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ENGINEERING
Excerpt from the book "The Ecological Engineer: Glumac": Kelley Engineering Center
Design of a Specialized
Airborne-Infection Isolation Suite
Lessons learned from the design of new National Institutes of Health facility By fARHAD MEMARZADEH, PhD, PE,
and DEBORAH E. WILSON, DrPH, CBSP,
National Institutes of Health,
Bethesda, Md.,
and KRISHNAN RAMESH, PE,
Affiliated Engineers Inc.,
Rockville, Md.
ria used for the SCSU, which can be applied for any other type of alrborne-infection-isolation suite (AIlS). General Design Features The SCSU receives air via the main clinical supply-air system, wruch is served by air-handling units located in another part of the building. Trus is a manifolded system providing supply air to all patient rooms and support spaces (Figure 1). All clinical spaces are served by a non-recirculating (100-percent exhaust) HVAC system. All general clinical spaces, as welJ as the adjacent Vaccine Evaluation Clinic (VEC), are served by general exhaust systems consisting of multiple exhaust fans connected to a common exhaust air manifold. Dedicated isolation-room exhaust systems consist of multiple exhaust fans connected to a common exhaust-air manifold. If one fan fails, the remaining fans
A b iocbntainment patient-care unit (BPCU) is a facil ity designed and operated to maximize patient care with app opriate infection-control practices and procedures. A PCU is secure, is physically separated from other patient-care areas, and has special air-handling systems. 1 The National Institutes of Health's Speclll Clinical Studies Un" (SCSU) Vaccine Evaluallon Clinic new Special Clinical Studies Unit (SCSU) (Illcludes occupallonal~xposure Isolation room, patient room, and nursing support) in Bethesda, Md., is a rughJy specialized BPCU, housing patients with extremely infectious diseases transmissible by respiratory aerosolization, direct con tact with primary body fluids, or dried infectious particles from body fluids. The SCSU has three patient rooms plus an occupational-exposure isola tion room (OETR).1t is equipped to meet all clinical-care needs, including basic medical observation, minor surgical procedures, and intensive care. Thus, planning had to address housekeeping, • Welded stainless-s18e1 ductwork security, emergency evacuation, and the use of experimental therapeutics. T1Us article will discuss design crite- FIGURE 1. a...t .....ment of mechanical systems.
Director of the National Institutes of Health's (NIH's) Division of Technical Resources, Farhad Memarzadeh, PhD, PE, consults on matters related to biocontainment and medical research laboratories around the world. He has written four books and more than 60 scientific research and technical papers pubJ.ished in peer-reviewed journals and been a guest and keynote speaker for more than 50 international scientific and engineering conferences and symposia. Deborah E. Wilson, DrPH, CBSP, is director of the NIH's Division of Occupational Health and Safety and founder and director of the National Biosafety and Biocontain ment Training Program. She is a career U.S. Public Health Service Commissioned Officer. Krishnan Ramesh, PE, is a managing prindpal of Affiliated Engineers Inc. He has extensive experience planning, engineering, and designing biological and chemical research laboratories and vivaria nationwide and is a technical contributor to the NIH Design Requirements Manual for Biomedical Laboratories and Animal Research Facilities. 24
I8ta\C &NGINDRING
FEBRUARY 2011
compensate to provide the required design exhaust-air quantity. The VEe is exhausted through the general clinical exhaust system, while the sesu is exhausted through a dedicated system. Exhaust air from all sesu spaces, including the OEIR, is manifolded in the dedicated exhaust system. The dedicated system is equipped with high-efficiency-particulate-air (HEPA) filters prior to exhaust fans and discharges outside (Figure 2). At both entrances to the sesu are vestibules maintained at negative pressure relative to the adjoining corridors. The OEIR has an ante room maintained at negative pres sure relative to the rest of the sesu to mitigate the risk of release of an airborne agent. The negative pres sure of the patient rooms, the OEIR, and the sesu is monitored and alarmed at the nurses' station.
Vaccine Evaluation Clinic
Special Clinical Studies Un" (SCSU)
• Welded stainless-steel ductwork
Hlgll-efficiency-particulate·alr filtration unij
AGURE 2. Dual-use-Isolation-roocn Interoollillechlnlcil syste....
SCSU Design Features Design features specific to the sesu include: .. Walls (outside of the OEIH) sealed to minimize uncontrolled
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Circle 168 FEBRUARY 2011
NPAC ENGINEERING
25
DESIGN OF A SPECIALIZED AIRBORNE-INFECTION-ISOLATION SUITE
Galvanlzed·steel ductwork Welded stainless-steel ductwork •
Best fuel efficiency of any firetube
AGURE 3. Dual-use Isolation room.
