-free perception of information both for the pupils and teachers. We achieve above-average values in all parameters in the chapter Ecology. The usage of LED light sources and the latest luminaire technologies are assessed by the highest score. By implementing the daylight sensor we have been able
to achieve a saving of energy up to 51 %. The above-average LQS values confirm the quality of the lighting system used. The computer room is ranked in the energy class A and reaches an excellent value of LENI 9.7 kWh/year.m2.
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For the basic illumination of the lecture theatre it is suitable to use the light sources emitting the light of neutral white colour with the correlated colour temperature 4,000 K. Lecture theaters In the modern higher (e.g. university) educational premises the lecture theatres fulfil a multifunctional task. They are used for lectures, social events as well as multimedia performances. From this point of view we place higher demands on the lighting solution especially concerning their comprehensiveness and flexibility. The lighting system in a structure space of the lecture theatre has to be adapted to its structure. The individual groups of luminaires have to offer adequate lighting value in the zones they are determined for and at the same time induce an atmosphere in compliance with type of the event. For the basic lighting of a lecture theatre it is suitable to use sources emitting homogeneous, non-glare light of neutral white colour with the correlated colour temperature 4,000 K. It supports the impression of the space openness, creates condition for concentrated work and enables the students to work out their notes. For the illuminance of the task area we have a stated value of minimally 500 lux, the lighting of the surrounding task area and the background is to reach
Lecture theaters
the value minimally 300 lux. For this purpose it is suitable to use the suspended luminaires with the direct and indirect luminous flux distribution or the built-in ceiling luminaires with a wide luminous intensity curve. When designing the lighting system in the case of a tiered auditorium, it is inevitable to ensure the same lighting intensity at any point of the space. This demand can be met by placing an increased number of luminaires over the lowest desks. The harmonious distribution of brightness in the space of the lecture theatre can prevent excessive fatigue. The demonstration area plays an important role in the lecture theatre. The standard EN 12464-1 determines a value 1.5 times higher than the main lighting of the auditorium has for its illuminance. The board or projection screen in the demonstration area requires an independent solution. The normative requirement for their illuminance – 500 lux – can be fulfilled by placing an asymmetric luminaire 0.85 to 1.3 m from the presentation surface. For the purposes of the multimedia presentations or events when documents or films are projected, it is inevitable for the individual groups of the luminaires to be dimmed or fully switched off independently. At the same
time, during these events it is important to ensure the basic visibility in the space due to the orientation and safety. It can be achieved by placing the additional controllable luminaires on the walls. The adequate vertical illuminance contributes to a better orientation feeling. If there is a staircase in the lecture theatre, it is inevitable to illuminate the individual steps by the recessed floor luminaires. Placing the safety and emergency lighting and adequate marking the escape routes is adjusted by the standard EN 1838. The variedness of the roles fulfilled by the lecture theatre in dependence on the type of the event requires an effective utilisation of the lighting management system tools. Through implementing the tool - calling of lighting scenes - it is possible to choose the preselected scene for any type of event by using a simple control -pushing a button. In the halls where the daylight is available it is effective to consider the installation of the daylight sensor. The windows are to be fitted by a system of curtains and blinds. The variedness of tasks and activities which are performed in the lecture theatres require the implementation of the lighting management intelligent tools. By using the tool – calling of the lighting scenes – and pushing a button of the simple control we can choose the pre-selected scene for any type of event.
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AVANT LINE
127
AVANT ASYMMETRIC 127
In the workshops it is suitable to use luminaires fitted with electronic control gears to avoid the rise of the stroboscopic effect during operations with rotational tools. Laboratory and Workshop rooms The education of the natural sciences and development of practical skills are part of the teaching process at many schools. The learning process of this type of subjects is based on observing and practical experiments. The correct lighting of the space creates optimal conditions for teaching and at the same time the level of safety is increased. The education in the area of physics, biology or chemistry as well as development of the practical skills in the workshops cannot be realised without practical experiments and handling of tools. The experimental labs and workshops place extraordinary high demands on the solution of the lighting system. The correctly designed lighting system has to comply with the illuminance parameters stated by the standard and simultaneously has to create such light conditions which contribute to the safety of these spaces. The European standard EN 12464-1 determines the minimal illuminance 500 lux for the labs and workshops and the more demanding the visual RELAX XTP LED
tasks to be realised in the specialised room are, the higher its value has to be. It is important to prevent the rise of undesirable glare and reflections from the glossy surfaces and to avoid sharp shadows. The optimal light conditions can be achieved by using the suspended luminaires with a larger part of the indirect radiation which are the source of soft diffuse light and will ensure sufficient vertical illuminance. For better concentration of the pupils it is suitable to use the light sources emitting cold white light. The experiments in the labs of natural science place increased demands on the correct identification of colours of chemicals, wires or connectors therefore from the point of view of safety it is inevitable to use the luminaires with a high colour rendering index – CRI >90. It is suitable to use luminaires with a housing made of unbreakable material which does not change its photometric properties. When solving the lighting system in the workshops it is important to avoid the stroboscopic effect when the artificial lighting is on. The stroboscopic effect represents extreme danger especially when we work with rotational tools because at the
same frequency and rotational speed, an impression that the tool is off can develop and it can cause serious injuries to the user. The stroboscopic effect can be prevented by installing the LED luminaires or high-frequency control gears emitting the light with such a frequency that the human eye is not able to notice and therefore he/ she perceives it as permanently continuous. If overhead projectors or computers are used in the lab or workshop during the educational process, it is suitable to design the lighting system in such a way that one part of the luminaires can be independently switched off or dimmed. Through implementing the tool - calling of lighting scenes - it is possible to choose the pre-selected lighting scene by using a simple control -pushing a button, necessary for carrying out the corresponding type of activity.
143
When selecting the luminaires for the labs and workshops it is necessary to take into account several factors at the same time. It is suitable to use luminaires with the protection level IP 54 or IP 65 in these spaces. In the workshops where there is a higher risk of injuring by moving rotating or reciprocating machines the luminaires should be fitted by electronic control gears to prevent the rise of the stroboscopic effect.
Laboratory and Workshop rooms
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CLASSIC XTP
135
The luminaires in the gym have to be resistant against the impact of a ball or to be protected by a cover.
Sport facilities The gym and playing field provide space for relax and physical activities in every school facility. Their utilisation for various types of sport activities requires variable solutions of the lighting system. The most important criteria, when planning the illumination of the sports grounds, are the intensity and uniformity of the lighting, low glare and good rendering of colours. The heterogeneity of the sports places an additional demand on the lighting management – it has to correspond with the sport activity or event carried out that takes place in the spaces of the sports ground. The individual types of sport and events require various levels of lighting. Their values are stated by the European standard EN 12193 which states the value of 200 lux for the majority of sports at the level of a lesson or training. The standard adjusts the minimal illuminance according to the speed of the individual type of sport and divides them to three groups. The group C has the highest demands on the illuminance level (300 to 500 lux) – this includes e.g. tennis, squash, hockey, floorball. At the same time it adjusts the minimal illuminance for competitions. If we organise a higher or international competition in the gym or at the sports ground, the minimal illuminance is increased up to 500 – 700 lux. In the case of ball games, the requirement on the minimal illuminance is in direct proportion to the size of the ball. The smaller the
SPORT FACILITIES
ball and the faster the sport is, the higher illuminance rate we require. When planning the lighting system the basis is the sport activity placing the highest demand on the lighting quality. The required illuminance levels, lighting uniformity and low glare can be achieved by correct selection and deployment of the luminaires. The recessed ceiling or ceiling surfaced luminaires with sufficient protection against impacts and with shielding (e.g. with a louvre) which avoids undesirable glare are suitable. In the gyms with high ceilings it is possible to use linear suspended luminaires. The white neutral light with the correlated colour temperature CCT 4,000 K is ideal lighting for the sports grounds. An additional criterion when selecting the luminaires for playgrounds is the resistance against impacts. They are especially the luminaires with the certificate DIN VDE 0710-13 which confirms they fulfil the requirements on the resistance for the indoor playgrounds. These luminaires have to be resistant against the impact of a ball and to have a cover which will prevent the fall of the fragments to the ground if the luminaire is damaged. The luminaire tested has to resist 36 impacts of the ball from three directions at the maximum speed 60 km/h and the ball has the size of a handball. The utilisation of the gym for various types of sports and school events requires involving into the lighting solution an intelligent management system which enables e.g. dimming the individual groups of lighting fixtures or using
the adjusted lighting scenes. In the gyms with availability of daylight it is recommended to use the daylight sensor due to the economy. Because this is a space without permanent presence of persons, we recommend using the presence detector which will switch the lighting off if the gym is not being used. The selection of the light source plays here an
important role. From the point of view of economy, life span and demands placed on the maintenance the LED source is an ideal solution.
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UX-MYAR
149
CLASSIC ASR PAR
135
When planning the illumination of the sports facilities, intensity and uniformity of the lighting are the most important criteria.
UX-PETRO R SYMMETRIC
150
The changing rooms in the sports premises require a special solution. The emphasis is especially laid on the correct vertical illumination which helps recognising the clothing in the lockers. To ensure that the clothing and sports dresses will be recognised well, it is suitable to use the light sources with a sufficient colour rendering index CRI 80. Similarly as the gym the changing room is a space without permanent occurrence of persons. By installing the presence detectors we ensure the illumination of changing rooms when it is really necessary and in this way we achieve the optimal energy consumption.
From the normative point of view there are not high demands on the illuminance level in the changing rooms. However, it is important to ensure sufficient vertical illuminance of the lockers and to create conditions for appropriate recognising the colours.
SPORT FACILITIES
The swimming pool places extremely high demands on the illumination. Due to safety it is inevitable to use only special water-proof luminaires determined for lighting the swimming pools. When designing the lighting system, it is necessary to solve not only the lighting in the surrounding of the swimming pool but also lighting of its interior. Without lighting the internal surfaces of the swimming pool the water surface reflecting the light from the external lighting would perform as a mirror and would cause undesirable glare. For the illumination of the swimming pool’s internal surfaces it is good to use the recessed luminaires located on the walls of the pool.
For reaching an optimal intensity and uniformity for lighting the outdoor sports grounds we recommend to use high-performance column lighting by luminaires with a narrow luminous intensity curve. To avoid creating sharp and long shadows they are placed in the corners of the playground or at its edges. The luminaires are to be placed in such a way that every point on the playground is illuminated minimally from two places. The undesirable glare can be prevented by installing the luminaires in sufficient height.
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UX–stadio mars
150
UX-PETRO R SYMMETRIC
150
Lighting requirements for sport areas, tasks and activities EN 12193 INDOOR sports
Horizontal illuminance Em (lux)
CRI
Note
U0
Basketball
200
0.5
20 No luminaires should be positioned in that part of the ceiling, which is above a 4 m diameter circle around the basket.
Floorball
200
0.5
20
Football
200
0.5
20
Handball
200
0.5
20
Volleyball
200
0.5
20 No luminaires should be positioned in that part of the ceiling, which is directly above at least the net area.
Wrestling
200
0.5
20
Dancing
200
0.5
20
Gymnastics
200
0.5
20
Tennis
300
0.5
20 No luminaire should be positioned in that part of the ceiling which is directly above the area limited
by the rectangle of the marked area extended to 3 m behind the base lines.
Swimming
1. Diving-Additional reqirement Ehavg / Evavg = 0.5
200
0.5
20
2. The above are general requirements only. Special requirements can be needed for individual pools
Badminton
300
0.7
20 No luminaires should be positioned in that part of the ceiling witch is above the principal area.
Table tennis
300
0.7
20
OUTDOOR sports Athletics (all activities)
Horizontal illuminance CRI Em (lux) 100
GR
Note
U0 0.5
55
20
1. Horizontal illuminance can be reduced to 50 lux for running events 2. For discus, javelin and hammer special precautions shold be taken to ensure the safety of persons within the
stadium since the object being thrown maytravel above the line of light and hence be invisible
during part of their flight.
Tennis
200
0.6
55
3. The vertical illuminance at the finishing line should be 1,000 lux for photo-finish equipment and officials.
20
Running Street / Cross Country 3
0.1
-
-
Cycle racing
100
0.5
55
20
Ice hokey
200
0.5
-
20
American football
75
0.5
55
20
Basketball
75
0.5
55
20
Floorball
75
0.5
55
20
Football
75
0.5
55
20
Handball
75
0.5
55
20
Volleyball
75
0.5
55
20
Golf driving range
100
0.8
-
20
Swimming
200
0.5
-
20
The vertical illuminance at the finishing line should be 1,000 lux for photo-finish equipment and officials
Vertical illuminance on Distance Marker (at 1 m height) 1. The above are general requirements only. Special requirements can be needed for individual pools. 2. No underwater lighting should be used.
Em = average illuminance in lux (maintained value) U0 = lighting uniformity UGR = UGR limit (direct glare limitation) GR = glare rating limit (upper limit of glare) CRI = colour rendering index of lamps
Lighting requirements for sport areas, tasks and activities EN 12193
12/13
Suitable conditions for concentrated work in the teacher’s room can be achieved by the light sources emitting the light of neutral white colour. TEACHER’s ROOM
Teacher’s office
The teacher’s room and the teacher officials represent in the school premises a background determined for group meetings and individual preparation of the teachers. Their correct illumination creates suitable conditions for concentrated work.
The teacher’s offices in the school facilities create the teachers backgrounds for preparation of teaching or self-study.
At school premises the teacher’s room is a space determined for meetings and information exchange between teachers. The tasks are assigned here; they plan, realise and assess the school projects as well as the performance of the pupils. The standard EN 12464-1 determines the minimal illuminance level 300 lux for the teacher’s room. The required normative level can be achieved by using the luminaires with the direct and indirect characteristic of the luminous flux distribution which also gives sufficient illuminance of the walls and ceiling. For creating optimal conditions for concentrated work we recommend using the light sources producing the light of neutral white colour with the correlated colour temperature CCT 4,000 K. If there is a presentation surface in the teacher’s room, it is necessary to use the additional luminaire with an asymmetric luminous intensity curve. Its placement 0.85 to 1.3 metres from the presentation surface we ensure its sufficient vertical illuminance. The heterogeneity of the activities carried out in the teacher’s room creates a potential for utilising the programmable lighting scenes. Implementing the lighting management system
TEACHER’S ROOM
tool – calling of lighting scenes – we can simply choose and release the selected scene by simple pushing a button on the control panel. As the teacher’s room is a space with availability of the daylight, it is suitable to consider installing the daylight sensor due to optimisation of the energy consumption.
The classical solution of the lighting with recessed luminaires with a parabolic louvre ensures sufficient illumination of the workplace but the upper parts of the walls and the ceiling remain dark. Such illumination causes a feeling of a cave effect and makes the room optically smaller.
Optimal lighting solution in this space is represented by suspension luminaires with direct and indirect characteristics of the luminous flux distribution. The indirect diffuse light helps to model objects, it reduces indirect glare when the light reflects from the PC screen or the shiny surfaces in the room.
A similar result as with the suspension luminaires with direct and indirect characteristics of the luminous flux distribution can be achieved with recessed luminaires with a specially shaped diffuser.
From the normative point of view it is necessary to maintain the minimal illuminance level 300 lux in these spaces. Currently the most frequently used lighting solutions are the recessed luminaires with louvers which are, however, unsuitable from the ergonomic point of view. This type of luminaires cannot achieve the sufficient illuminance of the walls and ceiling. The dark walls and ceiling cause the rise of the so called cave effect which can affect the teachers in a depressive way. The ceiling surfaced or suspended luminaires with the direct and indirect characteristic of the luminous flux distribution which reach sufficient vertical as well as horizontal illuminance represent a suitable solution. Thanks to this solution even the space of a small teacher’s office is larger and lighter. For achieving constant visual conditions we also recommend completing the lighting system by standard lamps or table lamps which serve for illuminating the task area. In this way we also reach the required illuminance 500 lux. Similarly, as in the case of the teacher’s room, it is suitable to use the light sources producing neutral light of white colour with the correlated colour temperature CCT 4,000 K. In the teacher’s offices equipped with the VDU workstations it is necessary to avoid undesirable veiling reflections
on the monitor during work with PC which reduce the contrast of depicted information and make reading difficult. The rise of undesirable reflections can be prevented by choosing appropriate types of the luminaires (the luminaires with low luminance are suitable) and their suitable layout. By placing the desks rectangular to the windows for the sunshine to fall onto the desks from side and fitting the windows by a system of blinds or curtains we simultaneously reduce the risk of the glare from the sunshine. From the point of view of the energy consumption the teacher’s offices have a big potential for savings. Due to the fact that it is a space with a good availability of daylight, it is suitable to use the function of the daylight sensor. The teacher’s offices are also spaces without permanent occurrence of persons. Thanks to this fact it is possible to make use of the presence detector which ensures switching on and off in dependence on the fact if the room is just being used.
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MODUL CLEARANCE 122
To prevent excessive noise it is recommended to use the luminaires with passive thermal management.
LIBRARY
cent lamp luminaires with the magnetic control gear do not emit any sounds. Digitalising of information has digitising changes in the form of the VDU workstations to the libraries. Also for these zones the standard EN 12464-1 determines the illuminance rate 500 lux. Similarly as in the whole library space here it is desirable to avoid any undesirable glare as well. It can be prevented by correct selection of luminaires emitting non-glare light or correct shielding and locating the light source. In the spaces with availability of daylight we should not forget to fit the windows with a system of blinds and curtains which prevent direct glare caused by sunshine. The availability of daylight in the majority of the library spaces contributes to the overall visual and psychical well-being of people and at the same time it gives an opportunity (when we utilise the lighting management system, e.g. daylight sensor) to achieve substantial energy savings. When solving the library lighting the question of a correct selection of the light source comes to foreground. The paper documents, magazines and books are sensitive to the ultraviolet radiation therefore the LED light sources which are the only not to emit it are considered the best choice in this type of space.
Libraries are an inseparable part of the educational process. When designing their lighting system it is inevitable to take into account aspects which characterise this type of space. For the lighting system designers it means not only designing the adequate main lighting but also the illumination of the reading area, shelves and VDU workstations.
modul box freestanding
146
The European standard EN 12464-1 determines the value 500 lux for the workplaces and spaces of the library for reading. The suitable solutions are the recessed or suspended luminaires with the direct and indirect luminous flux distribution, ensuring uniform lighting and harmonious distribution of brightness in the room. It is suitable to use additional table or free-standing luminaires for illuminating the surfaces determined for reading and work. The neutral white light with the correlated colour temperature 4,000 K induces a pleasant atmosphere in the space, for a better recognition of colours we recommend to use the luminaires with the colour rendering index CRI 80. The library spaces are also sensitive to noise; therefore it is suitable to prefer luminaires with passive thermal management which in difference to the fluoresWhen designing the library lighting system the emphasis is laid also on the vertical illumination of the racks and shelves. The correctly illuminated racks ensure sufficient visibility of the books from the highest shelf to bottom one. The linear suspended luminaires with the direct and indirect radiation component, located along the aisles between individual book shelves are considered a suitable solution. The standard EN 12464-1 determines the minimal illuminance 200 lux for the racks.
LIBRARY
From the point of view of safety we must not forget about marking and lighting the escape routes and exits in the library. Marking has to be visible from every place in the room. The parameters of the emergency and safety lighting are adjusted by the standard EN 1838.
86/87
AVANT par-V2
124
The multifunctional utilisation of the canteen requires a flexible solution of the lighting system.
REFRESHMENTS AND CANTEEN
improving the vertical space illuminance it is possible to place the wall-washers directly on the walls which will take care of pleasant colour accents on the coloured walls. In the canteen and café spaces it is recommended to use luminaires with sources emitting warm white light which creates a pleasant relaxing atmosphere and gives the human skin a more natural tone. For the colour of the meal and the food to remain as truthful as possible, it is necessary to use the luminaires with a high colour rendering index CRI >90. Due to the fact that the canteens and cafés are located at the periphery of the building and have sufficient availability of daylight, it is recommended due to the energy economy and efficiency to use the tool management system daylight sensor. The multifunctional utilisation of the canteen space for social events requires a flexible solution of the lighting system. When designing it, it is reasonable to count on the function “calling of lighting scenes” which will complete the atmosphere of a social event by a mere push of the button.
way contribute to the welcoming atmosphere. The standard EN 12464-1 determines the value 200 lux for the main lightThe catering establishment ing of the catering establishin the school facilities plays ments. It is suitable to use the a specific role. As a matter of fact, besides refreshments suspended linear luminaires with the direct and indirect this space also provides component of radiation or the possibility for recovery and ceiling luminaires with the direct socialising. The illumination and indirect component of has to meet this mission. radiation which will sufficiently illuminate also the vertical surThe illumination in the caterfaces and ceiling. When there ing establishments should be is a stable layout of the tables, designed to create a positive it is suitable to deploy the lumicommunication atmosphere (besides meeting the normative naires in such a way that they requirements). The time people will copy the communication spend in these spaces is mostly paths in the canteen (café) and will make the orientation in the limited therefore the recovery effect of the illumination on the space easier. The main lighting human well-being should come can be completed by suspended luminaires placed over individual in the shortest possible time. tables. If they were to affect Through the combination of the space in a disruptive way, the natural light, daylight and alternative can be the a suitable artificial light in the buffet and luminaires with a narrow lumicanteen areas we can create nous intensity curve directed an impression as if they were literally filled by light and in this straight over the table. For TUBUS PHACT
118
The suspended luminaire over the table is to be placed for the distance between the table surface and the bottom edge of the luminaire to be approximately 60 centimetres. If there are persons sitting at the table, the luminaire will be over their eye level and will not cover part of the face of people sitting opposite. It is good to use luminaires made of opaque or coloured glass. If the suspended luminaires were to give a disruptive impression, they can be replaced by a downlight with a narrow luminous intensity curve directed straight to the table.
