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Dates and Locations at www.clarion.org

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HE COURSES DESCRIBED in this brochure continue to represent some of the best-available industry-based technical training courses for those working in the oil and gas pipeline industry, both onshore and offshore. Ranging in length from one to five days, all are designed to be both informative and intensive; some are well known and have been presented to thousands of participants world-wide (the pipeline defect assessment course and the subsea pipeline engineering course are examples of these), while some are still relatively new to our program. All, however, are presented by recognized industry experts, and all undergo continuous development and improvement, based both on industry advances and participants’ feedback. While each course can be considered as ‘stand-alone’, they all have been planned to fit into the schematic shown opposite, with the intention of providing engineers and technical specialists in this industry with a defined route for training and continuous professional development. By following one or other of the various routes shown, an individual can be sure to receive an intensive and complete overview of the different subjects involved, starting at the basic level and progressing to an advanced understanding. Clarion Technical Conferences® and Tiratsoo TechnicallTM are committed continuously to update, revise, and augment this course programme, and for the latest information on what is planned, readers are referred to www.clarion.org and www.pipeconferences.com. BJ Lowe, Director, Clarion Technical Conferences John Tiratsoo, Director, Tiratsoo Technical

Contents Please see the website for dates and locations: www.clarion.org

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NEW! Inspection of Challenging Pipelines...........................................................................4 NEW! Managing Cracks and Seam Weld Anomalies on Pipelines......................................5 NEW! Hydrostatic Testing of Pipelines..................................................................................6 NEW! Safety and Engineering Assessment of Onshore Pipeline Gathering Systems.......8 Inspection of offshore pipelines and tubular structures....................................................10 Geohazard Management for Pipeline Engineers................................................................ 11 Onshore Pipeline Engineering ......................................................................................12-13 Pipeline Pigging and ILI.......................................................................................................14 Practical Pigging Operations................................................................................................15 Defect Assessment in Pipelines......................................................................................16-17 Pipeline Defect Assessment Workshop................................................................................18 The Pipeline Defects Clinic..................................................................................................19 Introduction to Excavation Inspection and Applied NDE for Pipeline Integrity Assessment....................................................20 Advanced Pipeline Risk Management.................................................................................21 In-Line Inspection of Pipelines - Introduction...................................................................22 In-Line Inspection of Pipelines - Advanced........................................................................23 Stress-Corrosion Cracking in Pipelines...............................................................................24 Microbiological Corrosion in Pipelines: Prevention, Detection, Mitigation...................25 Pipeline Repair Methods, Hot Tapping, & In-Service Welding..........................................26 Performing Pipeline Rehabilitation....................................................................................27 Pipeline Integrity Management...........................................................................................28 DOT Pipeline Safety Regulations.........................................................................................29 Subsea Pipeline Engineering.......................................................................................... 30-31 Subsea Production Systems Engineering............................................................................32 Deepwater Riser Engineering..........................................................................................33-34 Engineering for Arctic Environments ................................................................................35 NEW! API Recommended Practice 1173: Pipeline Safety Management System Requirements ....................................................36 The Pipeline Integrity Master Class ...................................................................................37 Administrative details Course curriculum...................................................................................................................3 Course schedules..................................................................................................................4-5 Course Fees.............................................................................................................................37 Contact details.......................................................................................................................37 Index of courses by topic......................................................................................................38 Index of courses by title........................................................................................................39

NEW! Inspection of Challenging Pipelines

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he course will provide an in-depth introduction into the inspection of challenging pipelines, i.e. pipelines that cannot be inspected in a straightforward manner using traditional free- swimming in-line inspection tools. The course will introduce typical flaws and anomalies found in challenging assets, including a wide range of metalloss and crack features. Assets covered in the course include difficult-to-inspect onshore and offshore pipelines in the up-, mid- and downstream sector, including gathering and distribution lines, loading lines, storage lines, risers, flexible pipe and risers, laterals. The course includes an introduction of all relevant inspection technologies and related non-destructive testing principles as well as operational procedures, data analysis and reporting.