Completely integrated • Self-closing exit doors. • Balanced ventilation air to main tain negative pressure (inflow of air) relative to the corridor (between public corridor and the SCSU). • Exhaust-air grilles located low on patient-room walJs. • Pressure-monitoring system continuously indicating airflow from adjacent spaces into the SCSU. • Displays of relative space pres surization at the corridor and vesti buJes. • Remote alarms at the nurses' station. • Twelve-air-changes-per-hour (ACH) minimum ventilation rate of non-recirculating air (100-percent outdoor air) for the SCSU and OEIR. • Dedicated toilet, bath, and hand washing facilities in each patient room. • Dedicated exha ust-air system serving the SCSU and OEm. The dedicated constant-volume exhaust system consists of three vari able-speed exhaust fans. Each fan is designed at 50 percent of capacity to provide the required level of redun dancy and reliability and 20-percent reserve-airflow capacity to account for final air-balance adjustments and future needs. The fans operate con tinuously, their speed controlled with variable-frequency drives based on a
static-pressure sensor in the exhaust ductwork. Discharge from the fans is manifolded to ensure a high stack discharge velocity. One of the exhaust fans receives life-safety branch power; the other two receive general standby-equip ment branch power. In the event of normal power loss, life-safety power is restored within 10 sec, and the first fan is re-engaged and ramps up to satisfy required minimum exhaust and directional airflows. Shortly thereafter, power to the other fans is restored, and the fans arere-engaged . Air distribution to individual spaces! rooms is by constant- and/or vari able-volume, pressure-independent supply and exhaust air terminals to each temperature- and/or pressure control zone. Pairs of supply and ex haust venturi-style air-term.inal units track airflow to ensure the specified pressurization (directional airflow) is maintained. The onJy prerequisite for the air terminals to operate properly is sufficient duct static pressure. Th.is is monitored via differential-pressure switches across each air valve. Addi tionally, automatic bubble-tight iso lation dampers are provided in the supply duct to each zone. AU exhaust air-terminal units are low-leakage (less than 3 cfm at 1 in. water), with high-speed actuators
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Minimum excess air across the operating range
Can meet 5 ppm NOx emissions requirements Can meet 1 ppm CO emissions requirements
Cleaver Brooks·
Circle 170 FEBRUARY 2011
HPAC ENGINDRING
27
DESIGN OF A SPECIALIZED AIRBORNE-INFECTION-ISOLATION SUITE
(Iess-than-1-sec fulJ response time) to stay within 5 percent of airflow set point. The air-terminal units' controllers are linked between supply and exhaust. If duct static pressure falls below levels required for accurate tracking, the supply-air bubble-tight dampers close, and the exhaust-air valves are commanded to a minimum position, maintaining directional airflow. The control devices operate autonomously, even in the event communications with the overall building control system are dis rupted. All of the contro.llers and bubble-tight dampers are provided uninterruptible power to ensure the air-terminal units track each other to maintain the specified airflow differential. All serviceable compo nents, such as air terminals, exhaust valves, and reheat coils, are located in the interstitial space outside of the patient-care/containment area. AU exhaust ductwork for the SCSU and negative-pressure examination room on the room side of the HEPA filter is made of welded stainless steel (Figure 3). The supply ductwork is made of galvanized steel augmented with welded stainless steel. Bubble tight dampers are provided on all supply ducts branching from the interstitial level to SCSU patient rooms and the OEIR. These are fast-acting pneumatic actuators that close upon a loss of exhaust airflow. Ductwork from the bubble tight dampers to air devices is made of welded stainless steel. Backflow preventers are installed in domestic-water piping running to the SCSU. When the SCSU is in isola tion mode, oxygen, medical vacuum, and medical air are provided via local dedicated units . HEPA filtration is provided on the main plumbing vents leaving the SCSU. Emergency power is provided for critical branch, life-safety, and standby equipment in the SCSU and for exhaust fans on the interstitial level as appropriate. Electrical services for the OEIR 28
HPAC ENGINEERING
FEBRUARY 2011
are sealed airtight to mInimize outside penetrations. A third in ner layer of sheetrock prevents air migration that can occur as the result of required utility boxes and
associated penetrations_
Room Control Sequences Under normal conditions, sup ply- and exhaust-air valves oper
•
Air·handllng units, N+ 1 redundancy
Two exhaust fans on emergency power ---"--1-;:;:"'[ One exhaust fan on life-safety power ----1-.:;;;1'1 Main-building clinical exhaust
+------".