REFRESHMENTS AND CANTEEN
For lighting the kitchens of the mass catering establishments the standard EN 12464-1 determines the minimal illuminance level 500 lux. The luminaires have to possess sufficiently high colour rendering index CRI, to be resistant against high temperatures, vapour and chemicals. It is recommended to use unbreakable luminaires over the area for preparing meals or luminaires protected by a special cover which will prevent the fragments from falling onto the meals if the luminaire is damaged.
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caph
141
TORNADO PC LED
149
CANTEEN
Classic
Modul Box Square
DW 224
Castor
Line range
ERGONOMICS
Caph
i
Classic
Colour rendering index (CRI) Glare prevention Illumination level (task area) Illumination level (surrounding of task area) Lighting uniformity Harmonious distribution of brightness
EMOTION
Modul Box Square
DW 224
Castor
Line range
ERGONOMICS
Caph
EMOTION
i
SCHEME SCHEME SCHEME
COMPONENTS COMPONENTS COMPONENTS
RGB colour mixing
MODUL BOX SQUARE SURFACED MICROP CDP LED 4100lm/830 1x52W. LED DRIVER DALI
possibility to set up not only exact colour but also brightness and saturation of the colour.
Ambient lighting
show details of ceiling and enhance atmosphere of room
Vertical illumination Ceiling illumination Biological factor of illumination Availability of daylight Bluelight content (Tc>6500K) Daylight simulation Dynamic lighting Tunable white Accent lighting RGB colour mixing Ambient lighting
ECOLOGY
ECOLOGY
i
ArcLine Optic40 MC21°x36° bringing natural conditions into interior by maximizing the use of daylight, thus minimizing operating costs.
Tue
Wed
Mains (230V)
Touch panel
6
Fri
Working hours / night:
Sun
1477
[kWh/year]
Power consumption with LMS
1477
[kWh/year]
0 8.21
Touch panel
Data line
Sa
Power consumption
LENI
lighting system allows to program several lighting scenes, which can be launched anytime by using of different user interfaces.
R8 Photo cell dimmin
Thu
1
EL-DOWNLIGHT COMET MOTION 40°LED 1300lm/830 1x18W, LED DRIVER
[kg/year] [kWh/year.m2]
Push button EM
D
Mains (230V)
Push button
Data line
Sensor Remote controler
EC
EF
ENERGY SAVING
EFFICIENCY i Presence detector
R3 Auto ON/Dimmed
Constatnt illuminance sensor Daylight sensor Calling of lighting scenes
normal movement of R8 Photo cell dimmin
Working days: Mon
ER
0 %
COMPONENTS COMPONENTS CAPH MICROPRISMA CDP LED 2400lm CRI90 1x45W, LED DRIVER DALI
normal movement of
Working days: Mon
CO2 savings
Calling of lighting scenes
SCHEME SCHEME
R3 Auto ON/Dimmed
Constatnt illuminance sensor Daylight sensor Calling of lighting scenes
i
Latest lamp technology LED System efficacy of luminaire Thermal output of lamp Dangerous material content Product life-time and maintenance costs
BENEFITS BENEFITS
EFFICIENCY i Presence detector
Working hours / day:
Availability of daylight
i
Vertical illumination Ceiling illumination Biological factor of illumination Availability of daylight Bluelight content (Tc>6500K) Daylight simulation Dynamic lighting Tunable white Accent lighting RGB colour mixing Ambient lighting
Latest lamp technology LED System efficacy of luminaire Thermal output of lamp Dangerous material content Product life-time and maintenance costs
BENEFITS BENEFITS BENEFITS
i
Colour rendering index (CRI) Glare prevention Illumination level (task area) Illumination level (surrounding of task area) Lighting uniformity Harmonious distribution of brightness
Tue
Wed
Working hours / day:
6
Thu
Fri
Working hours / night:
Sa
Sun 1
Power consumption
1512
[kWh/year]
Power consumption with LMS
769
[kWh/year]
CO2 savings
457
[kg/year]
LENI
4.24
[kWh/year.m2] ER
Remote controll
2.36 3.12
58 %
EM
B
EF
ENERGY SAVING
EC
3.47
Power supply for the DALI line
Combined motion and illuminance sensor
In this lighting system we used the luminaires Modul Box Square with LED technology. The space is illuminated uniformly and without any disruptive shadows. The luminaires used are of non-glare character and achieve a low value UGR 90. These luminaires achieve sufficient illuminance level 204 lux with uniformity 0.614 (compared to the required 200 lux with uniformity 0.4). Thanks to the Tunable White technology we are
able to reach the simulation of the daylight. The implementation of this technology is based on the knowledge that the natural daylight is most suitable for the visual and psychological well-being of the pupils. The daylight is not monotonous; it changes its properties in dependence on the season of the year and daily cloudiness and this fact causes that its intensity and correlated colour temperature change. All these factors affect the perception of the space and the objects inside of it. The
objective of simulating the daylight is to achieve light conditions in the canteen space which copy the properties of the daylight as truthfully as possible. In the lighting system used, we made use of the accent lighting which helps localising important parts of the space and in this way it simplifies understanding and system of catering. The accent lighting concentrates the attention e.g. to the board with the daily offer of meals and drinks. As this is a space with availability of daylight, we used the
daylight sensor from the accessible lighting management tools – with this tool we are able to reach up to 50 % saving of energy. The resulting efficiency of the lighting system is expressed by LENI = 4.2 kWh/year.m2 which means that the lighting system used ranks to the energy class B. The resulting value LQS 3.47 expresses that through this system we achieve the above-average quality of lighting.
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The correct illumination of the corridors will make the orientation in space easier and will increase the safety during the transfer of pupils.
plastic PLAST H
137
Corridors and Communication
zones with availability of the daylight). High demands in the school spaces are laid on the lighting of the staircases. It is important to ensure sufficient visibility of the individual steps and to prevent the rise of undesirable reflections and glare during the movement upwards and downwards as well. The recessed floor and wall luminaires are an ideal solution. From the point of view of safety it is inevitable to install the emergency lighting which in the case of a power cut will ensure the minimal illuminance level necessary for safe movement of persons around the building on the staircase and the corridors as well.
of the task area and surrounding area when designing the lighting system. The suspended luminaires with the direct and In the schools the commuindirect component of radiation nication zones connect the over the working desk of the entrance with foyer, individual floors and classrooms. permanent service, possibly completed by a table or freeThrough their correct illumination we can achieve quick standing luminaire will ensure the receptionist optimal workorientation in the space, ing conditions. The corridors contribute to the feeling of at schools not only represent overall well-being and last but not least increase safety. connecting lines between individual levels of the building and rooms but also the space where The entrance, reception, and the pupils gather during breaks. foyer represent the place of The correct lighting of the corrithe first contact at schools. dors will simplify the orientation When planning the illuminain the space and will contribute tion it is necessary not only to the overall feeling of comfort to think about fulfilling the of persons who are moving in standard but we have to the school spaces. The sufficient think of creating a positive vertical illuminance of surfaces welcoming atmosphere and if is considered one of the most necessary this space is to fulfil important criteria for lighting the representation role. The recessed luminaires with a wide corridors. The insufficiently illuminated walls and ceilings luminous intensity curve and create the cave effects and light sources radiating warm cause depressive impressions. white light could be a suitable It is suitable to use luminaires solution. If the reception is part of the foyer or a reception with a wide luminous intensity curve or suspended luminaires desk with permanent service, it is necessary to also take into with the direct and indirect luminous flux distribution which account appropriate lighting
The school utilises the corridors often as a communication tool and places there information boards, message boards, pieces of work of its students or awards from various competitions. For highlighting these objects it is appropriate to use the accent lighting in the form of luminaires with a narrow luminous intensity curve or the wall-washers.
will sufficiently illuminate all corridor surfaces. The corridors belong among the spaces utilised during the breaks where the students transfer between classrooms and lecture rooms. In this situation considerable reduction of the adaptation luminance represents the greatest risk – it develops when transferring from the space illuminated by 500 lux (classroom) to a space with significantly lower illuminance 100 lux (corridor). To prevent injuries during a sudden transfer to worse light conditions, it is recommended to make this transfer softer.
Corridors and Communications
In practice we achieve this by using additional luminaires or placing these luminaires directly over the classroom door. The communication zones in the school premises are spaces without permanent occurrence of persons and have a considerable saving potential. A correctly selected lighting management system tool enables the school to achieve significant energy savings. The presence detectors are suitable tools in the school communication zones (e.g. corridors and lockers) and possibly the daylight sensors (for the communication
rebeLl
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118
CORRIDOR
DW S211
DW Noviel
Line range
ERGONOMICS
Plast
i
DW S211
Colour rendering index (CRI) Glare prevention Illumination level (task area) Illumination level (surrounding of task area) Lighting uniformity Harmonious distribution of brightness
1 3 0
EMOTION
DW Noviel
Line range
ERGONOMICS
Plast
EMOTION
i
SCHEME SCHEME
COMPONENTS COMPONENTS
Accent lighting
DOWNLIGHT NOVIEL POLISHED REF LED 2100lm/830 1x25W, LED DRIVER, 9003
enhance visual properties of an illuminateobject.
Availability of daylight
Vertical illumination Ceiling illumination Biological factor of illumination Availability of daylight Bluelight content (Tc>6500K) Daylight simulation Dynamic lighting Tunable white Accent lighting RGB colour mixing Ambient lighting
ECOLOGY
ECOLOGY
i
R3 Auto ON/Dimmed
Constatnt illuminance sensor Daylight sensor Calling of lighting scenes
Mon
DOWNLIGHT PROXIMA 170 LED POLISHED REF LED 1900lm/830 1x31W
Presence detector
passive infrared sonsor that reacts on movements. It is switching luminaires on to a pre-programmed level by occupancy of the room and switching luminaires off by absence of persons.
BENEFITS BENEFITS
EFFICIENCY i Presence detector
Mains (230V) Data line
Sensor
Combined motion and illuminance sensor
Tue
Wed
Working hours / day:
Thu 11
R8 Photo cell dimmin
Sa
636
[kWh/year]
350
[kWh/year]
CO2 savings
175
[kg/year]
LENI
5.83
[kWh/year.m2]
A ER
sensor reduce the use of artificial light in interiors when natural daylight is available.
45 % EF
elements in the corridor: the boards with timetables or diplomas or showcases with awards gained by the pupils of the school. Thanks to the LED light sources used we gain the best possible marks in the category Ecology. The LED light sources are an ideal solution for the schools also from the point of view of safety. They are light sources which compared to the conventional light sources contain negligible amounts of heavy metals (e.g. mercury). Moreover,
2.92
CORRIDOR / LQS COMPOSER
energy and therefore the lighting system is assessed by the mark A.
normal movement of R8 Photo cell dimmin
Mains (230V)
Push button
Data line
Sensor
Remote controll
Remote controler
Wed
Thu 11
Fri
Sa
Sun
Working hours / night:
1
Power consumption
1368
[kWh/year]
Power consumption with LMS
596
[kWh/year]
CO2 savings
471
[kg/year]
LENI
9.93
[kWh/year.m2]
A ER
EM
56 % EF
ENERGY SAVING
Calling of lighting scenes
lighting system allows to program several lighting scenes, which can be launched anytime by using of different user interfaces.
they contain them only in the solid state, so even when the light source is damaged they do not present any danger of breathing in the harmful vapours for the pupils. The lighting management system in the form of the presence detector is integrated in the system – it is able to achieve up to 30 % energy savings. The resulting quality of the lighting system is on an average level, however, at the same time it creates conditions for the maximal utilisation of the electric
Push button PLASTIC PLAST H OPAL FDH G5 1x49W, ECG
Tue
Working hours / day:
EC
Switch
The luminaires with microprism are used for the main lighting and thanks to this the lighting fixtures have a wide luminous intensity curve without any undesirable glare. The luminaires have a low value of UGR6500K) Daylight simulation Dynamic lighting Tunable white Accent lighting RGB colour mixing Ambient lighting
Latest lamp technology LED System efficacy of luminaire Thermal output of lamp Dangerous material content Product life-time and maintenance costs
BENEFITS BENEFITS
i
Colour rendering index (CRI) Glare prevention Illumination level (task area) Illumination level (surrounding of task area) Lighting uniformity Harmonious distribution of brightness
The luminaire thanks to the sine curve of the luminous intensity achieves very high values of the vertical illuminance and this fact makes the orientation of the pupils in the space much easier. The system fulfils the criteria LG7 for lighting the interiors. From the emotional point of view the system contains the RGB ambient light in the supporting poles of the corridor and in this way it draws the pupils´ attention to the danger of injury. This solution highlights the
EC
3.31
ArcLine Optic 40 MC21°x36°
dangerous places in the corridor, e.g. the edges, etc. This makes the student’s eye save and remember the area where an obstacle is placed. In the category Ecology we gain an average quality here. The fluorescent lamps FDH (T5) used contain mercury in gaseous state and when the light source is damaged there is a danger of breathing in the harmful vapours. The system is fitted with the lighting management system in the form of the daylight sensor
which can bring savings of the energy consumption amounting up to 56 %. The implemented lighting system is of an excellent quality and has an above-average level in the category of effective utilisation of the electric energy. Thanks to these parameters we can rank this lighting system to the class A.
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Correctly planned and carefully maintained emergency lighting can prevent an outbreak of panic, injuries and even save lives. SAFETY AND EMERGENCY LIGHTING
The battery pack LED luminaires represent the optimal solution – the producers guarantee here the minimal lifetime of 50,000 In the spaces with an increased hours. In this way the maintenance costs are reduced and concentration of persons, rooms without any access of compared to other light sources the daylight and in the com- the user can save up to 70 % of munication zones determined the power consumption. for escape paths the safety and emergency lighting helps The effectiveness of the LED emergency lighting can be to solve collision situations and reduces the risk of injury. increased by installing the additional optics and reflectors which will reduce the number Regardless to the fact if it is of the LED luminaires when the a power cut, danger of fire or another crisis situation, the task legal standard is fulfilled. of the safety and emergency The requirement on the lighting is to ensure the pupils safety and emergency lighting basic visibility and orientation is adapted by the European during leaving the space or to standard EN 1838. The EN 1838 make their access to the fire standard specifies the minimum extinguishers easier. Correctly horizontal lighting needed to planned and carefully maintained emergency lighting can be 1 lux along the central axis of escape path that has to be at prevent an outbreak of panic, least 2 m wide. injuries and even save lives. When selecting the type of the emergency lighting the requirement on its long-term lifetime and the ability to fulfil its tasks at good visibility also during the power cut plays the most important role.
Emax
Emin
Emax
Emin
Emax
REQUIREMENTS ON EMERGENCY LIGHTING Illuminace Emin = 1 lux Uniformity Emax: Emin ≤ 40: 1 lux Colour rendering index CRI ≥ 40 Operating time 1 h Activation of lighting 50 %, or for required illuminance within 5 seconds, 100 % within 60 seconds
SAFETY AND EMERGENCY LIGHTING
During normal operation the illumination level of communications zones reaches prescribed levels. During the blackout or in case of fire emergency lighting ensures the pupils basic visibility and orientation during leaving the space or to make their access to the fire extinguishers easier.
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line snappy
132
EMERGENCY
147
DOWNLIGHT VISION LED
140
TUBUS VISION LED
134
The games determined for recognising colours require using light sources with the CRI value of more than 90.
kindergarten In the system of education kindergarten fulfils one of the most important missions. The children here learn to recognise the world. The way in which they can see it plays a key role in this process. The correct illumination of the space will enable them to understand it to the smallest detail. The children are driven by their own curiousness. The kindergarten is to give them the space to learn as much as possible about the world that surrounds them though they are in continual movement, during playing and larking around. The visual perception and imitation are the strongest tools through which the children are able to grasp the world around. The designed lighting system has to show it to them in the real shapes and colours. The decisive factor when selecting the luminaires for the kindergarten is therefore the type of the luminaire and the optimal value of the colour rendering index of the light source. For the overall lighting of the space we recommend using lighting fixtures with the direct and indirect radiation of the luminous flux. It is also important to take into account how the children play and move. As they often fall down and roll about intentionally on the carpet it is necessary to use such luminaires that do not glare and emit soft diffuse light. The creative games
aimed at correct recognising and assigning the colours place specific demands on the capability of the luminaire to show the coloured objects truthfully. Therefore it is appropriate to use the light sources with the colour rendering index CRI>90. During the day the majority of activities in the kindergarten take place in the day room. That is why the illumination here requires increased demands on the lighting flexibility. It is suitable to complete the main illumination by additional luminaires determined for various types of activities. The issue of safety is an important factor when we choose the lighting fixtures. Regarding the type of the facility for the children it is recommended to use unbreakable, covered luminaires which are resistant against impacts (e.g. by a ball). The freestanding or any other portable luminaires are considered unsuitable for the kindergarten premises. The majority of the kindergarten spaces have availability of the daylight and therefore it makes sense to consider the installation of the daylight sensors. In the day rooms determined for carrying out various activities from drawing through games up to the rest and relaxation it is good to implement the lighting management system – calling of lighting scenes – which enables starting a pre-adjusted lighting scene by pushing a button.
GACRUX
It is important to take into account how children play and move. As they often fall down and roll about intentionally on the carpet it is necessary to use such luminaires that do not glare and emit soft diffuse light.
In the rooms determined for relaxation it is good to implement the lighting management system – calling of lighting scenes, which enables to create a relaxing atmosphere by a simple pushing of a button.
kindergarten
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141
The balanced ratio between the light and the shadow improves the capability to orient in the space. FORSTREET SYRMA
148
External areas and Parking areas
towards the upper half-space and thus do not produce the light smog are a suitable solution. These requirements are met especially by the LED light sources. They are typical by high efficacy and effectiveness. Due to their low failure rate and long life span they do not represent any increased burden from the point of view of the maintenance costs. In difference to the traditional light sources, e.g. fluorescent lamps or discharge lamps, the LEDs reach the full luminance immediately, moreover, after a short power cut the full luminance is reached without any delay. For the illumination of the external areas and the parking area of the school it is possible to achieve full luminance immediately and this fact sig-
The external areas of the school represent a combination of the relaxation and communication zones and a space where the pupils can release their accumulated energy during the breaks. The correct illumination increases the safety especially during the winter months when the students move in the external areas and creates a positive mood. The task of the lighting designer when solving the external lighting is to achieve sufficient illumination of the horizontal and vertical surfaces without any dark places and differences of the luminance levels. This prevents the rise of sharp shadows which decrease the ability of the human eye to respond to the possible obstacles. The balanced ratio between the light and the shadow improves the capability to orient in the space. Sufficient cylindrical illuminance (minimally 1 lux) and enough diffuse light will make the recognition of faces easier. The illumination of the staircase should be paid special attention. The nonglare illumination that enables recognising the steps safely can be reached e.g. by using the recessed floor luminaires. The adequate general lighting of the external areas can be made by placing the pole luminaires with a wide luminous intensity curve. There are increased demands on their resistance against the temperature fluctuations, dust and water, ideally in an antivandal environment. It is recommended to use the luminaires
with IP 66 for this type of space. The accent lighting in the form of the recessed floor lighting fixtures with a narrow luminous intensity curve can emphasise interesting architectonic details of the school building. The lighting solutions also require porches above the entrance of the school which can be illuminated by luminaires with the direct characteristic of the luminous flux distribution. The more sophisticated solutions can also involve the ambient lighting and specific solutions of the green areas. The coniferous trees
External areas and Parking areas
and broad-leaved trees of light green colour become apparent in the light of the luminaires with sodium discharge lamps, the dark green trees in the light of the metal-halide lamps. Their suitable placement helps achieve a multicolour effect. From the point of view of the moving persons it is extremely important to pay increased attention to the illumination of the entrances, entryways, parking areas and zones where the routes of the pedestrians, bikers and motor bikers or car drivers overlap each other. The higher the traffic density is,
nificantly improves the safety of pupils´ and teachers´ movement in the school premises. In the external environment, the fact that in difference to the conventional sources there is no decline of efficiency at low temperatures and vice versa its effectiveness is even increased in such conditions, says in favour of the LED. From the point of view of safety it is a very resistant light source that can be hardly damaged, moreover also in the case of damage they do not constitute any threat for the health of the pupils and teachers. Compared to the conventional sources they contain a negligible amount of heavy metals which are, moreover, only in the solid state in the LED and this reduces the danger of contaminating the air.
the higher the risk of collision is. Sufficient visibility ensured by a higher lighting intensity reduces the risk of accidents. The rules for lighting the parking areas and communication zones in the external areas are adjusted by the standard EN 12464-1. When choosing the type of the light sources for the external lighting, the issue of ecological character and economy is coming to the foreground. From the ecological point of view, new types of luminaires that do not emit the light
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SELECTING THE RIGHT SOURCE The individual areas in the school building place different demand on the illumination. When designing a lighting system the task of the lighting designer is to choose the light sources with the most suitable parameters where besides the procurement price the categories of effectiveness, lifespan and safety are also included.