Who should attend? Pipeline Engineers, Integrity Engineers, Corrosion Specialists, Engineering Consultants in the field of pipeline inspection and integrity, personnel from regulators or certifiers involved with pipeline inspection and assessment.

Course Objectives Approximately 40% of all pipelines installed globally are considered “un-piggable,” which means they cannot be inspected with traditional free-swimming in-line inspection tools. However these other lines also have to be inspected to investigate whether there are geometric, metalloss or crack-related issues that would affect their mechanical integrity. Many of these challenging lines can be inspected from within, i.e. using specially designed or modified tools. Some, however, will have to be inspected from the outside because internal inspection is not possible at all. The important questions relating to the inspection of Challenging Pipelines are: • Accessibility:how can the line be accessed and how can an inspection device be introduced into the line? • Negotiability:this relates to either operational challenges such as high flow and high pressure or low flow and low pressure during the inspection. It also relates to issues such as bends, diameter variations and other issues relating to the design or the operation of the pipeline. • Propulsion:How is the tool moved through the line? Can it be pumped, is a cable or tether needed or maybe even a robotic approach?

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All this will be covered in order for the partcipants to fully understand the difference between “piggable” and “unpiggable” pipelines. The objective of the course is to build this understanding and provide an awareness of a wide range of solutions available on the market. Continuing Education Units: 1.4

Lecturers Dr. Michael Beller has more than 28 years’ experience in the pipeline inspection industry. Having served in both technical and management positions with Preussag Pipeline Services, Pipetronix, PII and NDT Systems & Services, he is currently Director of Corporate Strategy - Pipelines with Rosen Technology & Research Center in Karlsruhe, Germany. Michael holds a master’s degree in mechanical engineering, and obtained his PhD in fracture mechanics. He has been involved with a large number of inspection projects all around the world, including on- and offshore inspection work. Michael has considerable experience as a presenter and trainer, and in lecturing. He has authored more than 75 papers on the subject of pipeline inspection and intelligent pigging, and is also co-author of a German reference book on pigging technology. Currently, Michael serves on a number of Technical Committees and is also a member of the editorial board of The Journal of Pipeline Integrity. He is a former president of the Pipeline Products and Services Association. Dr. Konrad Reber studied physics and material science at the University of Mainz and Erlangen. For his Ph.D. thesis he worked on stray flux methods for the testing of magnetic materials. At Pipetronix he was responsible for the development of data analysis algorithms and the design of MFL-pigs. After moving to NDT Systems & Services AG in 2000, his focus changed to defect assessment and integrity management. Between 2006 and 2008 Konrad was with TÜV Rheinland as an expert within the Pipeline Technology Group. Since 2008 he has been head of research and development for the Innospection Group. His department is responsible for designing new inspection equipment for the oil and gas industry. His focus is on the development and refinement of testing technologies with applications for underwater and otherwise difficult-to-inspect structures.

Managing Cracks and Seam Weld Anomalies on Pipelines “If the operator has reason to believe any pipeline segment contains or may be susceptible to cracks or crack-like defects … the operator must perform fracture mechanics modeling for failure stress pressure and crack growth analysis to determine the remaining life of the pipeline….” PHMSA Notice of Proposed Rulemaking