Exhaust air to main building
Exhaust air to SCSU exhaust fans Supply air from main building
SUppiy air from G:D-----'~---... main building
Vaccine Evaluatloll Clinic
Special Clinical Studies Unit (SCSU) Occupational-exposure Isolation room
RGURE 4. ManHolded supply-air syste", and dedicated exhaust-air system for the SCSU.
Air-handling units. N+1 redundancy
I I~
•
Two exhaust fans on emergency --""---l~'"
power
One exhaust fan on life-safety power - - - - 1 ' 771 Main-building clinical exhaust + - - - - , Exhaust air to SCSU exhaust fans Supply air from main buUding
Exhaust air to main building
Supply air from main building
...
_~_
GIi.-,---.. . ·• •
Vaccine EvalllUon Clinic
Exhaust air to SCSU exhaust fans
.--0( +- _
Supply air from main building
Occupatlonal-exposure Isolation room (OEIR)
OEIR airteroom
Special Clinical Stadles Unit (SCSU) RGURE 5. ManHolded supply-air system and dedicated exhaust-air system for the SCSU.
DESIGN OF A SPECIALIZED AIRBORNE-INFECTION-ISOLATION SUITE
ate at "constant" airflow set points. The fixed differential between sup ply- and exhaust-airflow set points provides directional airflow and room pressurization_ For example, an exhaust-airflow set point of 700 cfm and supply-airflow set point of 600 cfm provides tOO-cfm inward airflow, maintaining a room at negative pressure. As long as the "measured" differential pressure across the supply- and exhaust-air valves is within an acceptable range (0.6 in. wg to 3.0 in. wg), air valves maintain their respective constant airflow set points, maintaining direc tional airflow and room pressuriza tion. Differential-pressure switches across each supply- and exhaust-air valve continuously monitor airflow. If the differential pressure across either the supply- or exhaust-air valve in any room drops below 0.3 in. wg, the bubble-tight damper on
~I~
Airflow-tracking
control
1-----------, I I
· h--de H1\1.."... ncyparticulate-air filtration unit
I I
I I I
l___ ~
Venturi supply-air valve
to sesu
exhaust fans
Bubble-tight
damper
Supply air
Exhaust air ~
Transfer air from anteroom, 100 elm
Galvanized-steel _ ductwork Welded stainless- ~ steel ductwork
PaUent room
RGURE 6. Patient·room airflow.
the supply duct to that room closes immediately. The supply-airflow and exhaust-airflow set points are reset to emergency-mode minimum values.
When the main supply-duct static pressure and main exhaust-duct static pressure J"ise above 0.85 in. wg, the bubble-tight damper opens, sup-
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FEBRUARY 2011
HPAC ING..EERlNG
29
DESIGN OF A SPECIALIZED AIRBORNE-INFECTION-ISOLATION SUITE
ply- and exhaust-airflow set points are reset to their normal values, and the room reverts to normal opera tion. The room control sequences are illustrated in figures 4-6.
Particle Dynamics Clinically applicable distinctions are made between short-range airborne-infection routes (between individuals less than 3.28 ft apart) and long-range routes (within a room, between rooms, or between individuals greater than 3.28 ft apart). Small droplets may partici pate in short-range transmission, but are more likely than large drop lets to evaporate to become drop let nuclei. True long-range aerosol transmission becomes possible when droplets of infectious material are small enough to remain airborne almost indefinitely and be transmit ted over long distances. There is
Breathing zone around bed
RGURE 7. SCSU ventilation system.
essential agreement that particles with an aerodynamic diameter of 5 lJlTI or less are aerosols, while par ticles with an aerodynamic diameter of 20 llm are large droplets.
Methodology For the SCSU, computational fluid dynamics and particle tracking were
used to study the influence ofventiJa tion flow rate (12 ACH and 16 ACH), exhaust location (high exhaust, low exhaust, and the combination of high and low exhausts), and patient posi tion (sitting and lying) on the removal of aerosol generated by a cough. The model suite consisted of three rooms-main isolation room w ith
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DESIGN OF A SPECIALIZED AIRBORNE-INFECTION-ISOLATION SUITE
Rllllll: 3 . .. Balilrolfl
Room
V.ntllII
Alalll: I lila IIItInom Room
lInatNng
1
Sitting
12
Low
22"10
24"10
54"10
Brutlll•• 9%
42"10
6"10
Lying
12
Low
21"10
20/.
77%
7%
35% 29%
23%
2
4"10
67%
7%
3
Sitting
16
Low
27%
7%
66%
6"10
40%
7%
53%
5%
4
Lying
16
Low
26%
4%
71%
8"10
35%
6%
60%
7%
5
Sitting
12
I.Ai
15%
19%
66"10
12%
26%
200/.