Colour rendering index (CRI) from-to
Power rating from - to (W)
Luminous flux from - to (lm)
Efficacy from - to (lm/W)
Light colour
Tube-shaped fluorescent FD (T8) Ø 26 mm
18 - 70
860 - 6,200
61 - 93
ww/nw/dw
80 - 96
G13
Tube-shaped fluorescent FDH (T5) Ø 16 mm
14 - 80
1,100 - 6,150
67 - 104
ww/nw/dw
80 - 93
G5
Compact fluorescent lamp 2 or 4 tube, elongated construction
5 - 57
250 - 4,300
46 - 90
ww/nw/dw
80 - 90
2G11 2G7
Compact fluorescent lamp 3 or 4 tube, compact construction
60 - 120
4,000 - 9,000
67 - 75
ww/nw
80 - 85
2G8-1
Metal halide - single-end mounting with ceramic technology
20 - 400
1,600 - 46,000
80 - 100
ww/nw
80-95
G12
Metal halide - single-end mounting with ceramic technology
70 - 250
5,100 - 25,000
73 - 100
ww/nw
80-85
PGJ5
Metal halide lamps - double-end mountings
70 - 150
6,800 - 14,500
86 - 115
nw/dw
88-95
RX7s
Tubular shape with ceramic technology and with reflector
45 - 315
2,200 - 128,000
96 - 120
nw/dw
82-90
GX8,5
High-pressure sodium - ellipsoidal shape
35 - 1000
2,200-128,000
63 - 139
ww
25, 65
PG12-1
High-pressure sodium - tubular shape
50 - 1000
4,400 - 130,000
70 - 150
ww
25, 65
GX12-1
3 -7
90 - 806
37 - 46
ww/nw/dw
80 - 90
GU10 E27
24-30
700 - 1,900
51 - 66
ww/nw/dw
70 - 90
G13
0.2 - 50
100 - 5,000
90 - 160
ww/nw/dw
70 - 98
-
Lamp type
LED retrofit
LED tubes Ø 26 mm
LED module
Socket
ww = warm white correlated colour temperature (CCT) below 3,300 K nw = neutral white correlated colour temperature (CCT) 3,300 K to 5,300 K dw = daylight white correlated colour temperature (CCT) over 5,300 K
SELECTING THE RIGHT SOURCE
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When in 1962 the American professor Nick Holonyak created the prototype of the first
The LED luminaires used in the schools have to fulfil high ergonomic and economic requirements. In the school they are required to deliver high-quality, glareless lighting for the optimal visual comfort also for the Visual Display Units (VDU) and at the same time they have to fulfil the requirements of the European standards. The LED diodes are primarily the source of the white colour radiation. The white LED light can be acquired by various methods; however, the principle of luminescence is most frequently used for its production. In this method a thin phosphorus layer is applied to the blue LED which, after the switching on of the source, changes part of the blue light which passes it into the white one. This technology of the LED production enables achieving the emission of the white light with various correlated colour temperature from 2,700 K to 10,000 K.
“light emitting diode” – LED, his invention remained almost unnoticed. The only one who anticipated its revolutionary future on the pages of the magazine Rider´s Digest was the inventor himself. It lasted almost forty years until the industry revealed all the exceptional properties of the LED and learned how to utilise them. In the lighting industry the LED sources currently represent an area that is developing in the most dynamic way. In what respect are the LED sources so exceptional and exceed the properties and parameters of the conventional sources? Why do the architects, developers and users of school buildings concentrate more and more frequently on the LED sources when designing the lighting systems? It would be possible to answer in a very simple way: The LED sources are highly effective, they have a long lifespan and an excellent colour rendering, they are cost-effective and environmentfriendly. But let us have a look at the individual categories more thoroughly and we will explain why the LED sources represent also for your school the best solution.
The LED sources are based on the semi-conductor basis. A very small amount of energy is necessary for emitting the light. The diodes emitting light consist of two types of semi-conductors – the N-type with surplus of electrons and the P-type which has lack of electrons (the so called holes). After connecting the power the excessive electrodes and holes begin to migrate to the PN junction. When they meet the recombination develops and the diode starts emitting a photon. By its size that is not larger than a dot made by a pencil the LED ranks among the smallest light sources. The package which is at the same time a lens serves
as protection. It enables distributing the luminous flux directly under the angle 15 to 180°. While a common light bulb is able to change into visible light only 5 % and the fluorescent lamp 30 % of the electric power, the LED with its ability to change up to 40 % of the total energy reaches incomparably better parameters in this category. The efficiency of the light source or its efficacy says with what efficiency the electric
energy is changed into the light, i.e. how much of luminous flux it produces fem. the electric input power (W) delivered to the light source. The unit is lumen per watt (lm/W). While the first LEDs in 1996 had an efficacy of 0.1 lm/W, today there are commercially available LED chips with an efficacy of 160 lm/W for cool white CCT LED and in the labs there has been achieved an efficacy of up to 254 lm/W.
Another method making it possible to acquire the white LED light consists of mixing the coloured light of various wavelengths. Through additive mixing the red, green and blue colours (RGB) the white light can arise. The advantage of this method is that besides the white light by targeted mixing we can also acquire coloured light. The disadvantage when acquiring the white light by the RGB technology consists in its demandingness. It requires a lot of know-how because the management of the coloured LED with various values of luminance is demanding and the white light produced often achieves lower values of the colour rendering index CRI 70 – 80. If we consider changes of the correlated colour temperature of the white light when solving the illumination in the schools, it is suitable to combine the coloured chips with white LEDs. In this way optimal CRI values are obtained.
Colours straight from the semiconductor LEDs do not require colour filters: their light comes in different colours produced directly by different semiconductor materials. Secondary colours are also possible. The major semiconductors are: Semiconductor material
Abbreviation
Colour(s)
Indium gallium nitride
InGaN
green, blue, (white)
Aluminium indium gallium phosphide
AlInGaP
red, orange, yellow
Aluminium gallium arsenide
AlGaAs
red
Intensity (counts)
LED for school Blue peak 4000 3500 3000 Yellow phosphor 2500 1500 1000 500 0 300 350 400 450 500 550 600 650 700 750 800 Wavelenght (nm)
White light can be produced by combining blue and yellow light only. Sir Isaac Newton discovered this effect when performing colour-matching experiments in early 1700 s. SpectrUM of white and coloured LEDs
watts
1,2
1,0
0,8
0,6
0,4
0,2
0
380
430
480
530
580
630
680
730
nanometres
LEDs do not require colour filters. The colour tone of the light is determined by the semiconductor material used and the dominant wavelength.
to 70 %, in some cases to 50 % is introduced as the LED lifespan end. It means that the LED failure rate is substantially lower compared to the conventional sources. However, appropriate cooling of the light source is a necessary condition for maintaining the lifespan parameters.
From the point of view of the lifespan the LED light sources achieve above-average parameters. Their lifespan moves in the values of up to 50,000 hours which represents 18 years for 11-hour-operation daily, 250 days a year. The drop of the light source performance Definition of lifespan luminous flux (lm)
Reflective cup Emitted light Molded epoxy lens
p-type GaN
Positive terminal
Active region
Gallium arsenide phosphide
GaAsP
red, orange, yellow
Negative terminal
n-type GaN
Silicon carbide
SiC
blue
Silicon
Si
blue
Anoded wire y 0,9
Anode lead Cathode lead
540
0,7
Hole
The lifespan of the LED sources
560
0,6 500
Electron
580
0,5 TC(K)
0,4
4000 3000
600 2000 1500
10000
moves in the values of up to 50,000
2500
6000
0,3490
620
hours which represents 18 years for
700 8
If the LED sources after binning are on the Planck curve, they emit “pure white”, i.e. pure white light.
LED for SCHOOL
0,2 0,1
100 %
75 %
50 %
25 %
0 %
Tc(2)
Tc(1)
T50(a) T T70(a)
T70(b)
50(b)
hours
520
0,8
Photon
480
11-hour-operation daily, 250 days
470
460 380 0,0 0,0 0,1 0,2
LEDs do not fail but the intensity of the light they produce diminishes over time. The lifespan (L) of an LED thus needs to be defined for different applications. For emergency lighting, for example, rating up to L80 or more are required, this means that the LED reaches the end of its service life when the luminous flux falls to 80 percent of the original flux measured. For general lighting, values of L50 or L70 are defined. The lifespan of an LED depends on a large extent on ambient and operating temperature. Where an LED is operated at a high temperature (Tc(1)) or with poor thermal management, its life is shortened.
0,3
0,4
0,5
0,6
0,7
0,8 x
a year.
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The experts estimate that if we replaced all existing light sources for the LED ones today, the energy savings worldwide could reach the amount of 30 %. If we realise that the artificial lighting consumes up to one fifth of the energy produced, this amount is not negligible at all.
LED for school
The LED source saving potential can be maximised by installing the intelligent lighting management which enables adjusting the radiation intensity of every luminaire in the lighting system automatically in dependence on the availability or intensity of the daylight. The environment-friendly approach is a topic also for the producer of the light sources today. The reality is that the majority of the conventional light sources cannot be produced without using the toxic heavy metals – lead and mercury. The users of the premises equipped with this type of light sources have an additional burden when they replace them as they are compulsory to remove the used or damaged sources in compliance with the law about disposal of the toxic waste and on the other hand they are exposed to the risk of breathing the toxic vapours when the light source is damaged. In this respect the LED sources represent an incomparably lower risk. Though they contain a small amount of heavy metals, they are in solid state and so there is no danger of breathing in the toxic vapours when the LED source is damaged.
Thermal management Similarly as in the case of other light sources, the temperature significantly affects the performance of the LED light source. Without any adequate thermal management overheating of the LED source can develop and it reduces its lifespan and the risk of its damage is also increased. Implementing a suit-
able cooling system we achieve maintaining the declared lifespan of the LED light source and its high efficacy. From this point of view the thermal management represents the most critical factor for the luminaires with the LED source.
Binning During the industrial production of LEDs deviations of the key parameters arise in the individual batches. In the framework of one batch the parameters are generally the same, but when we compare two various batches, the LEDs difference e.g. in colour or the luminous flux. To ensure the constant quality of light with the same level of luminance and colour of the light, it is inevitable to sort out every batch according to the value of individual parameters. This sorting is called binning. The main criteria taken into account when binning are as follows: the luminous flux measured in lumens (lm), the correlated
y
0,9
colour temperature measured in Kelvins (K); the forward voltage measured in volts (V). The LED sources are nowadays classified according to the binning standard ANSI. This standard defines the colour shades of LED by the MacAdam ellipses which depicts the colour deviation on the axis X and Y. The MacAdam ellipses shows how the colour of the individual LED modules can differ. The binning standard ANSI recommends for the resulting colours to be inside of the ellipse on the curve with four threshold values. The binning groups of the LED sources which show minimal differences of the values measured will produce the light of the same colour.
Cy
520
ANSI colour codes
0.43
0,8
540
spectral locus
0,7
0.38
560
0.33
0,6 500
580
0,5
TC(K)
4000 3000
2500
0.28 blackbody radiation curve
6000
0,4
2000 1500
10000
600
0,3490
620 700
8
In spite of higher purchase costs the LED sources represent in a longer-term horizon the most effective and economical light solution. The experts estimate that if we replaced all existing light sources for the LED ones today, the energy savings worldwide could reach the amount of 30 %. If we realise that the artificial lighting consumes up to one fifth of the energy produced, this amount is not negligible at all. When we take into account a smaller area, e.g. the classroom illuminated by obsolete conventional sources, we would be able to save up to 75 % of lighting system input power by the controlled LED illumination. All light sources also produce the IR radiation during the change of the electric power into the light which the human organism perceives as heat. However, the LED light sources produce it in a negligible amount compared to the conventional sources and thus they do not increase the inadequate costs for the airconditioning power consumption. The lifespan and failure rate of the LED sources reduces the lighting system maintenance costs as it does not require any regular interventions of service staff and purchasing new light sources.
0,2 0,1
line of purples
480 470 460
0,0 0,0 0,1
380
0,2
theoretical colours
0,3
0,4
0,5
0,6
0,7 0,8 x
0.27
0.32
0.37
0.42
Fluorescent IEC 60081 Planck Daylight ANSI 2700 ANSI 3000 ANSI 3500 ANSI 4000 ANSI 4500 ANSI 5000 ANSI 5700 ANSI 6500
0.47 Cx
The LED sources are mostly classified in compliance with the binning standard ANSI. ANSI defines the colour shades in the space xy of the Mac Adam ellipse. According to the standard the defined colours should be inside of the ellipse on the curve with four threshold values.
PWM control The Pulse Width Modulation (PWM) represents the most effective method how to check the intensity of the LED light source. The PWM principle is based on periodical switching on and off of the constant current directed to the LED. The resulting intensity of the LED light source is characterised by the ratio between the state of switching on and off. The frequency of switching on and off is adjusted for the human eye
On
50 % Duty-Cycle
On
Power
Off 0
to perceive the emitted light as a continuous luminous flux. Its intensity depends on the adjustment of the PWM cycle (0 % to 100 %). The advantage of the impulse width modulation is the maintaining of the constant correlated colour temperature in the whole range of dimming.
70 % Duty-Cycle
Power
20 Time (miliseconds)
40
Off 0
20 Time (miliseconds)
40
Compared with the conventional light sources the LED light sources reach the full luminance immediately. The immediate start of the LED source is a benefit from the point of view of safety and comfort. At the same time compared to the conventional sources, frequent switching on and off does not make any damage to the LED source and does not reduce its lifespan as well.
108/109
BASIC TERMS LUMINOUS FLUX Φ
EFFICACY η
2,700 K
The luminous flux is a physical quantity which states how much light in total a light source emits to all directions. It is the radiant power of the light source assessed from the point of view of the human eye sensitivity. The luminous flux expresses the ability of the radiant flux to cause a visual perception. The unit of the luminous flux is lumen (lm).
The luminous efficacy states with what efficiency the electric power is changed into the light, i.e. what proportion of the luminous flux is produced from the input power (W) delivered to the light source. The unit is lumen per watt (lm/W).
4,200 K
The correlated colour temperature of the light source determines the atmosphere in the room. It is defined by the correlated colour temperature of the light source expressed in kelvins (K). Low temperatures create a warm light, the high ones the cooler ones. The most used light colours are the warm white (over 3,300 K), the neutral white (3,300 to 5,300 K) and the day white colour (over 5,300 K). The warm white colour is predominantly used for emphasising the red and yellow colour. The blue and green colours become apparent at higher temperatures.
CORRELATED COLOUR TEMPERATURE (CCT)
The properties of light source colour rendering are given in the levels of the general index of colour rendering – Ra. The CRI gives the rate of the congruence of the object surface’s real colour illuminated by the considered light source under stated conditions of comparison. The smaller this difference is, the better the property of the colour rendering of the given source is. The light source with Ra=100 renders all colours completely equally as a standard light source. The lower the index Ra is, the worse the colour rendering is.
COLOUR RENDERING INDEX (CRI)
The Light Output Ratio is the share of the luminous flux coming out of the luminaire and the sum of the luminous fluxes from all light sources.
LIGHT OUTPUT RATIO (LOR)
6,500 K
LUMINOUS EFFICACY OF THE SOURCE LED High-pressure sodium lamp Metal halide lamp Linear fluorescent lamp Compact fluorescent lamp Mercury vapor lamp
CRI 70
Low voltage halogen lamp Incandescent lamp
0
20
40
60
80 100
120
140
160 180
200
220
240
Lumen/Watt (without ballast losses)
LUMINANCE L
LUMINOUS INTENSITY I
The luminance is the gloss of the shining or illuminated surface as the human eye perceives it. The unit is candela per square metre (cd/m2). This quantity gives the level of the luminous intensity over the specified surface area. The luminance of the illuminated surface depends in a great extent on its reflectance.
The luminous intensity is a physical quantity which states what volume of the luminous flux the light source (or luminaire) emits to the elementary space angle in the direction evaluated. The unit of the luminous intensity is candela (cd).
ILLUMINANCE E
This vector quantity states what amount of the luminous flux falls to the illuminated surface. The unit of the illuminance is lux (lx).
GLARE
If too great luminance occurs in the field of vision of the eye, its differences or the spatial or time contrasts which exceed the vision adaptability, the glare arises. During the glare the activity of the visual system is deteriorated.
BASIC TERMS
CRI 95
intensity distribution curve
110/111
PRODUCTS suspended
modular system
ceiling surfaced
ceiling recessed
rebell L led
118
tubus phact
118
tubus vision pendant led
118
tubus cygnus pendant
119
vega as exclusive
119
modul wings suspended
121
modul box 121 square suspended
hellos as suspended
121
CLASSIC XTP IP54
119
CLASSIC ASN ASYMMETRIC
119
CLASSIC ASN
120
classic 120 asn A1/a2/a3/a4/a5/a9
CLASSIC ASR II
120
modul box max
121
modul spiker
122
modul clearAnce
122
modul razzor
122
modul eye
122
modul ray suspended
123
modul quark II
123
modul rendo
123
avant led
124
avant
124
modul exe II led
modul exe II
125
modul en
124
line range 100 LED 125 suspended single piece
modul lambda
125
modul lambda max
125
modul box suspended
126
plastic plast h
126
modul Ray line
126
avant line led
127
avant line
line range 130 100 led suspended
line range 100 suspended
130
modul en line
131
modul lambda II line
131
line range 100 led surfaced
131
line range 100 surfaced
132
line snappy
132
relax H line
132
relax 133 line asymmetric led
line range pb 100 led
133
line range pb 100
133
PRESTIGE
tubus vision led
134
tubus cygnus
134
modul wings surfaced
modul box square surfaced
134
CLASSIC XTP ip54
135
CLASSIC ASR
135
CLASSIC ASR II
135
CLASSIC ASYMMETRIC
135
CLASSIC ASN
136
classic 136 asn A1/a2/a3/a4/a5/a9
modul lambda
136
modul lambda max
137
modul ray surfaced
137
downlight COMET motion
138
downlight avior motion
140
downlight square trimless
140
downlight quadro
141
caph
141
hellos
line snappy single piece
143
relax asymmetric led
143
PRODUCTS
127
128-129
SIMPLE SWAT
130
134
hellos as surfaced
134
modul box surfaced
136
plastic plast h
137
138
downlight proxima
138
downlight castra
139
downlight castor
139
downlight cygnus II
139
downlight mira
139
downlight propus
140
downlight vision led
140
downlight square
141
gacrux
141
vega PV exclusive
142
vega pv standard
142
saiph
142
terzo led
142
mirzam
143
relax xtp led
143
line range 143 pb 100 led single piece
124
114/115
PRODUCTS ceiling recessed
relax PV asymmetric
144
track system
vario track 11/12 led
144
vario track exe
144
vario track diffuse
145
wall mounted
wall cygnus
145
avant wall led
145
avant wall
146
freestanding
box freestanding
146
emergency
UX-emergency 2600
147
UX-emergency 2610
147
UX-emergency 2810
147
street Lighting
FORSTREET SIRIUS
148
FORSTREET ASTEROPE
148
FORSTREET SYRMA
148
industrial lighting
eco bay
149
tornado pc led
149
ux-myar
ARCHITAINMENT
arcpad xtreme
150
arcsource inground
150
arcsource twinwall
PRODUCTS
UX-emergency 2760
147
149
ux-petro s
149
ux-petro R
150
151
arcline optic led rgb
151
arcsource 96 integral
151
ux-stadio mars
150
116/117
suspended Suspended luminaires suitable for applications with high ceilings, where perfectly excels distribution of light. Luminaires with direct or indirect characteristic of radiation can with their shape and design complete the atmosphere of room. Luminaires can be fitted with several types of light sources. From the most
suspended efficient LED through metal - halide lamps to compact fluorescent lamps. According to the type of luminaire. Luminaires can be placed directly over the desired area of visual tasks and to provide sufficient illumination and required uniformity of lighting.