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arious forms of cracks or crack-like indications are known to be present in pipelines, which could become a safety concern to their safe operation. The most common forms of cracking are manufacturing related, environmentally induced, and mechanically driven, such as Stress Corrosion Cracking, Corrosion Fatigue Cracking, Hydrogen-Induced Cracking, Hook Cracks, and anomalies associated with the Seam Weld (as those found in vintage ERW/flash-welded pipe). This course will provide an integrated, data-driven approach for addressing these forms of cracking and seamweld anomalies. It covers in greater depth the formation of these types of features and the conditions that drive their growth until they become unstable, leading to leaks or ruptures. The appropriate assessment methods such as ILI crack tools, pressure testing and direct assessments will be presented as well as traditional and current engineering approaches for establishing crack severity and determining future integrity. Case studies will be reviewed and discussed throughout course instruction. Appropriate repairs options for cracks will also be covered. This course will be taught at the Pipeline Research Council International (PRCI) Technology Development Center in Houston Texas. Throughout the course, the instructor will be using pipe samples with actual cracks and seam weld anomalies located at this research center. Attendees will benefit from experiencing a world-class collection of pipe samples and discussing how the various types of cracks form and grow in pipelines.

What Will Be Learned On completion of the course, the student will understand what factors contribute to the formation and growth of crack‐like features and seam-weld anomalies in pipelines. In addition, the participant will be able to gather and analyze the type and extent of cracking found, key operational parameters, pipe material properties, full-scale testing data, and ILI crack tool data, and to apply industry-recognized engineering methods for developing and recommending appropriate remedial actions.

Who should attend? • Pipeline engineers and maintenance personnel who are involved or responsible for the maintenance, inspection, assessments and repair of pipeline systems • Non-Destructive Inspection personnel who wish to acquire or increase their knowledge of crack formation and growth in pipelines • Analysts who review ILI Crack tool data and issue inspection reports

Documentation and Materials Participants will receive a full set of course slides and notes in paper and electronic form, in color throughout. Continuing Education Units: 1.6 (1.4 for the 2-day version)

“Very good course and well taught; numerous takeaways to review and use to be a better operator.” – Erick Hallett

“Very knowledgeable instructor; great use of examples and experiences to complement the material.” – McKenzie Kissel

Lecturer Sergio Limon has worked in the oil & gas pipeline industry for more than 15 years with emphasis on pipeline integrity threat analysis and response. He was employed for 10 years with a large owner and operator of natural gas gathering, processing and transportation services. He led for six years the Asset Integrity group for the western division responsible for the analysis, response and remediation of integrity threats as well as the implementation of the Gas Integrity Management Program. Sergio holds B Sc. and M Sc. degrees in Mechanical Engineering with emphasis in fracture mechanics and materials from the University of Utah. He is the founder of Limon Pipeline Integrity Analytics.

Syllabus Material Behavior and Engineering Fracture Mechanics Characteristics and Behavior of Cracks Found on Pipelines Evaluating Crack Severity Repairing Crack-like Features and Seam Weld Anomalies Appropriate Crack Assessments

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Hydrostatic Testing of Pipelines

Course Outline

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his course is designed for pipeline personnel in engineering, integrity management, operations, and regulatory compliance roles. This course will cover a wide range of topics related to hydrostatic testing of pipelines for gas and hazardous liquid service for both in-service and new construction according to CFR 49 Parts 192 and 195.

Course Objectives To provide attendees with necessary information for planning and conducting a successful hydrostatic test, whether it’s for initial service or retesting existing lines. Planning will cover review of integrity prior to testing through evaluation of test results. The course will focus on testing with water but testing with other medium will be discussed.

Instructor Gary Zunkel, PE, is the Director of Mainline Engineering with Lake Superior Consulting in Duluth, MN. He has been involved in the oil and gas industry for over 30 years with the last 10 years focusing on pipeline integrity management. He has been involved with over 100 pipeline tests; planning, managing, and reviewing. In recent years, he has planned and conducted multiple, simultaneous tests on large diameter in-service pipelines for integrity verification. Continuing Education Units: 1.6 (1.4 for the 2-day version)

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Who Should Attend The course is intended to cover the technical aspects of planning and conducting a hydrotest. It is designed for engineers, project managers, integrity management, and operations personnel to prepare for testing. The following topics will be covered: • • • • •