55%
10%
6
Lying
12
I.Ai
13%
1%
85%
11 "10
24%
3"10
73%
11 %
7
Sitting
16
I.Ai
16%
18"10
66"10
13"10
30"10
200/.
50%
8%
8
Lying
16
I.Ai
15"10
1%
84%
8%
25%
4%
71%
14%
9
Sitting
12
High
13%
19"10
68%
14%
24%
21 %
55%
10%
10
Lying
12
Hi~
45%
3%
52%
6%
52%
5%
43%
7%
11
Sitting
16
High
24%
14%
62%
13"10
37%
17%
46%
8%
12
Lying
16
High
21%
1%
78%
9%
34%
64%
10%
20/.
TABLE 1. Case description and status of 3,000 particles 3 min and 5 min after a cough.
patient bed, bathroom, and ante room-connected via door gaps. A patient's cough was assumed to release 3,000 droplet nuclei with diameters of 3 llm. 2, 3 Further, the particles were assumed to be 93°F when released from the mouth.4
Results Three thousand particles were tracked individually for 5 min, with the number of particles removed from the room recorded every min ute. The location of each particle remaining in the room was recorded . Particular attention was pajd to the number of particles remaining in the breathing zone of the main room and the breathing zone around the bed where health-care workers were
most likely to be. The breatillng zone of the main room was defined as the space 3.6 ft to 5.75 ft from the floor; the breathing zone around the bed was defined as the space 9 in. from the edges of, and 3.6 ft to 5.75 ft above, the bed (Figure 7). Table 1 shows the percentage of particles removed from the suite 3 min and 5 min after a cough and the percentages of particles remaining in the bathroom, the main room, and the breathlng zone of the main room. During the first 3 min, the system removed 13 percent to 45 percent of the 3,000 particles. Withln 5 min, the percentage of particles removed increased to 25 to 55 percent, whlch is consistent with estimates 5 that, assuming a well-mixing condition,
_ 3mln 5 min 1,600 , . . . . - - - - . . . . , - - - - - - . , . - - - - - - ,
en
,....----...,..-----..,...."""'!"'.. ,. - --
1,600
1.400
I-------+-------+-------f
1,400 1 - - - - - - + - - - - - - +
1,200
1-- - ---.---.-+------+-------1
1,200
1,000
en
.90!
.~ ~
99 percent of particles will be removed after 9 min at 16 ACH. Note the percentage of particles in the bathroom is much higher when a sitting patient coughs than when a lying patient coughs. The reason is the rustribution of particles in the air current and the location of the bathroom. Figure 8 shows the number of particles removed 3 min and 5 min after the cough of a sitting patient and a lying patient. The combina tion of low and high exhausts was least effective in removing particles. Generally, with the exception of Case 10, the most particles were removed with low exhaust and high flow, With a lying pat ient, 12 ACH (Case 10) removed more particles than 16 ACH
1------+------+
1,000 1 - - - - --1
.90!
~
800
~
600
800 600
400
400
200
200
o
o Case 1 Case 3 Low exhaust
Case 5 Case 7 Low and high exhaust
Case 9 Case 11 High exhaust
Sitting patient
Case 2 Case 4 Low exhaust
Case 6 Case 8 Case 10 Case 12 Low and high exhaust High exhaust
Lying patient
RGURE 8. Number of parUcles removed 3 min and 5 min after a cough. FEBRUARY 2011
HPAC ENGINEERING
31
DESIGN OF A SPECIALIZED AIRBORN E-INFECTlON-ISOLATION SUITE
(Case 12) with high exhaust. This can be explained by the flow pattern above the patient determined by the downward forced convection from the ceiling diffusers above the bed and the upward flow of the cough from the mouth of the lying patient. With greater downward flow (16 ACH, rather than 12 ACH) from the ceiling diffuser, the upward move ment of droplets carried by the cough of a lying patient couJd be suppressed and, thus, have difficulty reaching high exhausts. For a sitting patient, particles in the breathing zone generaUy were reduced from minutes 3 to 5 (Figure 9). For a lying patient, they sometimes
increased, depending on the ventila tion system and flow rate. Figure 10 shows the combination of low and high exhausts resulted in a higher number of particles in the breathing zone around the bed, especially in the cases (6 and 8) of a lying patient. High exhausts with a high flow rate (Case 12) did not remove particles around the bed effectively. Figure 10 indicates fewer particles around the bed with low exhausts. The nwnber of particles below the breathing zone was higher with low exhausts than with high exhausts (Figure 11). High exhausts with high flow rates (Case 12) did not seem to remove particles around the bed
450
450
400
400
350
..