tubus cygnus pendant
Light source LED Optical system Diffuser Wiring Dimmable electronic control gear Housing: extruded aluminium, diffuser: opal plast Materials Surface finish grey (RAL 9006), other colors on request
TUBUS CYGNUS PENDANT OPAL LED 90° 1000lm 3000K 90
90
75
75 200
60
60
300
Type
rebell This exceptionally successful concept presented at Light+Building 2010 was specifically developed for high ceilings and open spaces. Its unique design with vertically perforated openings was inspired by the most famous global cathedral bells. This intelligent lighting solution allows for the distribution of both direct
rebeLl l led
REBELL L LED 50° 3500lm 4000K 90
90
75
75
500 750 1000 1250 1500
60 45
60 45
version basic1
version basic 2
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
version basic 3
version exclusive 1
version exclusive 2
tubus phact
TUBUS PHACT LED 36° 1900lm 3000K 90
version basic 4
90
75
75
800 1200 1600 2000 2400
60 45
60
15 0 C0.0-C180.0
45 15
Light source LED Optical system Reflector Transparent cover glass Wiring Dimmable electronic control gear DALI (5-100%) Materials Housing – upper part: injected polycarbonate Housing – bottom part: non-transparent/opal injected polycarbonate Reflector: anodized aluminium Trim: Injected polycarbonate Reflector cover: clear polycarbonate/hardened glass Surface finish Various color variants
Type
net lumen power output consumption (at Ta = 25 °C)
REBELL L LED REBELL L LED REBELL L LED REBELL L LED
30 C90.0-C270.0
tubus vision pendant led 90
75
75 200
60
60
300 45
1850 2050 3200 3500
31 31 53 53
83 83 83 83
net lumen power output consuption (at Ta = 25 °C) (lm) (W)
TUBUS PHACT TUBUS PHACT TUBUS PHACT TUBUS PHACT TUBUS PHACT TUBUS PHACT
90
(W)
correlated color temperature CCT (K)
thermal management
3000 4000 3000 4000
• • • •
vega as exclusive
1050 1050 1900 1900 2800 2800
Type
30
15 0 C0.0-C180.0
15
50° 50° 50° 50°
correlated color temperature CCT (K)
thermal management
CLASSIC XTP IP54
80 80 80 80 80 80
3000 4000 3000 4000 3000 4000
• • • • • •
TUBUS VISION PENDANT LED TUBUS VISION PENDANT LED TUBUS VISION PENDANT LED TUBUS VISION PENDANT LED
PRODUCTS
net lumen output (at Ta = 25 °C) (lm)
power consumption
1100 1100 2000 2000
net lumen output (at Ta = 25 °C) (lm)
power consumption
3600 3600
• • • •
45
45 cd/klm
30
PASSIVE
15 0 C0.0-C180.0
15
30 C90.0-C270.0
90° 90° 90° 90°
VEGA AS EXCLUSIVE LED 3600lm 4000K 90
90 75
75 100
60
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
55 55
>80 >80
4000 3000-5000
• •
60
150 200
45
250 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
PASSIVE
CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP
PASSIVE 36° 36° 36° 36° 36° 36°
Light source Linear fluorescent lamp FDH (T5)/FD (T8) Compact fluorescent lamp FSDH (TC-L) Optical system Parabolic louvre (PAR/PAR MAT), Diffuser (OPAL/PRISMA) Wiring Electronic control gear On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, parabolic louvre: polished/mat aluminium, cover: clear polycarbonate/clear hardened glass, diffuser: opal or prismatic polycarbonate, frame: elox aluminium Surface finish Housing: white (RAL 9003), other colors on request
Type
beam angle
Light source LED Optical system Reflector Wiring Electronic control gear, on request: dimmable electronic control gear DALI (10 - 100%) Materials Housing: polycarbonate, reflector: vacuum coated polycarbonate (polished/ white), decorative trim: sheet steel Surface finish Housing: upper part – white, bottom part – grey, other colors on request, Decorative trim: red, other colors on request Type
30 C90.0-C270.0
3000 4000 3000 4000
>90 >90 >90 >90
beam angle
LED Reflector, diffuser Dimmable electronic control gear DALI (10-100%) Housing: sheet steel, reflector: aluminum sheet, diffuser: acryl satine Housing: black (RAL 9005), reflector: white (RAL 9003)
INDIRECT VEGA AS INDIRECT VEGA AS
beam angle
CLASSIC asn ASYMMETRIC
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
15 13 28 26
80 80 80 80
3000 4000 3000 4000
• • • •
PASSIVE
optical system
power
PAR
PAR MAT
opal
prisma
(W)
• • • • • • • • • • • • • •
• • • • • • • • • • • • • •
• • • • • • • • • • • • • •
• • • • • • • • • • • • • •
2x36 3x18 4x18 4x36 2x28 2x54 3x14 3x24 4x14 4x24 4x28 4x54 3x40 3x55
lamp
CLASSIC XTP PAR FD 4x18W 90
90 75
75 100
60
60
150 220
45
45
250 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
CLASSIC XTP PRISMA FD 4x18W
lampholder 90
90
75
FD FD FD FD FDH FDH FDH FDH FDH FDH FDH FDH FSDH FSDH
G13 G13 G13 G13 G5 G5 G5 G5 G5 G5 G5 G5 2G11 2G11
Light source Linear fluorescent lamp FDH (T5)/FD (T8) Optical system Reflector (ASYMMETRIC) Wiring Electronic control gear On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, reflector: polished/mat aluminium Surface finish Housing: white (RAL 9003), other colors on request
75 100
60
60
150
45
45
200 30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
CLASSIC ASN ASYMMETRIC FD 1x36W 90
90
75
75
100 150 200 250 300
60 45
60 45
cd/klm
30
Type
45 cd/klm
10 10 15 15
thermal management
PASSIVE
color rendering index CRI (Ra)
15 13 28 26 50 46
Light source Optical system Wiring Materials Surface finish
700 700 1000 1000
correlated color temperature CCT (K)
45
The shape of this striking pendant luminaire suitably supplements every spacious public interior, hall, retail and cash point. Its design is reminiscent of the mouth of a fireplace and gives spaces a spirit of intimacy. The reflector made of highly-polished aluminium focuses the high luminous flux from the Fortimo DLM.
Type
TUBUS VISION PENDANT LED POLISHED 2000lm 3000K
(lm)
color rendering index CRI (Ra)
TUBUS CYGNUS/PENDANT TUBUS CYGNUS/PENDANT TUBUS CYGNUS/PENDANT TUBUS CYGNUS/PENDANT
Light source LED Optical system Reflector Wiring Electronic control gear, on request: dimmable electronic control gear DALI (10-100%) Materials Housing: sheet steel, reflector: anodized aluminium Surface finish Housing: RAL 9006 with metallic effect, RAL 9003 white on request
cd/klm
30
and indirect light flux. The luminaire is also manufactured in LED version. As well as the basic variant made in high-gloss and opal-gloss finish, it is also available in other exclusive colours that match designer’s ideas and interior architect’s requirements.
net lumen power color output consumption rendering (at Ta = 25 °C) index (lm) (W) CRI (Ra)
CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM
optical system REFLECTOR POLISHED MAT • • • • • • •
• • • • • • •
power
lamp
lampholder
FD FD FDH FDH FDH FDH FDH
G13 G13 G5 G5 G5 G5 G5
(W) 1x36 2x58 1x28 1x35 1x49 1x54 1x80
118/119
15 0 C0.0-C180.0
15
30 C90.0-C270.0
suspended CLASSIC ASN
CLASSIC ASN PAR-V2 FDH 4x14W 90
90
75
75 200
60
60
300 45
Light source Optical system Wiring Materials Surface finish
suspended Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel, parabolic louvre: polished/mat aluminium Housing: white (RAL 9003), other colors on request
MODUL BOX SQUARE SUSPENDED
45
Light source Optical system Wiring Materials Surface finish
LED Diffuser Electronic control gear On request: dimmable electronic control gear DALI (10-100%) Housing: sheet steel, frame: extruded aluminium profile Diffuser: PMMA OPAL + PMMA diamond microprisma Black (RAL 9005), silver grey (RAL 9006), other colors on request
MODUL BOX SQUARE LED 4100lm 3000K 90
90 75
75 200
60
60
300 400
45
45
cd/klm
cd/klm
30
15 0 C0.0-C180.0
15
30
30 C90.0-C270.0
Type Type
CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN
optical system
power
PAR-V2
PAR MAT-V2
(W)
• • • • • • • • • • • • • • • •
• • • • • • • • • • • • • • • •
1x14 1x24 1x28 1x35 1x49 1x54 1x80 2x14 2x24 2x28 2x35 2x49 2x54 2x80 4x14 4x24
lamp
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
net lumen power output consumption (at Ta = 25 °C) (lm) (W)
lampholder
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
MODUL BOX SQUARE MODUL BOX SQUARE MODUL BOX SQUARE MODUL BOX SQUARE
hellos as SUSPENDED
Light source Optical system Wiring Materials Surface finish
950 950 4100 4100
14 14 52 52
color rendering index CRI (Ra)
correlated color temperature CCT (K)
thermal management
>80 >80 >80 >80
3000 4000 3000 4000
• • • •
15 0 C0.0-C180.0
15
30 C90.0-C270.0
PASSIVE
LED Reflector + refractor Electronic control gear Housing: sheet steel, reflector: vacuum coated plastic Refractor: etched PMMA White (RAL 9003), other colors on request
HELLOS AS LED SUSPENDED 4300lm 4000K 90
90 75
75 300
60
60
450 600
45
45
750 cd/klm
30
Type
CLASSIC ASN A1/A2/A3/A4/A5/A9
CLASSIC FDH PAR MAT-V2 REF A2 L1 FDH 3x14W 90
90
75
75 200
60
60
300 45
45
400 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
CLASSIC FDH PAR-V2 A2 L1 FDH 3x14W 90
Light source Optical system Wiring Materials Surface finish
Type 90
75
75
CLASSIC ASN A1 CLASSIC ASN A1 CLASSIC ASN A2 CLASSIC ASN A2 CLASSIC ASN A3 CLASSIC ASN A3 CLASSIC ASN A4 CLASSIC ASN A4 CLASSIC ASN A5 CLASSIC ASN A5 CLASSIC ASN A9 CLASSIC ASN A9
60
300 45
45 cd/klm
30
15 0 C0.0-C180.0
optical system
power
PAR-V2
PAR MAT-V2
(W)
• • • • • • • • • • • •
• • • • • • • • • • • •
4x14 4x24 3x14 3x24 4x14 4x24 4x14 4x24 4x14 4x24 3x14 3x24
lamp
HELLOS AS-1 HELLOS AS-4
MODUL wings SUSPENDED
lampholder
15
30 C90.0-C270.0
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
CLASSIC ASR II
CLASSIC ASR II PAR-V FDH 3x80W 90
90 75
80 120 160
60 45
69 69
correlated color temperature CCT (K)
thermal management
80 80
4000 4000
• •
Linear fluorescent lamp FDH (T5) Parabolic microlouvre (PAR-Vm/PAR MAT-Vm) Electronic control gear On request: dimmable electronic control gear (1-10V/DSI/ DALI/switch DIM) Housing: polycarbonate and sheet steel Parabolic microlouvre: anodized polished/mat, aluminium Housing: black (RAL 9005), white (RAL 9003), other colors on request
MODUL WINGS PAR-Vm 3x24W 90
60
15 30 C90.0-C270.0
CLASSIC ASR II PAR MAT-V FDH 3x80W
Type
optical system
power
PAR-Vm
PAR MAT-Vm
(W)
• •
• •
3x14 3x24
MODUL WINGS MODUL WINGS
lamp
lampholder
FDH FDH
G5 G5
Light source Linear fluorescent lamp FDH (T5) Optical system Parabolic louvre (PAR-V/PAR MAT-V) Wiring Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, parabolic louvre: polished/mat aluminium, cover: clear plastic Surface finish Housing: white (RAL 9003), other colors on request
Light source LED Optical system Diffuser Wiring Dimmable electronic control gear DALI (10-100%) Materials Housing: sheet steel Frame: extruded aluminium profile Diffuser DIR: PMMA OPAL + PMMA diamond microprisma Diffuser INDIR: PMMA linear microprisma Surface finish Black (RAL 9005), silver grey (RAL 9006) Other colors on request
Type
Type
CLASSIC ASR II
90
90
75
75 100
60
60
15O 45
60 45
45
15 0 C0.0-C180.0
15
30 C90.0-C270.0
MODUL BOX MAX LED DIR 4200lm 4000K 90
75
75 200
60
60
300 45
45
400 cd/klm
30
optical system
power
PAR-V
PAR MAT-V
(W)
•
•
3x80
lamp
FDH
lampholder
G5
MODUL BOX MAX DIR MODUL BOX MAX DIR MODUL BOX MAX DIR/INDIR MODUL BOX MAX DIR/INDIR
net lumen power output consumption (at Ta = 25 °C) (lm) (W) 4200 4200 5350 5350
52 52 73 73
color rendering index CRI (Ra)
correlated color temperature CCT (K)
thermal management
>80 >80 >80 >80
3000 4000 3000 4000
• • • •
PASSIVE
45
200 15 0 C0.0-C180.0
60
90
cd/klm
30
75
100 150 200 250
15 0 C0.0-C180.0
15
30 C90.0-C270.0
45
140 15 0 C0.0-C180.0
90
75
MODUL BOX MAX LED DIR/INDIR 5350lm 4000K
cd/klm
30
30 C90.0-C270.0
PASSIVE
30
modul box max DIR/DIR-INDIR
75
Light source Optical system Wiring Materials Surface finish
4300 4300
color rendering index CRI (Ra)
15
cd/klm
200
60
Linear fluorescent lamp FDH Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel Parabolic louvre: polished/mat aluminium Powder coat finish – white (RAL 9003), other colors on request Bottom sheet: solid (DECOR L1)/perforated (DECOR L2)
net lumen power output consumption (at Ta = 25 °C) (lm) (W)
15 0 C0.0-C180.0
15 30 C90.0-C270.0
PRODUCTS
120/121
120
120
300 200
105
105
90
90
75
75
60
60 45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
MODUL SPIKER LED 6300lm 3000K 90
90
75
75 100
60
suspended
modul spiker
MODUL ray suspended
60
150 200
45
suspended Light source LED Optical system Diffuser Wiring Dimmable electronic control gear DALI (10-100%) Housing: extruded aluminium Materials Diffuser: microprismatic + lumio Surface finish White (RAL 9003)
45
250 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
net lumen output (at Ta = 25 °C) (lm)
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
6300 6600
120 120
80 80
3000 4000
• •
correlated color temperature CCT (K)
thermal management
3000-6500
•
Light source Optical system Wiring Materials Surface finish
Linear fluorescent lamp FDH (T5) LED strips Parabolic microlouvre (PAR-Vm/PAR MAT-Vm), Diffuser Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: extruded aluminium Parabolic louvre: anodized polished aluminium Diffuser: polycarbonate, housing, end caps: polycarbonate Housing: white (RAL 9003), grey (RAL 9006), black (RAL 9005)
Type
optical system
modul CLEARANCE
MODUL CLEARANCE LED 4300lm 6500K 160 120 80
90 75
90 75 60
60
Light source LED Optical system Edge lighting (EVONIC) Wiring Dimmable electronic control gear DALI (10-100%) Body: aluminium + PMMA, cover: glass Materials Surface finish Housing: grey
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
MODUL CLEARANCE
modul RAZZOR
modul razzor LED symmetric 9000lm 6500K 90
90
75
75
100 150 200 250 300
60 45 cd/klm
30
15 0 C0.0-C180.0
60
(W)
color rendering index CRI (Ra)
4300
77
80
PASSIVE
15
30 C90.0-C270.0
90
Type
modul EYE 90 75
75 80
60
120 160
45
200
net lumen output (at Ta = 25 °C) (lm)
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
9000
15 0 C0.0-C180.0
15
130
>80
3000-6500
•
90
Light source Linear fluorescent lamp FDH (T5) Optical system Microlouvre, two adjustable asymmetrical reflectors Wiring Dimmable electronic control gear DALI Servomotoric control of reflectors Materials Housing: sheet steel, microlouvre: anodized polished aluminium Reflectors: anodized mat aluminium Surface finish Housing: white (RAL 9016)
Type 90
75
optical system
power
Microlouvre + ref.
(W)
• •
4x28 4x54
lamp
MODUL EYE MODUL EYE
60
150 45
45
200
lampholder
15 0 C0.0-C180.0
15
Type
Light source Optical system Wiring Materials Surface finish
1x14* 1x24* 1x28* 1x35* 1x49* 1x54* 1x80* 2x14 2x24 2x28 2x35 2x49 2x54 2x80 3x14 3x24 3x28 3x35 3x49 3x54 3x80
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
optical system
power
CDP
CDP DIF
(W)
• • • • • • • •
• • • • • • • •
2x28 2x35 2x49 2x54 2x80 4x28 4x35 4x49
lamp
lampholder
FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5
Linear fluorescent lamp FDH (T5) Diffuser (MICROPRISMA LDP/CDP/CDP DIF) Electronic control gear Housing: extruded aluminium Diffusers: polycarbonate End caps: polycarbonate Housing: grey (RAL 9007), other colors on request
90
75
75
60
60 cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
MODUL QUARK II DIR CDP FDH 4x28W 90
90
75
75 80
60
60
120 160
45
45
200
MODUL RENDO MODUL RENDO MODUL RENDO MODUL RENDO
power
LDP
CDP
CDP DIF
(W)
• • • •
• • • •
• • • •
2x28 2x35 2x49 2x54
15
30 C90.0-C270.0
lampholder
FDH FDH FDH FDH
G5 G5 G5 G5
122/123
105
90
90
75
75
60
lamp
120
100 80 60 40
105
60
cd/klm
45
optical system
15 0 C0.0-C180.0
MODUL RENDO PRISMA CDP 2x54W 120
G5 G5
30 C90.0-C270.0
PRODUCTS
(W)
• • • • • • • • • • • • • • • • • • • • •
Linear fluorescent lamp FDH (T5) Diffuser (MICROPRISMA CDP/CDP DIF) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel, extruded aluminium Diffuser: polycarbonate with two types of microprismatic finish CDP or CDP DIF Housing: grey (RAL 9006), other colors on request
Type
cd/klm
30
FDH FDH
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
90
30
MODUL rendo
75 100
60
Light source Optical system Wiring Materials Surface finish
MODUL QUARK II MODUL QUARK II MODUL QUARK II MODUL QUARK II MODUL QUARK II MODUL QUARK II MODUL QUARK II MODUL QUARK II
30 C90.0-C270.0
MODUL eye NARROW 4x54W
lampholder
105
cd/klm
PASSIVE
cd/klm
30
MODUL quark II
45
MODUL eye WIDE 4x54W
45
power consumption
Light source LED Optical system Reflector, diffuser Wiring Electronic control gear, remote control Materials Housing: aluminium, reflector: polished aluminium (symmetric + asymmetric) Diffuser: opal + microprismatic, indirect part: shaped primary lenses Surface finish Stainless steel, black, silver
MODUL RAZZOR
60
net lumen output (at Ta = 25 °C) (lm)
PAR MAT-Vm
MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • * Blue LED ambient lighting on request
45
45
lamp
120
160 120 80
105
PASSIVE PAR-Vm
MODUL SPIKER MODUL SPIKER
power
MODUL RAY DIR-INDIR PAR-Vm 2x28W 120
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
suspended avant led
AVANT LED OPAL 4200lm 4000K 300 250 200 150 100
120 105
120 105
90
90
75
75
60
60
cd/klm
45
30 15 0 C0.0-C180.0
15
suspended
Light source Optical system Wiring Materials Surface finish
Type
avant 120 105
90
90
75
75
60
60
cd/klm
45
30 15 0 C0.0-C180.0
15
Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel, parabolic louvre: anodized polished aluminium Housing: white (RAL 9003), other colors on request
MODUL EXE II DIR PAR–V2 FDH 1x35W 90
90
75
75
60
200
45
300 30
AVANT OPAL 1x54W 300 250 200 150 100
Light source Optical system Wiring Materials Surface finish
60 45
cd/klm
net lumen power color correlated thermal output consumption rendering color management (at Ta = 25 °C) index temperature (lm) (W) CRI (Ra) opal microprisma CCT (K) PASSIVE
AVANT LED AVANT LED AVANT LED AVANT LED
120
modul exe II
30 45 C90.0-C270.0
Type
105
LED Diffuser (OPAL/MICROPRISMA) Dimmable electronic control gear DALI (10-100%) Housing: extruded aluminium, end caps: die cast aluminium Diffuser: PC/PMMA, diffuser end caps: PC/PMMA Carrying plate: extruded aluminium Powder coat finish – grey (RAL 9006)
30 45 C90.0-C270.0
optical system
• • -
Light source Optical system Wiring Materials Surface finish
• •
5050 5050 4200 4200
72 72 72 72
80 80 80 80
3000 4000 3000 4000
MODUL EXE II MODUL EXE II MODUL EXE II MODUL EXE II MODUL EXE II MODUL EXE II MODUL EXE II MODUL EXE II MODUL EXE II MODUL EXE II
• • • •
Linear fluorescent lamp FDH (T5) Diffuser (OPAL/MICROPRISMA) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: extruded aluminium, end caps: die cast aluminium Diffuser: PMMA, diffuser end caps: PC/PMMA Reflector end caps: ABS/PMMA Carrying plate: extruded aluminium Powder coat finish – grey (RAL 9006)
line range 100 led suspended single PIECE
Light source Optical system Wiring Materials Surface finish
optical system PAR-V2 PAR MAT-V2 • • • • • • • • • •
• • • • • • • • • •
power (W)
lamp
lampholder
1x28 1x54 1x35 1x49 1x80 2x28 2x54 2x35 2x49 2x80
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
LED Reflector, diffuser Dimmable electronic control gear DALI (10-100%) Housing: sheet steel, reflector: aluminium, diffuser: opal Housing: white (RAL 9003), reflector: white (RAL 9003)
15 0 C0.0-C180.0
15
30 C90.0-C270.0
LINE RANGE 100 suspended SINGLE PIECE 4700lm 4000K 90
90
75
75 800
60
60
1200 45
45
1600 cd/klm
Type Type
AVANT AVANT AVANT AVANT AVANT AVANT AVANT AVANT AVANT
MODUL en
MODUL EN PAR–V2 FDH 4x24W 240 200 160
120 105
120 105
80
90
90
75
75
60
60
cd/klm
45
30 15 0 C0.0-C180.0
15
Light source Optical system Wiring Materials Surface finish
optical system opal microprisma • • • • • • • • •
power (W)
• • • • • • • • •
lamp
1x28 1x35 1x49 1x54 1x80 2x28 2x54 2x35 2x49
lampholder
FDH FDH FDH FDH FDH FDH FDH FDH FDH
LINE RANGE 100 LED SINGLE PIECE LINE RANGE 100 LED SINGLE PIECE
G5 G5 G5 G5 G5 G5 G5 G5 G5
modul lambda
Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: elox aluminium Parabolic louvre: polished or mat aluminium Housing: grey (RAL 9006), other colors on request
optical system PAR-V2 PAR MAT-V2
MODUL EN MODUL EN
• •
• •
power (W)
lamp
lampholder
4x14 4x24
FDH FDH
G5 G5
modul exe II LED
90
90
75
75 200
60
60
300 45
Light source Optical system Wiring Materials Surface finish
LED Diffuser Electronic control gear On request: dimmable electronic control gear DALI (10-100%) Housing: sheet steel, diffuser: opal PMMA White (RAL 9003), other colors on request
CCT (K)
PASSIVE
4450
59
>80
3000
•
4700
59
>80
4000
•
correlated color thermal temperature management
Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2), reflector (ASYMMETRIC) Electronic control gear On request: dimmable electronic control gear (1-10V/DSI/DALI/switch DIM) Housing: sheet steel, parabolic louvre: polished/mat aluminium Reflector: polished anodized aluminium Housing: grey (RAL 9006), other colors on request
Type PAR-V2 MODUL LAMBDA MODUL LAMBDA MODUL LAMBDA MODUL LAMBDA MODUL LAMBDA
Light source Optical system Wiring Materials Surface finish
• • • • •
optical system PAR MAT-V2 ASYMMETRIC • • • • •
•/– •/– •/– •/– •/–
power (W)
lamp
lampholder
1x28 / 2x28 1x35 / 2x35 1x49 / 2x49 1x54 / 2x54 1x80 / 2x80
FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5
Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel, parabolic louvre: polished/mat aluminium Housing: grey (RAL 9006), other colors on request
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
optical system DIFFUSER
modul exe II LED modul exe II LED
PRODUCTS
• •
net lumen power output consumption (at Ta = 25 °C) (lm) (W) 4950 4450
70 70
color rendering index CRI (Ra) 80 80
correlated thermal color management temperature CCT (K) PASSIVE 4000 3000
30 C90.0-C270.0
MODUL LAMBDA DIR-INDIR PAR-V2 FDH 2x54W 120
120
200 150 100
105
105
90
90
75
75
60
60 30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
MODUL LAMBDA MAX DIR-INDIR PAR-V2 FDH 2x54W 120
120
200 150 100
105
105
90
90
75
75 60 cd/klm
optical system PAR-V2 PAR MAT -V2
power (W)
lamp
lampholder
2x28 2x35 2x49 2x54 2x80
FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5
cd/klm
30
15
60
Type
45
400
(W)
color rendering index CRI (Ra)
45
modul lambda max modul exe II LED 4950lm 4000K
power consumption
15 0 C0.0-C180.0
cd/klm
30 45 C90.0-C270.0
Type
Light source Optical system Wiring Materials Surface finish
net lumen output (at Ta = 25 °C) (lm)
30
• •
MODUL LAMBDA MAX MODUL LAMBDA MAX MODUL LAMBDA MAX MODUL LAMBDA MAX MODUL LAMBDA MAX
• • • • •
• • • • •
124/125
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
suspended modul box suspended
MODUL BOX LED 1800lm 4000K 90
90
75
75 200
60
60
300 400
45
45
Light source Optical system Wiring Materials Surface finish
MODULAR SYSTEM LED Diffuser Dimmable electronic control gear DALI (10-100%) Housing: sheet steel, frame: extruded aluminium profile Diffuser: PMMA OPAL+PMMA diamond microprisma Black (RAL9005), silver grey (RAL 9006) Other colors on request
avant line led
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Light source Optical system Wiring Materials Surface finish
LED Diffuser (OPAL/MICROPRISMA) Dimmable electronic control gear DALI (10-100%) Housing: extruded aluminium, end caps: die cast aluminium Diffuser: PC/PMMA, diffuser end caps: PC/PMMA Carrying plate: extruded aluminium Powder coat finish – grey (RAL 9006)
avant line led opal 5050lm 4000K 300 250 200 150 100
120 105 90
90
75
75
60
60
cd/klm
45
Type
optical system DIFFUSER
modul box sus.