Pipeline integrity review Water source identification, disposal, and permitting Leak detection Risk assessment and contingency planning Calculations for test pressures according to 49 CFR 195 • Assessment of test results, including methods of analyzing pressure discrepancies • Test scheduling • Documentation for regulatory review

1. Establishing Test Requirements • Purpose of the test ◊ Evaluate integrity of the pipeline ◊ Confirm integrity program • Establishing pressure requirements ◊ Federal regulatory requirements • Liquid – 49 CFR 195 • Gas – 49 – CFR 192 ◊ Pressure parameters based upon MOP/MAOP requirements ◊ Strength Test ◊ Leak Test ◊ Spike Test • Segment Isolation ◊ Headers & End Caps ◊ Valves • Gel Isolation 2. Conducting a Safe Test • Risks of potential energy ◊ Compressed gas ◊ Compressed liquid • Protecting the public • Managing test safety ◊ Immediate area ◊ Equipment • Communication prior to and during a test 3. Preliminary planning • Pipeline evaluation ◊ Historical records evaluation • Repairs • Previous test records • Integrity records • Equipment pressure ratings • Elevation profile • Water sources • Water crossings • Exposed pipe 4. Test Schedule • Preliminary Scheduling ◊ Water source & landing ◊ Outage ◊ Permitting ◊ Pipeline rehabilitation ◊ Notifications • Test Setup ◊ Site preparation ◊ Line Isolation ◊ Line fill • Test Sequence ◊ Stabilization ◊ Pressurization ◊ Test time ◊ Depressurization • Water movement & discharge • Restoring a line to service 5. Water as a test medium • Source ◊ Permits

◊ Volumes ◊ setup • Discharge ◊ Permits ◊ Treatment • Volume requirements and calculations 6. Other test medium • Liquid hydrocarbon • Natural gas • Nitrogen • Air • Applications ◊ Requirements ◊ Changes in test planning ◊ Instrumentation 7. Leak Detection • Dye • Gas • Acoustic pressure • Section isolation ◊ Valves ◊ Freeze plugs ◊ Test headers/caps 8. Test Documentation • Graphs • Calibration certificates • Drawings • Elevation profile • Test procedure • Summary of results • Explanation/calculations of pressure changes ◊ Test pressure interpretation ◊ Temperature effects on pressure ◊ Air entrapment ◊ Examples of test results and interpretation • Pressure Volume (PV) Plot ◊ Creation of a PV Plot ◊ Offset Line ◊ Interpretation of a PV Plot • Test log • OQ documentation ◊ Historical records evaluation • Repairs • Previous test records 9. Managing water movement • Fill rate • Purging prior to line fill • Dewatering ◊ Product ◊ Air • Drying ◊ Explanation of terminology • Penetration depth • Dew point and temperature • Air lock • Contamination • Contingency ◊ Drain up calculations

◊ Refill/Retest planning • Discharge ◊ Rates ◊ Discharge structure ◊ Treatment of contaminated product • Pigging ◊ Types ◊ Multiple pigs in the line ◊ Launching receiving ◊ Bypassing a station ◊ Tracking 10. Instrumentation • Types – Pressure & Temperature ◊ Bourdon Tube (Pressure & Temperature) ◊ Bi-metallic (Temperature) ◊ Resistance Temperature Detector (RTD) ◊ Quartz electronic • Accuracy vs. Repeatability • Calibration • Pressure measurement ◊ Deadweight – Mechanical/ Electronic ◊ Gauges ◊ Recorders • Temperature ◊ Thermometer ◊ Recorders • Quantity • Placement • Type • Volume measurement ◊ Stroke counter ◊ Flow meter 11. Data Interpretation & calculations • Pipeline evaluation ◊ Historical records evaluation • Repairs • Previous test records 12. Test Failure • Rupture • Leak • Pressure reversal • Equipment failure • Location of failure • Repairs • Retesting 13. Contingency Planning • Repair materials ◊ Sleeves ◊ Replacement Pipe ◊ Stopples • Emergency Response ◊ Public relations ◊ Notifications ◊ Cleanup and remediation • Retesting ◊ Venting & refill