Conclusions Conclusions that can be drawn from the study include: • Low exhaust outperforms other exhaust locations in terms of particle removal and number of particles remaining around a bed. • Increasing ventilation flow from 12 to 16 ACH generally helps to remove particles from an isolation
350
..
300
300
.JI
250
.JI
250
~
200
~
200
~
effectively. The number of particles above the breathing zone was higher with a lying patient regardless of flow rate and exhaust location (Fig ure 12). This was attributed primarily to the initial upward momentum of the cough jet.
~
150
150
100
100
50
50
0
0 Case 1 Case 3 Low exhaust
Case 5 Case 7 Low and high exhaust
Case 9 Case 11 High exhaust
Case 2 Case 4 Low exhaust
Sitting patient
Case 6 Case 8 Case 10 Case 12 Low and high exhaust High exhaust Lying patient
FIGURE 9. Number of particles remaining In breathing zone.
_
'"
3mln
5min
160
160
140
140
120
120
100
100
'"
.tI
.JI
~ ~
~
80
~
60
60
40
40
20
20
0
0 Case 1 Case 3 Low exhaust
Case 5
Case 7
Low and hiOh exhaust
Case 9
Case 11 HIgh exhaust
Sitting patient
FIGURE 10. Number of particles remaining In breathing zone around bed. 32
80
HPAC ENGINEERING
FEBRUARY 2011
Case 2 Case 4
Low exhaust
Case 6 Case 8 Case 10 Case 12 Low and high exhaust HiOh exhaust Lying patient
DESIGN OF A SPECIALIZED AIRBORNE·INFECTION·ISOLATION SUITE
1,000
900
800
800 700 .; ~ ~
700 600 •W 500 t ~ 400
....
600 500 400 300 200 100
o
Case 1 Case 3 Low exhaust
Case 5 Gase 7 Low and high exhaust
Case 9 case 11 High exhaust
300 200 100 0 Case 2 Gase4 Low exhaust
Sitting patient
case 6 Case 8 Case 10 Case 12 Low and high exhaust High exhaust Lying pallent
RGURE U. Number of particles below breaUllng zone•
• 3 min 5 min 2,000 - - - - - . . . . . . , . . . - - - - - - - - - - . . . . . , 1,800 1 - - - - - - - - - l - - - - - - + - - - - - - - 1 1,600 1 - - - - - - - + - - - - - - + - - - - - - - 1
1,400 1 - - - - - - + - - - - - - + - - - - - - - 1 ,; 1,2001-------+--------+--------1 ~ 1,000 1 - - - ~ 8OOJ-- 6001---
Gase 1 Gase 3 Low exhaust
Case 5 Case 7 Low and high exhaust
Case 9 Gase 11 High exhaust
Case 2 Gase 4 Low exhaust
Sitting patient
Case 6 Case 8 Case 10 case 12 Low and high exhaust High exhaust Lying patient
RGURE 12. Number of particles above breathing zone.
room (except in cases of high exhaust and a lying patient coughing), but not necessarily a breathing zone. • The number of particles in a bathroom resulting from a cough in a main room is dependent on air-current particle distribution and bathroom location. Standard operating procedures are extremely important and shouJd be developed as part of the planning process, with consideration given to facility purpose and features .
References 1) Smith, P.W., et al. (2006) . De signing a biocontainment unit to care for patients with serious com
municable diseases : A consensus statement. Biosecurity and Bioterror ism: Biodefense Strategy, Practice, and Science, 4, 351-365. Retrieved
from http://www.eunid.eu/public/ bioconteniment%20unit.pdf 2) Fennelly, K.P " Martyny, J.W., FuJton, K.E., Orme, I.M., Cave, D.M., & Heifets, L.B. (2004). Cough-gen erated aerosols of Mycobacterium tubercuJosis: A new method to study infectiousness . American Journal of Respiratory and Critical Care Medicine, 169, 604-609. 3) Fitzgerald, D., & Haas, D.W. Mycobacterium tuberculosis. In: Mandell, Douglas, and Bennett's principles and practice of infectious
diseases (6th ed .). (2005). Philadel phia: Churchill Livingstone. 4) Hoppe, P. (1981) . Temperature of expired air under varying climatic conditions. International Journal of Biometeorology,25,127-132. 5) Centers for Disease Control and Prevention. (2005, December 30) . Guidelines for preventing the trans mission of mycobacterium tubercu losis in health-care settings, 2005 .
Morbidity and Mortality Weekly Report, 54, 20. Did you find this article useful? Send comments and suggestions to Executive Editor Scott Arnold at scott.arnold@
penton. com. FEBRUARY 2011
HPAC ENGINEERING
33