plastic PLAST H
PLAST H OPAL FDH 1x28W 150 125 100 75 50
120 105
120 105
90
90
75
75
60
60
cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
105
105
90
90
75
75
60
PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H
120
200 160 120 80
60
cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
•
1800
35
color rendering index CRI (Ra) >80
correlated thermal color management temperature CCT (K) PASSIVE 4000
Type
•
Light source Linear fluorescent lamp FDH (T5) Optical system Diffuser (OPAL/PRISMA) Wiring Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, diffuser: prismatic or opal polycarbonate, end caps: white polycarbonate Surface finish Housing: white (RAL 9003), other colors on request Type
PLAST H PRISMA FDH 1x28W 120
net lumen power output consumption (at Ta = 25 °C) (lm) (W)
optical system REFLECTOR OPAL PRISMA • • • • • • • • • • • • • • • • • • • • • •
power (W)
lamp
lamp holder
1x14 1x24 1x28 1x35 1x49 1x54 1x80 2x14 2x28 2x35 2x49
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
avant line
MODULAR SYSTEM
120 105
90
75
75
60
modul ray line
Linear fluorescent lamp FDH (T5) Parabolic microlouvre (PAR-Vm/PAR MAT-Vm) Diffuser Electronic control gear, through wiring (F, T version) On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: extruded aluminium Parabolic microlouvre: anodized polished aluminium Diffuser: polycarbonate, housing end caps: polycarbonate Housing: white (RAL 9003)/grey (RAL 9006)/Black (RAL 9005)
60 cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
Type
• • • • • •
72 72 72 72 72 72 72 72 72 72 72 72
80 80 80 80 80 80 80 80 80 80 80 80
3000 4000 3000 4000 3000 4000 3000 4000 3000 4000 3000 4000
• • • • • • • • • • • •
Light source Optical system Wiring Materials Surface finish
Linear fluorescent lamp FDH (T5) Diffuser (OPAL/MICROPRISMA), parabolic louvre (PAR-V/PAR MAT-V) Reflector (SYMMETRIC/ASYMMETRIC) Electronic control gear, through wiring (F, T version) On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: extruded aluminium, end caps: die cast aluminium Diffuser: PC/PMMA, diffuser end caps: PC/PMMA Reflector: anodized polished aluminium, reflector end caps: ABS/PMMA Parabolic louvre: polished or mat aluminium Carrying plate: extruded aluminium Powder coat finish – grey (RAL 9006)
avant line par-v 2x28W 90
90
75
75
50 75 100 125
60 45
60 45
150 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
optical system
AVANT TRACK LINE
AVANT line F/T/L AVANT line F/T/L AVANT line F/T/L AVANT line F/T/L AVANT line F/T/L AVANT line F/T/L AVANT line F/T/L AVANT line F/T/L AVANT line F/T/L AVANT TRACK line
• • • • • • • • • -
power
PAR OPAL MICROPRISMA SYMMETRIC ASYMMETRIC MAT-V • • • • • • • • • -
• • • • • • • • • -
• • • • • • • • • -
• • • • • • • • • -
• • • • • • • • • -
lamp
(W) 1x28 1x35 1x49 1x54 1x80 2x28 2x35 2x49 2x54 max. 500
FDH FDH FDH FDH FDH FDH FDH FDH FDH -
150 125 100 75 50
120 105
120 105
90
90
75
75
60
60
cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
avant line symmetric 2x28W 90
90
75
75
100 150 200
60 45
60 45
300 cd/klm
30
optical system PAR-Vm PAR MAT Vm
MODUL RAY LINE F/T/L • MODUL RAY LINE F/T/L • MODUL RAY LINE F/T/L • MODUL RAY LINE F/T/L • MODUL RAY LINE F/T/L • MODUL RAY LINE F/T/L • * Blue LED ambient lighting on request
PRODUCTS
5050 5050 5050 5050 5050 5050 4200 4200 4200 4200 4200 4200
• • • • • • -
Type
• we can control lighting scenes by dimming, • it is very useful for lighting cash desk areas, but can be used as general lighting as well, • using the direct/indirect version highlights design of the ceiling and opticaly extents the space of the shop, • a possibility to use energy-saving fluorescent lamps, • the deployment of luminaires in lines one after another, we achieve a high uniformity of vertical illumination, • when illuminating racks, it does not glare customers due to the asymmetric light curve (at some types of luminaires), • due to high power they can be used in hypermarkets with high ceilings.
105
90
30 45 C90.0-C270.0
avant line par mat-v 2x28W
Stylish fluorescent lamp luminaires, which direct the luminous flux either downwards, upwards reflecting indirectly from the ceiling, or a combination of these two methods (direct/reflected). For the required indirect light diffusion from the ceiling they need sufficient distance between the luminaire and the ceiling. The biggest advantage of the Modul luminaires is the possibility to combine the direct and indirect lighting. This combination can suppress sharply defined transitions between light and shadow, emerging on the walls when using louver luminaires, which strictly divide the luminous flux down in prescribed angles. However, that is not the only advantage of this system. Some of the others are: • the luminaires can be plugged into a coherent line,
120
160 120 80
15
net lumen power color correlated thermal output consumption rendering color management (at Ta = 25 °C) index temperature opal microprisma (lm) (W) CRI (Ra) CCT (K) PASSIVE
PAR-V
Light source Optical system Wiring Materials Surface finish
30 15 0 C0.0-C180.0
optical system
AVANT LINE LED F AVANT LINE LED F AVANT LINE LED T AVANT LINE LED T AVANT LINE LED L AVANT LINE LED L AVANT LINE LED F AVANT LINE LED F AVANT LINE LED T AVANT LINE LED T AVANT LINE LED L AVANT LINE LED L
modul
modul ray line 2x28W
120 105
• • • • • •
power (W)
lamp
lampholder
1x28* 1x54* 2x28 2x54 3x28 3x54
FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5
par-v
symmetric
par mat-v
microprisma
opal
asymmetric
126/127
15 0 C0.0-C180.0
15
30 C90.0-C270.0
MODULAR SYSTEM
The continuous lighting system is ideally suitted to areas which require high levels of uniform light. The Prestige system is produced for FDH (T5) and FD (T8) linear fluorescent lamps – single and twin lamp luminaires. Optimal solution for specific applications is enabled by variations of wiring installed in the suspension profile. As the internal wiring is a part of the mounting rail, it decreases costs for distribution of electricity. For a better direction of the luminous flux, reflectors are used
PRESTIGE
Easy-to-mount system Prestige by OMS is a solution, which perfectly fits the use in a hypermarket. It is equipped with a wide range of louvres and reflectors and therefore provides very easy and high-efficient realisations of different types of interior lighting installations.
TBP
SB
SBT24
SBT15
CHP02
CHP02+CHS
according to customer’s requirements. Another advantage is the possibility to mount luminaires with a narrow beam angle directly to the track system. By using these luminaires we can achieve accent lighting. On request Prestige can be equipped with an emergency unit.
RSE02
RS02
MRE
MRCP
Characteristics of the Prestige system are following: • quick and easy toolless assembly • high variability • high efficiency optical system – up to 98 % by using reflectors • connection of luminaires in a continuous uninterrupted line • quick and safe mounting • maximum light output
MR FDH II / MR FDH III MR FDH I
MR FD II / MR FD III MR FD I
MR FDH COVER MR FD COVER
MRCP L/T/X01/X02
MRCP L/T/X01/X02
FDH DM FDH 2x IP65
DM FDH 1x
R12 FDH AL DEEP 03 IP65
DM FDH 2x
REP R12
R1 FDH
REP R12
R12 FDH L1 REP R12
REP R12
REP R12
REP R12
R12 FDH L1 R12 FDH AL
REP R12
DM FD 1x
DM FDH TRACK
DM FD 2x
REP R12
REP R2
REP R2
R1 FD AL
R2 FD L1
R2 FD AL
DM FD TRACK
R1 FD L1 R12 FDH AL
RSK FDH
REP R12
RSK FD
REP R2 R12 FDH L2
R12 FDH L2
REP R12
REP R12
R1 FD L2 REP R12
R1 FDH PAR-V
R2 FD L2
RSKE FDH
RSKE FD
REP R2 R12 FDH L4
RCP R12 AL
R12 FDH L4
RCP R12 AL
R1 FD L4
RCP R2 AL
RCP R12 AL
R2 FD L4 RSKN FD
R1 FDH PAR-V MAT RCP R12
R12 FDH PAR-V
RCP R12
RCP R12
R12 FDH AL DEEP
R12 FDH PAR-V MAT
R12 FDH PAR-V
R12 FDH AL DEEP
R1 FD PAR-V
R12 FD AL DEEP
RCP R2
R12 FD AL DEEP
R1 FD PAR-V MAT
R12 FDH PAR-V MAT
R2 FD LA
R12 FDH LA
R1 FD LA
R12 FDH LA
R2 FD LB R12 FDH LB
R12 FDH AL ASYMMETRIC
R12 FDH LB
R12 FDH AL ASYMMETRIC
R12 AL ASYMMETRIC
R12 FD AL ASYMMETRIC
R1 FD LB
R2 FD PRISMATIC R12 FDH PRISMATIC
R12 FDH OPAL
PRODUCTS
R12 FDH AL DEEP 02
R12 FDH PRISMATIC
R12 FDH OPAL
R12 FDH AL DEEP 02
R1 FD PRISMATIC
R1 FD OPAL
R1 FD AL DEEP 02
R2 FD OPAL
128/129
LINE RANGE 100 LED 4700lm 4000K 90
90
75
75 800
60
MODULAR SYSTEM
MODULAR SYSTEM
line range 100 led suspended
modul en line
60
1200 45
45
1600 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Light source Optical system Wiring Materials Surface finish
LED Reflector + diffuser Electronic control gear On request: dimmable electronic control gear DALI (10-100%)/touchDIM Housing: sheet steel Reflector: aluminium Diffuser: opal PMMA End caps: sheet steel Housing: white (RAL 9003) Reflector: white (RAL 9003) Other colors on request
Light source Optical system Wiring Materials Surface finish
Linear fluorescent lamp FDH (T5) Diffuser (MICROPRISMA), parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Through wiring (F, T version) Housing: sheet steel Diffuser: polycarbonate Parabolic louvre: anodized polished aluminium Housing: grey (RAL 9006), other colors on request
Type
Type
net lumen output (at Ta = 25 °C)
power consumption
(lm)
(W)
color rendering index CRI (Ra)
4450 4700
59 59
>80 >80
LINE RANGE 100 LED F/T/L LINE RANGE 100 LED F/T/L
LINE RANGE 100 suspended
LINE RANGE 100 1x54 W 90
90
75
75
100 150 200 250 300
60 45
60 45
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Light source Optical system Wiring Materials Surface finish
PAR-v2
3000 4000
optical system
power lamp
PAR-V2
par mat-v2
OPAL
MICROPRISMA
ASYM
(W)
• • • •
• • • •
• • • •
• • • •
– – – •
1x28 1x35 1x49 1x54
PAR MAT-V2
OPAL
MODUL EN LINE F/T/L MODUL EN LINE F/T/L MODUL EN LINE F/T/L MODUL EN LINE F/T/L MODUL EN LINE F/T/L
• •
Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2) Diffuser (OPAL) Reflector (ASYMMETRIC) Electronic control gear On request: dimmable electronic control gear (1-10 V/switch DIM/DSI/DALI) Through wiring (F, T version) Housing: sheet steel Parabolic louvre: anodized polished/mat aluminium Diffuser: polycarbonate Reflector: anodized aluminium Housing: grey (RAL 9006) Other colors on request
Type
LINE RANGE 100 F/T/L LINE RANGE 100 F/T/L LINE RANGE 100 F/T/L LINE RANGE 100 F/T/L
correlated thermal color management temperature CCT (K) PASSIVE
FDH FDH FDH FDH
MODUL LAMBDA II LINE
SIMPLE SWAT
120
120
120 90 60
105
105
90
90
75
75
60
Type
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
SIMPLE SWAT SIMPLE SWAT SIMPLE SWAT SIMPLE SWAT SIMPLE SWAT SIMPLE SWAT SIMPLE SWAT SIMPLE SWAT SIMPLE SWAT
PRODUCTS
PAR-V2
PAR MAT-V2
MICROPRISMA
(W)
• • • • •
• • • • •
• • • • •
2x28 2x54 2x35 2x49 2x80
optical system PAR-V2 PAR MAT-V2
lamp
lampholder
FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5
asymmetric
power (W)
lamp
240 200 160
105
120 105
80
90
90
75
75
60
60
cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
MODUL LAMBDA II LINE PAR MAT-V2 DIR FDH 1x28W 90
90
75
75 200
60
60
300 45
45
400 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
MODUL LAMBDA II LINE PAR-V2 DIR FDH 1x28W
lampholder 90
90
75
lampholder
Modul LAMBDA F/T/L Modul LAMBDA F/T/L Modul LAMBDA F/T/L Modul LAMBDA F/T/L Modul LAMBDA F/T/L Modul LAMBDA F/T/L Modul LAMBDA F/T/L Modul LAMBDA F/T/L Modul LAMBDA F/T/L Modul LAMBDA F/T/L
G5 G5 G5 G5
• • • • • • • • • •
• • • • • • • • • •
• • • • • – – – – –
1x28 1x35 1x49 1x54 1x80 2x28 2x35 2x49 2x54 2x80
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
75 200
60
60
300 45
45
400 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
ASYM
Linear fluorescent lamp FDH (T5) Electronic control gear On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel, end caps: sheet steel Housing: white (RAL 9003)
Light source Optical system Wiring Materials Surface finish
LED Reflector, diffuser Electronic control gear On request: dimmable electronic control gear DALI (10-100%)/touchDIM Housing: sheet steel, reflector: aluminium Diffuser: opal PMMA, end caps: sheet steel Housing: white (RAL 9003), reflector: white (RAL 9003) Other colors on request
power (W)
lamp
1x14 1x21 1x24 1x28 1x35 1x39 1x49 1x54 1x80
FDH FDH FDH FDH FDH FDH FDH FDH FDH
90
90
75
75 800
60
60
1200 45
45
1600 30
lampholder
G5 G5 G5 G5 G5 G5 G5 G5 G5
line range 100 led surfaced 4700lm 4000K
cd/klm
Type
60 cd/klm
45
Light source Wiring Materials Surface finish
power
Light source Linear fluorescent lamp FDH (T5) Optical system Parabolic louvre (PAR-V2/PAR MAT-V2), reflector (ASYMMETRIC) Wiring Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Through wiring (F, T version) Materials Housing: sheet steel, parabolic louvre: anodized polished aluminium Reflector: anodized aluminium Surface finish Housing: grey (RAL 9006) Other colors on request
Type
line range 100 led surfaced SIMPLE SWAT FDH 1x28W
optical system
MODUL EN PAR-V2 FDH 2x28W 120
LINE RANGE 100 LED F/T/L LINE RANGE 100 LED F/T/L
net lumen output (at Ta = 25 °C) (lm)
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
4450 4700
59 59
>80 >80
3000 4000
• •
PASSIVE
130/131
15 0 C0.0-C180.0
15
30 C90.0-C270.0
LINE RANGE 100 1x54W 90
90
75
45
MODULAR SYSTEM
LINE RANGE 100 surfaced
relax line asymmetric led
75
100 150 200 250 300
60
MODULAR SYSTEM 60 45
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Light source Optical system Wiring Materials Surface finish
Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2), diffuser (OPAL), reflector (ASYMMETRIC) Electronic control gear On request: dimmable electronic control gear (1-10 V/switch DIM/DSI/DALI), through wiring (F, T version) Housing: sheet steel, parabolic louvre: anodized polished/mat aluminium Diffuser: opal/prismatic, reflector: anodized aluminium Housing: grey (RAL 9006), other colors on request optical system
LINE RANGE 100 F/T/L LINE RANGE 100 F/T/L LINE RANGE 100 F/T/L LINE RANGE 100 F/T/L
LINE snappy
LINE SNAPPY LED 4100lm 4000K 90
90
75
75
100 150 200 250 300
45
60 45
Light source Optical system Wiring Materials Surface finish
power lamp
PAR-V2
par mat-v2
OPAL
MICROPRISMA
ASYM
(W)
• • • •
• • • •
• • • •
• • • •
– – – •
1x28 1x35 1x49 1x54
15 0 C0.0-C180.0
15
90
75
75
60
60 450
net lumen output (at Ta = 25 °C) (lm)
power consumption
3550 3550 3550
RELAX PV ASYM. LED F/T/L RELAX PV ASYM. LED F/T/l RELAX PV ASYM. LED F/T/L
LINE RANGE PB 100 led
30 C90.0-C270.0
Light source Optical system Wiring Materials Surface finish
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
47 47 47
80 80 80
3000 4000 3000-6500
• • •
net lumen output (at Ta = 25 °C) (lm)
power consumption
4100 4100 4100 4100
LINE SNAPPY F/T/L LINE SNAPPY F/T/L LINE SNAPPY SINGLE PIECE LINE SNAPPY SINGLE PIECE
RELAX H LINE
RELAX H LINE PAR-V2 1x28 W 90
90
75
75
100 150 200 250 300
60 45
60 45
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Light source Optical system Wiring Materials Surface finish
Type
RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L RELAX H LINE F/T/L
PRODUCTS
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
LED Reflector + diffuser Electronic control gear On request: dimmable electronic control gear DALI (10-100%)/touchDIM Housing: sheet steel, reflector: aluminium Diffuser: opal PMMA Housing: white (RAL 9003), reflector: white (RAL 9003) Other colors on request
66 66 66 66
80 80 80 80
3000 4000 3000 4000
• • • •
Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2), diffuser (OPAL/MICROPRISMA) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel Parabolic louvre: polished / mat aluminium Diffuser: opal/microprismatic polycarbonate Powder coat finish – white (RAL 9003), other colors on request
optical system PAR-V2 PAR MAT-V2 OPAL MICROPRISMA • • • • • • • • • • • • • •
• • • • • • • • • • • • • •
• • • • • • • • • • • • • •
• • • • • • • • • • • • • •
power (W)
lamp
1x14 1x24 1x28 1x54 1x35 1x49 1x80 2x14 2x24 2x28 2x54 2x35 2x49 2x80
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
Type
PASSIVE
lampholder
net lumen output (at Ta = 25 °C) (lm)
power consumption
4550 4700
LINE RANGE PB 100 LED F/T/L LINE RANGE PB 100 LED F/T/L
LINE RANGE PB 100
PAR-V2 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
59 59
>80 >80
3000 4000
• •
optical system par opal MICROPRISMA asyM mat-v2
LINE RANGE PB 100 F/T/L LINE RANGE PB 100 F/T/L LINE RANGE PB 100 F/T/L LINE RANGE PB 100 F/T/L LINE RANGE PB 100 F/T/L
• • • • •
PAR-v2
PAR MAT-V2
• • • • •
• • • • •
• • • • •
OPAL
• -
15
30 C90.0-C270.0
LINE RANGE PB 100 led 4700lm 4000K 90
90
75
75 800
60
60
1200 45
45
1600 cd/klm
15 0 C0.0-C180.0
15
30 C90.0-C270.0
PASSIVE
Light source Linear fluorescent lamp FDH (T5) Optical system Parabolic louvre (PAR-V2/PAR MAT-V2), diffuser (OPAL/MICROPRISMA) Reflector (ASYMMETRIC) Electronic control gear Wiring On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, Asymmetric reflector: anodized aluminium, Diffuser: opal/ microprismatic polycarbonate, Parabolic louvre: polished/matt aluminium Surface finish Housing: white (RAL 9003)
Type
15 0 C0.0-C180.0
PASSIVE
30
Type
45
600 30
G5 G5 G5 G5
LED Diffuser Electronic control gear Housing: extruded aluminium Diffuser: opal polycarbonate Fixing accessories: zinc coated sheet steel White (RAL 9003)
90
cd/klm
lampholder
FDH FDH FDH FDH
RELAX LINE ASYMMETRIC LED 3550lm 4000K
45
cd/klm
30
LED Asymmetric reflector Electronic control gear On request: dimmable electronic control gear DALI (10-100%) Housing: sheet steel, reflector: polished aluminium Housing: white (RAL 9003), other colors on request
Type Type
60
Light source Optical system Wiring Materials Surface finish
power (W)
lamp
lampholder
1x54 1x28 1x54 1x35 1x49
FDH SEAMLESS FDH FDH FDH FDH
G5 G5 G5 G5 G5
ASYMMETRIC
132/133
LINE RANGE PB 100 ASYMMETRIC 1x54 W 90
90 75
75 60
60
300 400
45
45
500 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
TUBUS VISION LED POLISHED 2000lm 3000K 90