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NEW! Safety and Engineering Assessment of Onshore Pipeline Gathering Systems

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he aim of this course is to help engineers understand the most important considerations in developing a plan for managing onshore gathering system integrity. The intent is to provide a thorough background of systems and processes in order to develop customized Mechanical Integrity Management plans and strategies. Accordingly, the course will focus on these primary areas: • Types of gathering systems • Integrity threats affecting gathering systems and flowlines • Gathering system construction materials and practices • Risk assessment • Risk management • Codes and regulations • Pipe inspection and assessment • Anomalies, imperfections, and defects • Assessing anomalies • Pipe repairs • Forward planning

Who should attend? Project managers, pipeline engineers and maintenance personnel who are involved or responsible for the maintenance, inspection, assessment and repair of pipeline systems. Continuing Education Units: 1.4

Documentation Participants will receive a full set of course slides and notes in paper and electronic form, in color throughout.

Lecturer

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Bryan Melan has 40 years of experience in mechanical and structural engineering and project management in the upstream and midstream oil & gas industries, including 27 years specializing in pipeline integrity management and engineering with Sunoco Logistics and, for 16 years, with Marathon Oil, where he was most recently Pipeline Integrity Subject Matter Expert for Marathon’s worldwide assets. Bryan is currently owner and principal engineer at Tide Water Integrity Services LLC, an engineering consultancy providing expertise on pipeline and fixed equipment structural integrity engineering: risk assessment, inspection, data integration, data validation, asset fitness-for-service and design life-extension analyses for fixed equipment such as pipelines, process piping, pressure vessels, and tanks. He is also currently engaged to provide expert witness services in new pipeline construction and patent infringement litigation.

Syllabus Types of Gathering System Configurations • Pad & Central Battery Systems • Vapor Recovery and Primary Treatment • Flowlines & Ancillary systems Integrity Threats Affecting Gathering Systems and Flowlines • External Corrosion • Internal Corrosion o Galvanic o Oxygen o Under-deposit o MIC • Spans and Washouts • Third Party Damage • Construction Defects • AC and DC Interference Gathering System Construction Materials and Practices • Steel Pipe Manufacture • Construction planning for integrity management and assessment • External coatings • Internal liners, pre-fab and retrofit • Internal cladding • Pipe-in-pipe • ZapLok • Composite Materials • Duplex steels • Flexible pipe • Hot taps • NACE MR0175 materials and practices • Other material codes and practices Risk Assessment • Liquid Spill Modeling • Gas Potential Impact Radius (PIR) • Quantitative Risk Assessment • Relative Risk Assessment and Prioritization • ASME B31.8S threats • Pipeline Cleaning & Inspection – from basic to high tech • Operations Issues Risk Management • Hydraulic Models and Internal Leak Detection Systems (CPM) • External Leak Detection Systems • Flow Assurance • Product Quality & Preventive and Mitigative Measures Monitoring

Codes and Regulations • API RP 80 • CFR 192 & 195 jurisdiction • Pending PHMSA regulations • State Codes • BSEE Subparts H and J Pipe Inspection • Direct Assessment • In Line Inspection • “Unpiggable” Technologies Anomalies, Imperfections, and Defects • Time Dependent Anomalies o Metal Loss o Cracking • Time Independent and Stable Anomalies • Selecting Anomalies for Investigation and Validation • Codes: API 1163, NACE SP0102, ASNT ILI-PQ o API 1163 terminology Assessing Anomalies • Pipe Preparation for Visual/NDE • NDT Methods • Assessment Codes, Fitness-for-Purpose Determination • POF specification Pipe Repairs • Sleeving • Composite Repairs • Other Repairs Allowed by Code – Recommended and Not Recommended • Temporary vs. Permanent Repairs • PRCI Pipe Repair Manual Forward Planning • Data Exploitation and Probability of Exceedance • Reinspection Interval Determination o Corrosion Growth Models o Growth Rates from ILI o Fatigue Crack assessment • Pipeline Design Life Extension

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Inspection of offshore pipelines and tubular structures Course objectives To provide a wide-ranging overview of internal and external inspection procedures, technologies, and equipment for pipelines and associated structures.