CEILING SURFACED
CEILING SURFACED
tubus vision led
CLASSIC XTP IP54
90
75
75 200
60
60
300 45
45
Light source LED Optical system Reflector Wiring Electronic control gear On request: dimmable electronic control gear DALI (10 - 100%) Materials Housing: polycarbonate, reflector: vacuum coated polycarbonate (polished/ white), decorative trim: sheet steel Surface finish Housing: upper part – white, bottom part – grey, other colors on request, Decorative trim: red, other colors on request
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
net lumen output (at Ta = 25 °C) (lm)
power consumption
1100 1100 2000 2000
TUBUS VISION LED TUBUS VISION LED TUBUS VISION LED TUBUS VISION LED
tubus cygnus
TUBUS CYGNUS LED 90° 1000lm 4000K 90
90
75
75 200
60
60
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
15 13 28 26
80 80 80 80
3000 4000 3000 4000
• • • •
Type
PASSIVE CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP CLASSIC XTP
Light source LED Optical system Diffuser Wiring Dimmable electronic control gear - thyristor dimming (5-100%) Housing: extruded aluminium, diffuser: opal plast Materials Surface finish Grey (RAL 9006), other colors on request
300 45
45
Type
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
TUBUS CYGNUS TUBUS CYGNUS TUBUS CYGNUS TUBUS CYGNUS
MODUL wings SURFACED
MODUL WINGS PAR-Vm 3x24W 90
90
75
75
100 150 200 250
60 45
60 45
Light source Optical system Wiring Materials Surface finish
net lumen power color output consumption rendering (at Ta = 25 °C) index (lm) (W) CRI (Ra) 700 700 1000 1000
10 10 15 15
correlated color temperature CCT (K)
thermal management
3000 4000 3000 4000
• • • •
>90 >90 >90 >90
beam angle
15 0 C0.0-C180.0
15
90° 90° 90° 90°
CLASSIC ASR
MODUL WINGS MODUL WINGS
hellos as surfaced
HELLOS AS surfaced 4300lm 4000K 90
90 75
75 300
60
60
450 600
45
15 0 C0.0-C180.0
15
Type
30 C90.0-C270.0
HELLOS AS
MODUL BOX SQUARE SURF. 4100lm 3000K 90
90
75
75 200
60
MODUL BOX SQUARE surfaced
60
300 400
45
PAR-Vm
PAR MAT-Vm
(W)
• •
• •
3x14 3x24
Light source Optical system Wiring Materials Surface finish
4300
69
color rendering index
15 0 C0.0-C180.0
lamp
lampholder
FDH FDH
G5 G5
CLASSIC ASR II
thermal management
CRI (Ra)
correlated color temperature CCT (K)
30 C90.0-C270.0
Type
80
4000
•
LED Diffuser Dimmable electronic control gear DALI (10-100%) Housing: sheet steel, frame: extruded aluminium profile Diffuser: PMMA OPAL + PMMA diamond microprisma Black (RAL9005), silver grey (RAL 9006), other colors on request
MODUL BOX SQUARE MODUL BOX SQUARE MODUL BOX SQUARE MODUL BOX SQUARE
PRODUCTS
net lumen power output consumption (at Ta = 25 °C) (lm) (W) 950 950 4100 4100
14 14 52 52
color rendering index
(W)
• • • • • • • • • • • • • •
• • • • • • • • • • • • • •
• • • • • • • • • • • • • •
• • • • • • • • • • • • • •
2x36 3x18 4x18 4x36 2x28 2x54 3x14 3x24 4x14 4x24 4x28 4x54 3x40 3x55
60
150 220
45
45
250 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
CLASSIC XTP PRISMA FD 4x18W 90
90
75
FD FD FD FD FDH FDH FDH FDH FDH FDH FDH FDH FSDH FSDH
G8 G8 G8 G8 G5 G5 G5 G5 G5 G5 G5 G5 TL-C TL-C
75 100
60
60
150
45
45
200 30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
CLASSIC ASR PAR-V FDH 3x35W 90
90
75
75
80 120 160
60 45
60 45
140
optical system
power
PAR-V
PAR MAT-V
(W)
• • • •
• • • •
3x28 3x35 3x49 3x54
lamp
lampholder
FDH FDH FDH FDH
G5 G5 G5 G5
Light source Linear fluorescent lamp FDH (T5) Optical system Parabolic louvre (PAR-V/PAR MAT-V) Wiring Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, parabolic louvre: polished/mat aluminium, cover: clear plastic Surface finish Housing: white (RAL 9003), other colors on request
15 0 C0.0-C180.0
15
30 C90.0-C270.0
CLASSIC ASR II PAR-V FDH 3x80W 90
90
75
75
80 120 160
60 45
60 45
140 cd/klm
30
Type
optical system
power
PAR-V
PAR MAT-V
(W)
•
•
3x80
CLASSIC ASR II
lamp
lampholder
FDH
G5
15 0 C0.0-C180.0
15 30 C90.0-C270.0
PASSIVE
CLASSIC ASN ASYMMETRIC
Light source Linear fluorescent lamp FDH (T5)/FD (T8) Optical system Reflector (ASYMMETRIC) Wiring Electronic control gear On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, reflector: polished/mat aluminium Surface finish Housing: white (RAL 9003), other colors on request
CLASSIC ASN ASYMMETRIC FD 1x36W 90
90
75
75
100 150 200 250 300
60 45
60 45
cd/klm
30
Type
45 15
prisma
CLASSIC ASR CLASSIC ASR* CLASSIC ASR* CLASSIC ASR * version IP44 on request
cd/klm
30
opal
Type
LED Reflector + refractor Electronic control gear Housing: sheet steel, reflector: vacuum coated plastic, refractor: etched PMMA Housing: white (RAL 9003) net lumen power output consumption (at Ta = 25 °C) (lm) (W)
PAR MAT
75 100
60
lampholder
Light source Linear fluorescent lamp FDH (T5) Optical system Parabolic louvre (PAR-V/PAR MAT-V) Wiring Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, parabolic louvre: polished/mat aluminium, cover: clear plastic Surface finish Housing: white (RAL 9003) other colors on request
45
750 cd/klm
30
Light source Optical system Wiring Materials Surface finish
power
PAR
lamp
90
75
30
30 C90.0-C270.0
optical system
power
90
cd/klm
Linear fluorescent lamp FDH (T5) Parabolic microlouvre (PAR-Vm/PAR MAT-Vm) Electronic control gear On request: dimmable electronic control gear (1-10V/DSI/ DALI/switch DIM) Housing: polycarbonate + sheet steel, covers: sheet steel Parabolic microlouvre: anodized polished/mat aluminium Housing: black (RAL 9005), white (RAL 9003), other colors on request
Type
optical system
CLASSIC XTP PAR FD 4x18W
PASSIVE
cd/klm
30
Light source Linear fluorescent lamp FDH (T5)/FD (T8) Compact fluorescent lamp FSDH (TC-L) Optical system Parabolic louvre (PAR/PAR MAT), Diffuser (OPAL/PRISMA) Electronic control gear Wiring On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, parabolic louvre: polished/mat aluminium, cover: clear polycarbonate/clear hardened glass, diffuser: opal or prismatic polycarbonate, frame: elox aluminium Surface finish Housing: white (RAL 9003), other colors on request
thermal management
CRI (Ra)
correlated color temperature CCT (K)
>80 >80 >80 >80
3000 4000 3000 4000
• • • •
PASSIVE
CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM CLASSIC ASN ASYM
optical system
power
POLISHED
MAT
(W)
• • • • • • •
• • • • • • •
1x36 2x58 1x28 1x35 1x49 1x54 1x80
lamp
lampholder
FD FD FDH FDH FDH FDH FDH
G13 G13 G5 G5 G5 G5 G5
134/135
15 0 C0.0-C180.0
15
30 C90.0-C270.0
CLASSIC ASN PAR-V2 4x14W 90
90
75
75 200
60
CEILING SURFACED
CEILING SURFACED
CLASSIC ASN
modul lambda max
60
300 45
Light source Optical system Wiring Materials Surface finish
Linear fluorescent lamp FDH (T5) Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear 1-10V/switch DIM/DSI/DALI) Housing: sheet steel, parabolic louvre: polished/mat aluminium Powder coat finish – white (RAL 9003), other colors on request
Light source Optical system Wiring Materials Surface finish
Linear fluorescent lamp FDH Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel, parabolic louvre: polished/mat aluminium Housing: grey (RAL 9006), other colors on request
45
modul lambda 2x54W 120
120
200 150 100
105
105
90
90
75
75
60
60 cd/klm
cd/klm
30
15 0 C0.0-C180.0
15
45
30 C90.0-C270.0
Type
CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN CLASSIC ASN
CLASSIC ASN A1/A2/A3/A4/A5/A9
CLASSIC ASN PAR-V2 A1 3x14W 90
90
75
75 200
60
60
300 45
45
Light source Optical system Wiring Materials Surface finish
optical system
power
PAR-V2
PAR MAT-V2
(W)
• • • • • • • • • • • • • • • •
• • • • • • • • • • • • • • • •
1x14 1x24 1x28 1x35 1x49 1x54 1x80 2x14 2x24 2x28 2x35 2x49 2x54 2x80 4x14 4x24
lamp
lampholder Type
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
MODUL LAMBDA MAX MODUL LAMBDA MAX MODUL LAMBDA MAX MODUL LAMBDA MAX MODUL LAMBDA MAX
MODUL ray surfaced
Linear fluorescent lamp FDH Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel, parabolic louvre: polished/mat aluminium Powder coat finish – white (RAL 9003), other colors on request Bottom sheet: solid (DECOR L1)/perforated (DECOR L2)
Type
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
CLASSIC ASN A1 CLASSIC ASN A1 CLASSIC ASN A2 CLASSIC ASN A2 CLASSIC ASN A3 CLASSIC ASN A3 CLASSIC ASN A4 CLASSIC ASN A4 CLASSIC ASN A5 CLASSIC ASN A5 CLASSIC ASN A9 CLASSIC ASN A9
modul box surfaced
modul box surfaced 1800lm 4000K 90
90 75
75 200
60
60
300 400
45
Light source Optical system Wiring Materials Surface finish
Light source Optical system Wiring Materials Surface finish
optical system
power
PAR-V2
PAR MAT-V2
(W)
• • • • • • • • • • • •
• • • • • • • • • • • •
4x14 4x24 3x14 3x24 4x14 4x24 4x14 4x24 4x14 4x24 3x14 3x24
lamp
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
lampholder
optical system PAR-V2 PAR MAT-V2 • • • • •
lampholder
2x28 2x35 2x49 2x54 2x80
FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5
Linear fluorescent lamp FDH (T5) LED strips Parabolic microlouvre (PAR-Vm/PAR MAT-Vm) Diffuser Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: extruded aluminium Microlouvre: anodized polished/mat aluminium Diffuser: polycarbonate Housing end caps: polycarbonate Holder: sheet steel Housing: white (RAL 9003), grey (RAL 9006), black (RAL 9005)
optical system PAR-Vm
LED Diffuser Dimmable electronic control gear DALI (10-100%) Housing: sheet steel, frame: extruded aluminium profile Diffuser: PMMA OPAL + PMMA diamond microprisma Black (RAL9005), silver grey (RAL 9006), other colors on request
lamp
• • • • •
power
PAR MAT-Vm
(W)
• • • • • • • • • • • • • • • • • • • • •
1x14* 1x24* 1x28* 1x35* 1x49* 1x54* 1x80* 2x14 2x24 2x28 2x35 2x49 2x54 2x80 3x14 3x24 3x28 3x35 3x49 3x54 3x80
• MODUL RAY MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • MODUL RAY • * Blue LED ambient lighting on request
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
power (W)
lamp
lampholder
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
MODUL RAY DIR-INDIR PAR-Vm 2x28W 120
120
160 120 80
105
105
90
90
75
75
60
60 cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
45
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
optical system DIFFUSER
modul box sus.
modul lambda
modul lambda 1x54W 120
120
200 150 100
105
105
90
90
75
75
60
Light source Optical system Wiring Materials Surface finish
•
net lumen power color correlated thermal output consumption rendering color management (at Ta = 25 °C) index temperature (lm) (W) CRI (Ra) CCT (K) PASSIVE 1800
35
>80
4000
•
Linear fluorescent lamp FDH Parabolic louvre (PAR-V2/PAR MAT-V2) Electronic control gear On request: dimmable electronic control gear (1-10V/DSI/DALI/switch DIM) Housing: sheet steel, parabolic louvre: polished/mat aluminium Housing: grey (RAL 9006), other colors on request
60 cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
Type
MODUL LAMBDA MODUL LAMBDA MODUL LAMBDA MODUL LAMBDA MODUL LAMBDA
PRODUCTS
optical system PAR-V2 PAR mAT-V2 • • • • •
• • • • •
power (W)
lamp
lampholder
1x28 1x35 1x49 1x54 1x80
FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5
plastic PLAST H
Light source Linear fluorescent lamp FDH (T5) Optical system Diffuser (OPAL/PRISMA) Wiring Electronic control gear On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, diffuser: prismatic or opal polycarbonate, end caps: white polycarbonate Surface finish Housing: white (RAL 9003), other colors on request
PLAST H OPAL FDH 1x28W 150 125 100 75 50
120 105 90
90
75
75
60
PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H PLASTIC PLAST H
optical system REFLECTOR OPAL PRISMA • • • • • • • • • • • • • • • • • • • • • •
power (W)
lamp
lamp holder
1x14 1x24 1x28 1x35 1x49 1x54 1x80 2x14 2x28 2x35 2x49
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
60
cd/klm
45
Type
120 105
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
PLAST H PRISMA FDH 1x28W
136/137
120
120
200 160 120 80
105
105
90
90
75
75
60
60
cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
ceiling recessed
ceiling recessed
Recessed luminaires suitable for fitting into plasterboard ceilings. Its design does not interfere with the atmosphere of the room. These luminaires can find their utilization in applications with low ceilings. Into this group belongs luminaires of type downlights, adjustable downlights and then luminaires which are designed
downlight CASTRA
mainly for the office lighting (600x600), but they also find their application in lighting for retail areas. Luminaires can be fitted with several types of light sources. From the most efficient LED through metal - halide lamps to fluorescent lamps. According to the type of luminaire
downlight
downlight comet motion
90
90
75
75
60
60 4000
45
lamp, against which it has significantly lower power consumption and longer lifetime (LED – 50 000 h, discharge lamp – 15 000 h), • choice of the light color – warm white light is suitable for illuminating fruits, vegetables and pastries, neutral white light color can highlight textiles, dairy products and fish, • choice of various decorative elements to create a pleasant atmosphere of the premises, • quality optical parts to reduce direct glare to a minimum, • choice of different color filters, • low power consumption
Light source LED Electronic control gear Wiring On request: dimmable electronic control gear DALI (10-100%) Materials Housing: extruded aluminium + aluminium, trim: sheet steel, tilting and lifting mechanism: sheet steel, nickel plated steel, spring steel, reflector: facet metallized aluminium Surface finish White / black
Type
DOWNLIGHT CASTRA DOWNLIGHT CASTRA DOWNLIGHT CASTRA DOWNLIGHT CASTRA DOWNLIGHT CASTRA DOWNLIGHT CASTRA DOWNLIGHT CASTRA DOWNLIGHT CASTRA
DOWNLIGHT CASTOR
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
DOWN. Comet motion DOWN. Comet motion DOWN. Comet motion DOWN. Comet motion DOWN. Comet motion DOWN. Comet motion * >90 Ra on request
DOWNLIGHT AVIOR MOTION
DOWNLIGHT AVIOR MOTION LED 24° 1400lm 4000K 90
90
75
75 60
60 4000
45
net lumen power output consumption (at Ta = 25 °C) (lm) (W) 1300 1400 2500 2700 4000 4300
18 18 31 31 53 53
color rendering index CRI (Ra) 83* 83* 83* 83* 83* 83*
correlated thermal color management temperature CCT (K) PASSIVE 3000 4000 3000 4000 3000 4000
• • • • • •
beam angle
15 0 C0.0-C180.0
15
24°/40° 24°/40° 24°/40° 24°/40° 24°/40° 24°/40°
DOWNLIGHT CASTOR DOWNLIGHT CASTOR DOWNLIGHT CASTOR DOWNLIGHT CASTOR DOWNLIGHT CASTOR DOWNLIGHT CASTOR DOWNLIGHT CASTOR DOWNLIGHT CASTOR
Light source LED Optical system Reflector Wiring Electronic control gear, on request: dimmable electronic control gear DALI (10 - 100%) Materials Housing: die cast aluminium, trim: sheet steel, tilting and lifting mechanism: sheet steel, nickel plated steel, spring steel, reflector: facet metallized aluminium Surface finish Housing: white (RAL 9003)
Type
DOWNLIGHT AVIOR MOTION LED 40° 1400lm 4000K 90
90
75
75
60
60
3000 4000
45
DOWN. AVIOR MOTION DOWN. AVIOR MOTION DOWN. AVIOR MOTION DOWN. AVIOR MOTION DOWN. AVIOR MOTION DOWN. AVIOR MOTION * >90 Ra on request
45
5000 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
DOWNLIGHT PROXIMA
DOWNLIGHT PROXIMA 125 MT 1x70W 90
90
75
75 400
60
60
600 45
45
800 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
net lumen power output consumption (at Ta = 25 °C) (lm) (W) 1300 1400 2500 2700 4000 4300
18 18 31 31 53 53
color rendering index CRI (Ra) 83* 83* 83* 83* 83* 83*
correlated thermal color management temperature CCT (K) PASSIVE 3000 4000 3000 4000 3000 4000
• • • • • •
beam angle
75 400
60
60
600 45
45
800
Light source Optical system Wiring Materials Surface finish
power (W)
lamp
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
650 650 900 900 1800 1800 2650 2650
10 10 15 15 27 27 37 37
>90 >90 >90 >90 >90 >90 >90 >90
3000 4000 3000 4000 3000 4000 3000 4000
• • • • • • • •
15 0 C0.0-C180.0
15
30 C90.0-C270.0
beam angle
PASSIVE 60°/74° 60°/74° 60°/74° 60°/74° 60°/74° 60°/74° 60°/74° 60°/74°
LED Reflector Electronic control gear On request: DALI (5-100%) Housing: polycarbonate, reflector: anodished polished aluminium Trim: sheet steel, holders: zinc coated sheet steel Trim: white (RAL 9003), other colors on request
DOWNLIGHT CASTOR LED 60° 2650lm 4000K 90
90
75
75 400
60
60
600 45
45
800
lamp holder
net lumen output (at Ta = 25 °C) (lm) 650 650 900 900 1800 1800 2650 2650
power color consumption rendering index (W) CRI (Ra) 10 10 15 15 27 27 37 37
>90 >90 >90 >90 >90 >90 >90 >90
correlated color temperature CCT (K)
thermal management
3000 4000 3000 4000 3000 4000 3000 4000
• • • • • • • •
15 0 C0.0-C180.0
15
30 C90.0-C270.0
beam angle
PASSIVE 60°/74° 60°/74° 60°/74° 60°/74° 60°/74° 60°/74° 60°/74° 60°/74°
LED Diffuser Dimmable electronic control gear - thyristor dimmer (5-100%) Housing: sheet steel, diffuser: opal plast Trim: sheet steel, holders: zinc coated sheet steel Trim: white (RAL 9003), other colors on request
DOWNLIGHT CYGNUS LED 90° 1100lm 4000K 90
90 75
75 60
60
200 300
45
cd/klm
30
Type
DOWNLIGHT CYGNUS DOWNLIGHT CYGNUS DOWNLIGHT CYGNUS DOWNLIGHT CYGNUS
optical system REFLECTOR
net lumen output (at Ta = 25 °C) (lm)
45
24°/40° 24°/40° 24°/40° 24°/40° 24°/40° 24°/40°
Light source Metalhalide lamp MT (HIT), sodium lamp STH (HST) Optical system Reflector Wiring Conventional magnetic control gear with an ignitor,light fixtures are standardly compensated, electronic control gear Materials Housing: die cast aluminium, reflector: anodized polished aluminium, rotational trim: polycarbonate, installation trim: polycarbonate, trim: die cast aluminium, tilting handle: polycarbonate Surface finish Housing: white (RAL 9003) Type
Light source Optical system Wiring Materials Surface finish
Type
DOWNLIGHT cygnus II
30 C90.0-C270.0
90
75
30
cd/klm
30
90
cd/klm
45
5000
DOWNLIGHT CASTRA LED 60° 2650lm 4000 K
30
45
5000
LED Electronic control gear On request: DALI (5-100%) Housing: polycarbonate, reflector: anodished polished aluminium Trim: sheet steel, plasterboard trim: aluminium profile Holders: zinc coated sheet steel Trim, plasterboard trim: white (RAL 9003), other colors on request
cd/klm
The Downlight luminaires offer a wide variability of use and a wide range of versions. They are used especially for lighting food, corridors, halls and service areas of the hypermarket. We can mention some of their advantages: • a possibility to use an opal cover which prevents glare. This option is useful for illuminating glossy products (e.g. bread wrapped in cellophane and other products packed in shiny foils), • when using an LED chip, it is possible to control the luminous flux simply by an addressable ballast through the DALI protocol, and thus on/off switch and dimming of the luminaire. The LED chip can replace 35 W metal halide
DOWNLIGHT COMET MOTION LED 24° 1400lm 4000K
Light source Wiring Materials Surface finish
DOWNLIGHT MIRA
Light source Optical system Wiring Materials Surface finish
net lumen output (at Ta = 25 °C) (lm) 700 700 1100 1100
power color consumption rendering index (W) CRI (Ra) 10 10 15 15
>90 >90 >90 >90
correlated color temperature CCT (K)
thermal management
3000 4000 3000 4000
• • • •
beam angle
15 0 C0.0-C180.0
15
30 C90.0-C270.0
PASSIVE 90° 90° 90° 90°
LED Reflector + refractor Electronic control gear Trim:sheet steel, housing: die cast aluminium, reflector: vacuum coated plastic Refractor: etched PMMA, holders: zinc coated sheet steel Trim: white (RAL 9003), other colors on request
DOWNLIGHT MIRA 67° 2600lm 4000K 90
90 75
75 300
60
60
450 600
45
45
750 cd/klm
DOWNLIGHT PROXIMA 125 DOWNLIGHT PROXIMA 125 DOWNLIGHT PROXIMA 125 DOWNLIGHT PROXIMA 125 DOWNLIGHT PROXIMA 125 DOWNLIGHT PROXIMA 125
PRODUCTS
• • • • • •
1x35 1x20 1x50 1x70 1x100 1x150
MT STH STH MT STH MT
G12 G12 G12 G12 G12 G12
30
Type
DOWNLIGHT MIRA
net lumen output (at Ta = 25 °C) (lm) 2600
power color consumption rendering index (W) CRI (Ra) 43
>80
correlated color temperature CCT (K)
thermal management
4000
•
beam angle
PASSIVE 67°
138/139
15 0 C0.0-C180.0
15
30 C90.0-C270.0
DOWNLIGHT PROPUS LED 71° 3000lm 3000K 90
ceiling recessed
ceiling recessed
DOWNLIGHT PROPUS
downlight QUADRO
90 75
75 60
60
400 600
45
Light source Optical system Wiring Materials Surface finish
LED Reflector Electronic control gear, on request: dimmable electronic control gear DALI (10-100%) Housing: sheet steel, reflector: anodized aluminium Trim: sheet steel, holders: zinc coated sheet steel Trim: white (RAL 9003), other colors on request
15 0 C0.0-C180.0
Type
15
30 C90.0-C270.0
Type
DOWNLIGHT VISION LED
DOWNLIGHT VISION POLISHED 99° 3000lm 4000K 90
90 75
400 600 800 1000 1200
60 45
DOWNLIGHT QUADRO 74° 3600lm 4000K 90
90 75
75 300
net lumen output (at Ta = 25 °C) (lm)
power consumption (W)
color rendering index CRI (Ra)
1100 1100 2000 2000 3000 3000
15 13 28 26 50 46
80 80 80 80 80 80
60
correlated thermal color management temperature CCT (K) PASSIVE 3000 4000 3000 4000 3000 4000
• • • • • •
beam angle
power consumption (W)
color rendering index CRI (Ra)
1100 1200 2100 2300 3400 3600
18 18 31 31 53 53
83 83 83 83 83 83
DOWNLIGHT QUADRO DOWNLIGHT QUADRO DOWNLIGHT QUADRO DOWNLIGHT QUADRO DOWNLIGHT QUADRO DOWNLIGHT QUADRO
71° 71° 71° 71° 71° 71°
Light source LED Optical system Reflector Electronic control gear, on request: dimmable electronic control gear DALI/DMX Wiring Materials Housing: cover - PBT, inst. plate - zinc coated sheet Reflector: polycarbonate - evaporative coating (polished/white) Surface finish Trim: white (RAL9003), other colors on request
net lumen output (at Ta = 25 °C) (lm)
CAPH
45
Light source Optical system Wiring Materials Surface finish
correlated thermal color management temperature CCT (K) PASSIVE 3000 4000 3000 4000 3000 4000
beam angle
600
45
45
750 cd/klm
30
• • • • • •
60
450
45
DOWNLIGHT PROPUS DOWNLIGHT PROPUS DOWNLIGHT PROPUS DOWNLIGHT PROPUS DOWNLIGHT PROPUS DOWNLIGHT PROPUS
75
LED Dimmable electronic control gear DALI (10-100%)/switch DIM Housing: sheet steel, reflector: polished anodized aluminium Diffuser: PMMA diamond microprisma, trim: sheet steel Housing: white (RAL9003), trim: white (RAL9003), other colors on request
60
cd/klm
30
Light source Wiring Materials Surface finish
15 0 C0.0-C180.0
15
30 C90.0-C270.0
74° 74° 74° 74° 74° 74°
LED Diffuser Dimmable electronic control gear DALI (10-100%) (separate gearbox, cable length 0,5m) Housing: sheet steel Diffuser: PMMA OPAL + PMMA diamond microprisma White (RAL 9003), other colors on request
CAPH 2000lm 4000K 90
90
75
75 200
60
60
300
45
cd/klm
45
400 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
DOWNLIGHT VISION WHITE 99° 3000lm 4000K 90
DOWNLIGHT VISION 190 LED DOWNLIGHT VISION 190 LED DOWNLIGHT VISION 190 LED DOWNLIGHT VISION 190 LED DOWNLIGHT VISION 190 LED DOWNLIGHT VISION 190 LED DOWNLIGHT VISION 190 LED DOWNLIGHT VISION 190 LED
90
75
75 200
60
60
300
45
45 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
downlight SQUARE
DOWNLIGHT SQUARE 80° 2950lm 4000K 90
90
75
75 300
60
net lumen power color output consumption rendering (at Ta = 25 °C) index (lm) (W) CRI (Ra)
60
Light source Wiring Materials Surface finish
900 1800 1100 1100 2000 2000 3000 3000
40 50 15 13 28 26 50 46
80 80 80 80 80 80 80 80
correlated thermal color management temperature CCT (K) PASSIVE 2700-6500+RGB 2700-6500+RGB 3000 4000 3000 4000 3000 4000
– – • • • • • •
30
beam angle
99° 99° 99° 99° 99° 99° 99° 99°
Type
hellos
LED Electronic control gear On request: dimmable electronic control gear DALI (10-100%) Housing: sheet steel, reflector: polished anodized aluminium Trim: sheet steel + MIRO5 aluminium, frame: aluminium profile Housing: white (RAL9003), trim: white (RAL9003), other colors on request
cd/klm
30
15 0 C0.0-C180.0
15
Type
30 C90.0-C270.0
DOWNLIGHT SQUARE DOWNLIGHT SQUARE DOWNLIGHT SQUARE DOWNLIGHT SQUARE DOWNLIGHT SQUARE DOWNLIGHT SQUARE
downlight SQUARE TRIMLESS
DOWNLIGHT SQUARE TRIMLESS 80° 2950lm 4000K 90
90
75
75 300
60
60
Light source Wiring Materials Surface finish
net lumen output (at Ta = 25 °C) (lm)
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
1050 1050 1950 1950 2950 2950
15 13 28 26 50 46
80 80 80 80 80 80
3000 4000 3000 4000 3000 4000
• • • • • •
450 45
45
600 cd/klm
30
15 0 C0.0-C180.0
15
Type
30 C90.0-C270.0
DOWNLIGHT SQUARE DOWNLIGHT SQUARE DOWNLIGHT SQUARE DOWNLIGHT SQUARE DOWNLIGHT SQUARE DOWNLIGHT SQUARE
PRODUCTS
net lumen output (at Ta = 25 °C) (lm)
power consumption (W)
color rendering index CRI (Ra)
1050 1050 1950 1950 2950 2950
15 13 28 26 50 46
80 80 80 80 80 80
correlated thermal color management temperature CCT (K) PASSIVE 3000 4000 3000 4000 3000 4000
• • • • • •
beam angle
45
93
4000
•
30 C90.0-C270.0
HELLOS 4300lm 4000K 90
90 75
75 300
60
60
450 600
45
750 cd/klm
30
Type
net lumen output (at Ta = 25 °C) (lm)
power consumption
2150 4300 4300
HELLOS PV-3 HELLOS PV-1 HELLOS PV-4
PASSIVE
LED Electronic control gear On request: dimmable electronic control gear DALI (10-100%) Housing: sheet steel, reflector: polished anodized aluminium Trim: sheet steel + MIRO5 aluminium, frame: aluminium profile Housing: white (RAL9003), trim: white (RAL9003), other colors on request
2000
15
PASSIVE
45
beam angle
80° 80° 80° 80° 80° 80°
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
Light source LED Optical system Reflector+ refractor Wiring Electronic control gear Materials Housing: sheet steel Reflector: vacuum coated plastic Refractor: etched PMMA Surface finish Housing: white (RAL 9003)
45
600
power consumption
CAPH
450 45
net lumen output (at Ta = 25 °C) (lm)
15 0 C0.0-C180.0
GACRUX
correlated color temperature CCT (K)
thermal management
(W)
colo rendering index CRI (Ra)
34 69 69
80 80 80
4000 4000 4000
• • •
GACRUX PV-1 MICROPRISMA GACRUX PV-4 MICROPRISMA GACRUX PV-1 OPAL GACRUX PV-4 OPAL
net lumen output (at Ta = 25 °C) (lm)
power consumption
3900 4400 3550 4000
15
30 C90.0-C270.0
PASSIVE
Light source LED Optical system Diffuser Wiring Dimmable electronic control gear 0-10V Materials Housing: sheet steel, diffuser: PMMA OPAL + PMMA diamond microprisma Surface finish White (RAL 9003), other colors on request Type
15 0 C0.0-C180.0
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
51 51 51 51
>80 >80 >80 >80
3000/4000 3000/4000 3000/4000 3000/4000
• • • •
PASSIVE
80° 80° 80° 80° 80° 80°
140/141
GACRUX 4000lm 4000K 90
90 75
75 200
60
60
300 400
45
45
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
INDIRECT VEGA LED 7150lm 4000K 90
ceiling recessed
ceiling recessed
VEGA PV exclusivE
MIRZAM
90
75
75
80 120 160
60 45
60
30
15 0 C0.0-C180.0
15
Type
net lumen output (at Ta = 25 °C) (lm)
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
2200 3600 4700 7150
31 55 74 112
>80 >80 >80 >80
4000 4000 4000 4000
• • • •
PASSIVE
MIRZAM MIRZAM
RELAX XTP LED VEGA PV STANDARD
INDIRECT VEGA LED 3200lm 4000K 90
90
75
75
80 120 160
45
60
30
15 0 C0.0-C180.0
Light source LED Optical system Reflector, diffuser Wiring Dimmable electronic control gear DALI (10-100%) Materials Housing: sheet steel, reflector: alumium sheet Diffuser: opal PMMA Surface finish Housing and reflector: white (RAL 9003)
15
30 C90.0-C270.0
Type
VEGA STANDARD PV-1 VEGA STANDARD PV-1
SAIPH
INDIRECT SAIPH LED 4000lm 4000K 90
90 75
75 60
60
200 300
45
90
45
net lumen output (at Ta = 25 °C) (lm)
power consumption
3000 3200
15 0 C0.0-C180.0
15
Type
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
45 45
>80 >80
3000 4000
• •
RELAX XTP LED RELAX XTP LED
60
SAIPH PV-1 SAIPH PV-1 SAIPH PV-2 SAIPH PV-2
power consumption
3000 3000 4000 4000
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
3500 3300
52 52
80 80
3000 4000
• •
60
300 400
45
45
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
PASSIVE
RELAX XTP LED 3400lm 4000K 90
90
75
75 200
60
60
300 45
45
400
net lumen output (at Ta = 25 °C) (lm)
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
3300 3400
49 49
80 80
3000 4000
• •
15 0 C0.0-C180.0
15
30 C90.0-C270.0
PASSIVE
PASSIVE
LINE RANGE PB 100 led single piece
Light source LED Optical system Diffuser Wiring Dimmable electronic control gear DALI (10-100%) Materials Housing: sheet steel, reflector: aluminium, diffuser: opal PMMA Surface finish Housing: white (RAL 9003) Reflector: white (RAL 9003), other colors on request
LINE RANGE PB 100 led single piece 4700lm 4000K 90
90
75
75 800
60
60
1200 45
45
1600 cd/klm
Type
net lumen output (at Ta = 25 °C) (lm)
power consumption
4550 4700
LINE RANGE PB 100 SINGLE PIECE LINE RANGE PB 100 SINGLE PIECE
30 C90.0-C270.0
net lumen output (at Ta = 25 °C) (lm)
power consumption
75 200
30
Light source LED Optical system Diffuser Wiring Electronic control gear On request: dimmable electronic control gear DALI (10-100%)/ 1-10V (5-100%) Materials Housing: sheet steel, diffuser: opal Surface finish Housing: white (RAL 9003)
Type
net lumen output (at Ta = 25 °C) (lm)
90
75
cd/klm
cd/klm
30
MIRZAM 3300lm 4000K
Light source LED Optical system Diffuser Wiring Electronic control gear On request: dimmable electronic control gear DALI (10-100%) Materials Housing: sheet steel, frame: extruded aluminium Diffuser: PMMA OPAL + PMMA diamond microprisma, cover: polycarbonate Surface finish White (RAL 9003)
45
240
cd/klm
LED Diffuser Dimmable electronic control gear DALI (1-100%) Housing: sheet steel, diffuser: opal textured plastic White (RAL 9003)
Type
30 C90.0-C270.0
VEGA EXCLUSIVE PV-1 VEGA EXCLUSIVE PV-1 VEGA EXCLUSIVE PV-2 VEGA EXCLUSIVE PV-2
60
Light source Optical system Wiring Materials Surface finish
45
240
cd/klm
Light source LED Optical system Reflector, diffuser Wiring Dimmable electronic control gear DALI (10-100%) Materials Housing: sheet steel, reflector: aluminum sheet Diffuser: acryl satine Surface finish Housing: white (RAL 9003), reflector: white (RAL 9003)
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
34 34 36 36
90 90 90 90
3000 4000 3000 4000
• • • •
PASSIVE
LINE snappy SINGLE PIECE
Light source Optical system Wiring Materials Surface finish
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
59 59
>80 >80
3000 4000
• •
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
PASSIVE
LED Diffuser Electronic control gear Housing: extruded aluminium, diffuser: opal polycarbonate Fixing accessories: zinc coated sheet steel White (RAL 9003)
LINE SNAPPY LED 4100lm 4000K 90
90
75
75
100 150 200 250 300
60 45
60 45
cd/klm
Type
terzo LED
TERZO LED 4500lm 3000K 90
90
75
75
200 300 400 500
60 45
60
Light source Optical system Wiring Materials Surface finish
LED Diffuser, parabolic louvre (PAR-L) Dimmable electronic control gear DALI (10-100%) Housing: sheet steel, diffuser: vacuum moulded opal polycarbonate Parabolic louvre: anodized polished aluminium Housing: white (RAL 9003)
LINE SNAPPY SINGLE PIECE LINE SNAPPY SINGLE PIECE
45
RELAX ASYMMETRIC led
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
TERZO LED TERZO LED TERZO LED
net lumen output (at Ta = 25 °C) (lm) 4200 4500 4500
power consumption (W) 68 68 68
color rendering index CRI (Ra) 80 80 80
correlated color temperature CCT (K) 3000 4000 3000-6500
thermal management PASSIVE • • •
Light source Optical system Wiring Materials Surface finish
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
4100 4100
66 66
80 80
3000 3000
• •
15 0 C0.0-C180.0
15
30 C90.0-C270.0
PASSIVE
LED Asymmetric reflector Electronic control gear On request: dimmable electronic control gear DALI (10-100%) Housing: sheet steel, reflector: polished aluminium Housing: white (RAL 9003), other colors on request
relax asymmetric led 3550lm 4000K 90
90
75
75
60
60 450
45
45
600 cd/klm
30
Type
RELAX ASYM. LED RELAX ASYM. LED RELAX ASYM. LED
PRODUCTS
net lumen output (at Ta = 25 °C) (lm)
30
net lumen output (at Ta = 25 °C) (lm)
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
3550 3550 3550
47 47 47
80 80 80
3000 4000 3000-6500
• • •
PASSIVE
142/143
15 0 C0.0-C180.0
15
30 C90.0-C270.0
RELAX PV ASYMMETRIC POLISHED FD 1x18W 90
ceiling recessed
TRACK system
RELAX PV ASYMMETRIC
vario track diffuse
90
75
75
80 120 160 200
60 45
60 45
240
Light source Optical system Wiring Materials Surface finish
Linear fluorescent lamp FDH (T5)/FD (T8) Compact fluorescent lamp FSD/FSDH (TC-L) Reflector (ASYMMETRIC) Electronic control gear On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Housing: sheet steel, reflector: polished/mat aluminium Housing: white (RAL 9003), other colors on request
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Light source Linear fluorescent lamp FDH (T5) Optical system Diffuser Wiring Electronic control gear On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, plastic box for control gear: ABS, diffuser: opal polycarbonate Surface finish Housing: grey (RAL 9006) Plastic box for control gear: grey with metal pigment
VARIO TRACK DIFFUSE FDH 2x28W 120
optical system REFLECTOR MAT POLISHED
RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC RELAX PV ASYMMETRIC
• • • • • • • • • • • • • •
power
lamp
lampholder
Type
(W)
• • • • • • • • • • • • • •
1x18 1x36 1x14 1x24 1x28 1x54 2x14 2x24 2x28 2x54 1x40 1x55 2x40 2x55
FD FD FDH FDH FDH FDH FDH FDH FDH FDH FSDH FSDH FSDH FSDH
G13 G13 G5 G5 G5 G5 G5 G5 G5 G5 2G11 2G11 2G11 2G11
optical system DIFFUSER opal
power
• •
2x28 2x54
VARIO TRACK DIFFUSE VARIO TRACK DIFFUSE
lamp
lamp holder
FDH FDH
G5 G5
105
90
90
75
75
60
60
cd/klm
45
Type
120
160 120 80
105
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
(W)
vario track system
TRACK system vario track 11/12 LED
TRACK VARIO 11 LED 24° 2200lm 4000K 90
90 75
75 1000 1500 2000 2500
60 45
60 45
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
net lumen output (at Ta = 25 °C) (lm)
power consumption (W)
VARIO TRACK 11 LED 1100 31 (26*) VARIO TRACK 11 LED 1100 29 (24*) VARIO TRACK 12 LED 2200 62 (52*) VARIO TRACK 12 LED 2200 58 (48*) * power consumption without decorative LED trim
vario track exe/exe twin par-v2/par mat-v2
VARIO TRACK EXE TWIN PAR-V2 FDH 2x54W 120
120
160 120 80
105
105
90
90
75
75
60
60 cd/klm
45
30 15 0 C0.0-C180.0
15
90
90
75
75 200
45
300 15 0 C0.0-C180.0
>80 >80 >80 >80
3000 4000 3000 4000
optical system PAR-V2
VARIO TRACK EXE VARIO TRACK EXE VARIO TRACK EXE VARIO TRACK EXE VARIO TRACK EXE VARIO TRACK EXE TWIN VARIO TRACK EXE TWIN VARIO TRACK EXE TWIN VARIO TRACK EXE TWIN VARIO TRACK EXE TWIN
60 45 15
correlated thermal color management temperature CCT (K) PASSIVE • • • •
beam angle
30 C90.0-C270.0
PRODUCTS
• • • • • – – – – –
PAR MAT-V2 • • • • • – – – – –
power
PAR-V2 PAR MAT-V2 DIR/INDIR DIR/INDIR • • • • • • • • • •
• • • • • • • • • •
lamp
lamp holder
(W) 1x28 1x35 1x49 1x54 1x80 2x28 2x35 2x49 2x54 2x80
FDH FDH FDH FDH FDH FDH FDH FDH FDH FDH
WALL CYGNUS
24° 24° 24° 24°
Light source Linear fluorescent lamp FDH (T5) Optical system Parabolic louvre (PAR-V2/PAR MAT-V2) Wiring Electronic control gear On request: Dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Materials Housing: sheet steel, plastic box for control gear: ABS, installation plate: galvanised sheet steel, parabolic louvre: anodized polished or mat aluminium Surface finish Housing: grey (RAL 9006) Plastic box for control gear: grey with metal pigment Type
cd/klm
30
color rendering index CRI (Ra)
Luminaires are designed for wall mounting. Thanks to their light distribution source, which creates on the wall elipsoidal traces of the light. The second one up and down we are able to emphasize vertical surfaces. There are two types is luminaire with linear light source, which creates uniform lighting across the of these wall mounted luminaires. The first one is luminaire with a point light whole wall from the ceiling to the floor.
30 45 C90.0-C270.0
VARIO TRACK EXE DIR PAR-V2 FDH 1x28W
60
wall mounted
Light source LED Optical system Reflector Wiring Electronic control gear On request: dimmable electronic control gear DALI (10-100%) Materials Housing: aluminium profile, plastic box for control gear: ABS Installation plate: galvanised sheet steel Surface finish Housing: grey (RAL 9006) Plastic box for control gear: grey with metal pigment
G5 G5 G5 G5 G5 G5 G5 G5 G5 G5
Light source Optical system Wiring Materials Surface finish
LED Diffuser Dimmable electronic control gear - thyristor dimming (5-100%) Housing: sheet steel, diffuser: opal plast Grey (RAL 9006), other colors on request
WALL CYGNUS LED 90° 1000lm 4000K 90
90
75
75 200
60
60
300
Type
WALL CYGNUS WALL CYGNUS WALL CYGNUS WALL CYGNUS
avant wall LED
Light source Optical system Wiring Materials Surface finish Type
AVANT WALL OPAL AVANT WALL OPAL AVANT WALL MICROPRISMA AVANT WALL MICROPRISMA
net lumen output (at Ta = 25 °C) (lm)
power consumption (W)
color rendering index CRI (Ra)
700 700 1000 1000
10 10 15 15
>90 >90 >90 >90
correlated thermal color management temperature CCT (K) PASSIVE 3000 4000 3000 4000
• • • •
beam angle
power consumption (W)
color rendering index CRI (Ra)
5050 5050 4200 4200
72 72 72 72
>80 >80 >80 >80
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
AVANT WALL led 5050lm 4000K 300 250 200 150 100
120 105
90
75
75
144/145
60
cd/klm
45
• • • •
120 105
90
60
correlated thermal color management temperature CCT (K) PASSIVE 4000 3000 4000 3000
45 cd/klm
90° 90° 90° 90°
LED Diffuser (OPAL/MICROPRISMA) Dimmable electronic control gear DALI (10-100%) Housing: extruded aluminium, end caps: die cast aluminium Diffuser: PC/PMMA, diffuser end caps: PC/PMMA Wall bracket: steel profile + PC/ABS Carrying plate: extruded aluminium Powder coat finish – grey (RAL 9006) net lumen output (at Ta = 25 °C) (lm)
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
AVANT WALL ASYMMETRIC 2x28W 300 250 200 150 100
120 105
avant wall
Emergency luminaires are intended for emergency lighting. Low power consumption enables a three-hour operation, the standard EN 1838 requires a minimum one-hour operation of a luminaire. These luminaires have many advantages, such as: • Choice of pendant, wall or ceiling mounting,
• Quality light sources such as LED or compact fluorescent lamp, • Ni-Cd batteries with long life, • choice of four types of pictograms, • charging indicator, which informs what is the current battery level of a luminaire, • test button, which serves as a control of functions of the emergency circuit.
UX-EMERGENCY 2600
LED Ni-Cd battery, protection of battery against total discharge Protection of battery against overload and discharge Housing: white polycarbonate, diffuser: opal polycarbonate White LED charging indicator
120
90
75
75 60
cd/klm
45
EMERGENCY
105
90
60
wall mounted 30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
Light source Optical system Wiring Materials Surface finish
Linear fluorescent lamp FDH (T5) Diffuser (OPAL/MICROPRISMA) Parabolic louvre (PAR-V/PAR MAT-V) Reflector (SYMMETRIC/ASYMMETRIC) Electronic control gear On request: dimmable electronic control gear (1-10V/ switch DIM/DSI/DALI) Housing: extruded aluminium, end caps: die cast aluminium Diffuser: PC/PMMA, diffuser end caps: PC/PMMA Reflector: anodized polished aluminium, reflector end caps: ABS/PMMA Parabolic louvre: polished or mat aluminium Carrying plate: extruded aluminium Powder coat finish – grey (RAL 9006)
Type
optical system PAR-V PAR MAT-V OPAL MICROPRISMA SYM
AVANT WALL AVANT WALL AVANT WALL AVANT WALL AVANT WALL AVANT WALL AVANT WALL AVANT WALL AVANT WALL
• • • • • • • • •
• • • • • • • • •
• • • • • • • • •
• • • • • • • • •
ASYM
• • • • • • • • •
• • • • • • • • •
power lamp lampholder consumption (W) 1x28 1x35 1x49 1x54 1x80 2x28 2x54 2x35 2x49
FDH FDH FDH FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5 G5 G5 G5
box freestanding
300
120
120
200
105
105
100
90
90
75
75
60
60
cd/klm
45
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
Light source Optical system Wiring Materials Surface finish
Type
BOX FREESTANDING BOX FREESTANDING
Type
UX-Emergency 2601 UX-Emergency 2602 UX-Emergency 2603 UX-Emergency 2604
UX-EMERGENCY 2610
freestanding box freestanding 8950lm 4000K
LED DIR (diffuser)/INDIR (reflector asymmetric) Electronic control gear Housing: sheet steel, frame: extruded aluminium profile Diffuser: PMMA OPAL + PMMA diamond microprisma Reflector: mat aluminium Black (RAL9005), silver grey (RAL 9006) Other colors on request
net lumen output (at Ta = 25 °C) (lm)
power consumption
8750 8950
Light source Wiring Materials Surface finish Accessories
Light source Wiring Materials Surface finish Accessories
Type
UX-Emergency 2611 UX-Emergency 2612 UX-Emergency 2613 UX-Emergency 2614
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
118 118
80 80
3000 4000
• •
PASSIVE
UX-EMERGENCY 2810
Light source Wiring Materials Surface finish Accessories
Type
UX-Emergency 2811 UX-Emergency 2812
UX-EMERGENCY 2760
battery (Ni-Cd)
duration (h)
light output (lm)
2 2 2 2
3.6 V/1 Ah 3.6 V/1 Ah 3.6 V/1.5 Ah 3.6 V/1.5 Ah
1 1 3 3
25 25 25 25
LED Ni-Cd battery, protection of battery against overload and discharge Housing: sheet steel, painted white or grey, diffuser: plexiglass White LED charging indicator, test pushbutton
power consumption (W)
battery (Ni-Cd)
duration (h)
light output (lm)
2 2 2 2
3.6 V/2.5 Ah 3.6 V/2.5 Ah 3.6 V/2.5 Ah 3.6 V/2.5 Ah
1 1 3 3
25 25 25 25
LED Ni-Cd battery, protection of battery against overload and discharge Housing: aluminium profile, luminaire surfaces: plexiglass White LED charging indicator, test pushbutton – for emergency circuit function control
nr. of LED‘s
8 LEDs 11 (EXIT 6) LEDs
power consumption (W)
battery
duration
light output
(Ni-Cd)
(h)
(lm)
5 6
3.6 V/1 Ah 3.6 V/1 Ah
3 3
18/18 22/18
Light source LED Wiring Ni-Cd battery, protection of battery against overload and discharge Materials Housing: aluminium profile, luminaire surfaces: plexiglass Surface finish White Accessories LED charging indicator, test pushbutton – for emergency circuit function control
Type
UX-Emergency 2761 UX-Emergency 2762
PRODUCTS
power consumption (W)
nr. of LED‘s
9 (EXIT 8) LEDs 11 LEDs
power consumption (W)
battery
duration
light output
(Ni-Cd)
(h)
(lm)
5 6
3.6 V/1 Ah 3.6 V/1 Ah
3 3
80/80 100/80
146/147
FORSTREET SIRIUS LED 7050lm 90
90
75
75
60
60
45
45
STREET LIGHTING
INDUSTRIAL LIGHTING
FORSTREET SIRIUS
eco bay
Light source Optical system Wiring Materials Surface finish
cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
LED PMMA lenses Tilting angle adjustment: 20° to 60° Electronic control gear, bi-level light output (100%/50%) Housing: extruded aluminium Luminaire cover: injection moulded plastic Lenses cover: clear PMMA Housing: black, bottom frame: grey
Light source Linear fluorescent lamp FDH (T5) Optical system Reflector Electronic control gear Wiring On request: dimmable electronic control gear (1-10V/switch DIM/DSI/DALI) Material Housing: sheet steel, reflector: anodized aluminium -MIRO4 Surface finish Housing: white (RAL 9003), other colors on request
F. SIRIUS M F. SIRIUS L F. SIRIUS XL
power consumption
(pcs)
net lumen output (at Ta = 25 °C) (lm)
(W)
color rendering index CRI (Ra)
2x8 4x8 6x8
2350 4650 7050
(V/Hz)
(lm/W)
2x17 4x17 6x17
>70 >70 >70
100-240/50-60 100-240/50-60 100-240/50-60
69 68 69
FORSTREET asterope
FORSTREET ASTEROPE 10700lm 5000K 90
90
75
75
Light source Optical system Wiring Materials Surface finish
60
60 400 500 600
45 cd/klm
30
15 0 C0.0-C180.0
45 15
input
30 C90.0-C270.0
system efficacy
dimming
F. ASTEROPE F. ASTEROPE F. ASTEROPE F. ASTEROPE
net lumen power output consumption (at Ta = 25 °C) (lm) (W)
road class
(%)
recomended mounting height (m)
100/50 100/50 100/50
6-10 6-10 8-12
S3 ME5 ME4b
optical system REFLECTOR NARROW ULTRA NARROW • • • • • •
7 100 8 300 9 500 10 700
color rendering index CRI (Ra)
input
system efficacy
dimming
(V/Hz)
(lm/W)
(%)
5000 5000 5000 5000
70 70 70 70
220-240/50-60 220-240/50-60 220-240/50-60 220-240/50-60
89 89 89 89
-
79 92 106 120
7-12 7-12 7-12 7-12
FORSTREET syrma
90
90
75
75 200
60
60
300 400
45
Light source Optical system Wiring Material Surface finish
45
500 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
HST 1x70W HST 1x150W HST 1x150W
tornado pc led
F. SYRMA LED
nr. of LED´s
power consumption
(pcs)
net lumen output (at Ta = 25 °C) (lm)
(W)
4x8
4650
4x17
color temp.
ME5 ME5 ME4 ME4
UX-MYAR HPS 100W HPS 100W HPS 150W HPS 150W
input
system efficacy
dim.
recomended mounting height
(K)
CRI (Ra)
(V/Hz)
(lm/W)
(%)
(m)
4300/5300
>70
100-240/50-60
68
100/50
4-6
Light source Optical system Wiring Materials Surface finish
Light source Optical system Wiring Material Surface finish
ux-myar
road class
S2-S6
lampholder
4x28 4x54 4x35 4x49 4x80 4x120
FDH FDH FDH FDH FDH FDH
G5 G5 G5 G5 G5 G5
LED Diffuser Electronic control gear On request: dimmable electronic control gear DALI (10-100%)/1-10V Through-wiring Housing: injected polycarbonate (grey) Diffuser: injected polycarbonate (clear) Clips: polycarbonate or stainless steel (inox) Installation plate: sheet steel Housing: grey
ECO BAY ULTRA NARROW FDH 4x80W 90
90 75
75 300
60
60
450 600
45
45
750
net lumen output (at Ta = 25 °C) (lm)
power consumption
5100
15 0 C0.0-C180.0
15
30 C90.0-C270.0
TORNADO PC LED 5100lm 4000K 120
90
75
75 60
cd/klm
45
thermal management
(W)
correlated color temperature CCT (K)
51
80
4000
•
105
90
60
color rendering index CRI (Ra)
120
200 160 120 80
105
30 15 0 C0.0-C180.0
15
30 45 C90.0-C270.0
PASSIVE
replacement of standard
LED Diffuser Dimming electronic control gear (1-10V) Housing: die cast aluminium, diffuser: microprismatic PMMA Black / silver
UX-MYAR LED 11050lm 5000K 90
90 75
75 200
60
net lumen output (at Ta = 25 °C) (lm)
power consumption
correlated color temperature CCT (K)
thermal management
(W)
color rendering index CRI (Ra)
11050
106
80
5000
•
45
60
cd/klm
30
power
lamp
• • • • • •
• • • • • •
30 C90.0-C270.0
90 75
75 100
60
60
200
45
45
250 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
UX-PETRO S AS MT 1 x 250W
lampholder 90
(W) 150 250 400 150 250 400
15
90
90
75
UX-PETRO S UX-PETRO S UX-PETRO S UX-PETRO S UX-PETRO S UX-PETRO S
15 0 C0.0-C180.0
UX-PETRO S SM MT 1 x 250W
HST 1x70W optical system REFLECTOR SYMMETRIC ASYMMETRIC
45
400
PASSIVE
Light source Tubular metalhalide lamp MT (HIT) / Tubular high pressure sodium lamp ST (HST) Optical system Reflector (SYMMETRIC/ASYMMETRIC) Wiring Conventional control gear with an ignitor standardly compensated / Electronic control gear, ceramic lampholder, ceramic 3-pole terminal for conductors up to 2,5mm2 Material Housing: sheet steel, luminaire cover: clear hardened glass, sandblasted part above electrical equipment, reflector: aluminium, installation plate: zinc-coated sheet steel Surface finish White (RAL 9003)
Type
PRODUCTS
30 C90.0-C270.0
300
LED Lenses Electronic control gear, bi-level light output (100%/50%) Housing: die cast aluminium Lenses cover: clear PMMA Supporting arms: extruded anodized aluminium profile Housing: black Bottom frame: grey
color rendering index
lamp
(W)
15
replacement of standard
ux-PETRO S Type
45
400 15 0 C0.0-C180.0
30
Type FORSTREET syrma 4650lm 5300K
60
300
cd/klm
Type
recomended road class mounting height (m)
• • • • • •
power
replacement of standard
LED Lenses and reflector Dimmable electronic control gear 1-10V Housing: die cast aluminium Cover: polycarbonate Reflectors: MIRO4 aluminium Housing: black Bottom frame: grey
correlated color temperature (K)
75 200
60
30
TORNADO PC LED
Type
90
75
cd/klm
ECO BAY ECO BAY ECO BAY ECO BAY ECO BAY ECO BAY nr. of LED´s
90
45
Type
Type
ECO BAY NARROW FDH 4x80W
MT MT MT ST ST ST
E27 E40 E40 E40 E40 E40
148/149
75
100 150
60
60
200 250 300
45 cd/klm
30
15 0 C0.0-C180.0
45 15
30 C90.0-C270.0
UX-PETRO R SM MT 1 x 250W 90
INDUSTRIAL LIGHTING
ARCHITAINMENT
ux-PETRO R
ARCSOURCE TWINWALL
90 75
75 100
60
60
200
45
45
250 cd/klm
30
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type 90
75
cd/klm
30
15 0 C0.0-C180.0
UX-PETRO R UX-PETRO R UX-PETRO R UX-PETRO R UX-PETRO R UX-PETRO R
60
200 250 300
45
45 15
30 C90.0-C270.0
ux-stadio mars
UX-stadio mars 1000 c1 MN 1x1000W 90
90
75
75 2000
60
60
4500
45
optical system REFLECTOR SYMMETRIC ASYMMETRIC
power
lamp
lampholder
MT MT MT ST ST ST
E27 E40 E40 E40 E40 E40
(W)
75
100 150
60
45
6000
• • • • • •
• • • • • •
150 250 400 150 250 400
ARCLINE OPTIC LED RGB
Light source Double ended metalhalide lamp MN (HID) / Tubular metalhalide lamp MT (HIT) / Tubular high pressure sodium lamp ST (HST) Optical system Reflector Wiring Control gear Materials Housing: Die cast aluminium. Reflector: Anodized aluminium - Polished / peened. Shade: Anodized aluminium Surface finish Silver
15 0 C0.0-C180.0
15
30 C90.0-C270.0
Type
version asymmetric with ANTIGLARE LOUVRE
optical system REFLECTOR
UX-STADIO MARS 1000 SM SM/polished/narrow UX-STADIO MARS 1000 SM SM/peened/wide UX-STADIO MARS 1000 SM SM/peened/wide UX-STADIO MARS 1000 SM SM/polished/narrow UX-STADIO MARS 1000 AS AS/polished/narrow+defl. UX-STADIO MARS 1000 AS AS/polished/wide UX-STADIO MARS 1000 AS AS/polished/narrow
power (W)
lamp
1x1000 1x1000 1x1000 1x1000 1x1000 1x1000 1x1000
MN MN MT/ST MT/ST MN MN MT/ST
lamp holder cable cable E40 E40 cable cable E40
ARCHITAINMENT ARCPAD EXTREME
ArcPAd Xtreme
ARCSOURCE INGROUND
ARCSOURCE WALL 3
Lenses
max. 4.2
ARCSOURCE TWINWALL 3
Lenses
max. 8.4
ARCsource 96 integral
optical system (lm)
power
beam angle
(W)
color temperature CCT (K)
thermal management PASSIVE
Lenses
max. 580
rgBW
10°/23°/44°/14°x 26°
•
(W)
color temperature CCT (K)
beam angle
thermal management PASSIVE
rGBW/CW/WW R,G,B,A rGB/RGBW/cW
6°/15°/25°/ 38° asymmetric 6°/15°/25°/ 38° asymmetric
• •
Light source High power LED´s Optical system Lenses Power supply required: aRCPOWER 36, 72, 144, 360, rackMount384 Wiring Cable type: Cat 5e 1,5m with RJ45 male connector Material Precision extruded aluminium, transparent cover made of clear glass Operating ambient temperature range -20°C/+40°C Operating temperature +50°C @ ambient: +25°C optical system (lm)
power
beam angle
(W)
color temperature CCT (K)
thermal management PASSIVE
arcline optic 12 lenses
Lenses
max. 13.6
rGB/RGBW/cW
•
Lenses
max. 20.4
rGB/RGBW/cW
Lenses
max. 27.2
rGB/RGBW/cW
Lenses
max. 40.8
rGB/RGBW/cW
6°/15°/25°/38° asymmetric 6°/15°/25°/38° asymmetric 6°/15°/25°/38° asymmetric 6°/15°/25°/38° asymmetric
arcline optic 18 lenses arcline optic 24 lenses arcline optic 34 lenses
beam angle
thermal management PASSIVE
13°/25°/44° 12° x 32°
•
• • •
Light source High power LED´s Optical system Lenses Wiring USITT DMX 512, RGBW – depends on request Passive cooling for optimum thermal management Housing: die cast aluminium Material Operating ambient temperature range -20°C/+40°C Operating temperature +85°C @ ambient: +40°C
arcsource 96 integral
optical system (lm)
power (W)
color temperature CCT (K)
Lenses
max. 200
RGBW
Light source High power LED´s Optical system Lenses Wiring LED color variants: RGB, rGBW, White, cable type: Belden 7930A or similar (RJ45) Material Housing: stainless steel (316), tempered glass, plastic, aluminium Operating ambient temperature range -20°C/ +30°C Operating temperature +60°C @ ambient: +25°C
Type
Arcsource inground 12 Arcsource inground 36
PRODUCTS
power
Type
Light source 188 High Power LED´s Optical system Lenses Wiring Two independent LED modules, USITT DMX 512, RGBW – depends on request Passive cooling for optimum thermal management, power on board or external Material Housing: die cast aluminium Operating ambient temperature range -20°C/+40°C Operating temperature +85°C @ ambient: +40°C Type
optical system (lm)
Type
cd/klm
30
Light source High power LED´s Optical system Lenses Wiring Flammability: 94V-0 flame class rating, LED color variants: RGBW, cW, WW, r, G, b, A (depends on request), cable type: Belden 7930A or similar Housing: stainless steel Material Operating ambient temperature range -20°C/ +30°C Operating temperature +60°C @ ambient: +25°C Type
UX-PETRO R AS MT 1 x 250W 90
Light source Tubular metalhalide lamp MT (HIT) / Tubular high pressure sodium lamp ST (HST) Optical system Reflector (SYMMETRIC/ASYMMETRIC) Wiring Conventional control gear with an ignitor standardly compensated / Electronic control gear, ceramic lampholder, ceramic 3-pole terminal for conductors up to 2,5mm2 Material Housing: sheet steel, luminaire cover: clear hardened glass, sandblasted part above electrical equipment, reflector: aluminium, installation plate: zinc-coated sheet steel Surface finish White (RAL 9003)
optical system (lm)
power
beam angle
(W)
color temperature CCT (K)
thermal management PASSIVE
Lenses Lenses
max. 13.6 max. 40.8
rGB/RGBW/cW rGB/RGBW/cW
6°/15°/25°/ 38° 6°/15°/25°/ 38°
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150/151