Who should attend?

Documentation The course will be fully documented with all slides and related documents printed in a durable four-ring binder for reference during and after the course, providing an invaluable reference document. Continuing Education Units: 1.4

Those responsible for offshore pipeline integrity and maintenance as well as those responsible for the design and operation of such pipelines.

Lecturers Dr. Michael Beller has more than 28 years’ experience in the pipeline inspection industry. Having served in both technical and management positions with Preussag Pipeline Services, Pipetronix, PII and NDT Systems & Services, he is currently Director of Corporate Strategy - Pipelines with Rosen Technology & Research Center in Karlsruhe, Germany. Michael holds a master’s degree in mechanical engineering, and obtained his PhD in fracture mechanics. He has been involved with a large number of inspection projects all around the world, including on- and offshore inspection work. Michael has considerable experience as a presenter and trainer, and in lecturing. He has authored more than 75 papers on the subject of pipeline inspection and intelligent pigging, and is also co-author of a German reference book on pigging technology. Currently, Michael serves on a number of Technical Committees and is also a member of the editorial board of The Journal of Pipeline Integrity. He is a former president of the Pipeline Products and Services Association.

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Dr. Konrad Reber studied physics and material science at the University of Mainz and Erlangen. For his Ph.D. thesis he worked on stray flux methods for the testing of magnetic materials. At Pipetronix he was responsible for the development of data analysis algorithms and the design of MFL-pigs. After moving to NDT Systems & Services AG in 2000, his focus changed to defect assessment and integrity management. Between 2006 and 2008 Konrad was with TÜV Rheinland as an expert within the Pipeline Technology Group. Since 2008 he has been head of research and development for the Innospection Group. His department is responsible for designing new inspection equipment for the oil and gas industry. His focus is on the development and refinement of testing technologies with applications for underwater and otherwise difficult-to-inspect structures.

Syllabus Typical defects and loading conditions of offshore pipelines Pipeline materials Types of pipeline and riser Loading conditions Flaws and defects Special issues relating tdeep offshore Non-destructive testing techniques and technologies Magnetic-flux leakage technology (axial and circumferential) Ultrasound technologies (piezoelectric and EMAT) Eddy-current technologies (EC, remote-field EC, pulsed EC, SLOFEC) Other technologies Available inspection equipment and technologies Internal: free-swimming tools Internal: tethered and cable-operated tools Riser and caisson inspection Topsides’ inspection (piping, pressure vessels, welds) Subsea inspection including flexible risers Inspection procedures Planning an inspection Preparing the pipeline for an inspection Performing the inspection Special consideration regarding deep offshore applications Reporting Data evaluation Feature localization Feature identification and characterization Introducing POF Final report MAOP Run comparison Data management and archiving Integrity assessment MAOP metal-loss assessment Crack assessment Literature Exercises: the course includes exercises covering the following topics: Which tool does what? How tread tool data and defect-specification sheets Preparing an inspection project

Geohazard Management for Pipeline Engineers

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he course is an introduction to Geohazard Management for non-geotechnical pipeline managers and regulators within the Canadian context. It focuses on the key issues in Pipeline Geohazard Management, including: • Leading concepts and practices for the entire pipeline life cycle • Identification of Geohazards and their effects on pipelines • Risk reduction strategies during design, construction and operations The course covers the management of related data, risk assessment, monitoring and mitigation technologies. It also reviews the range of risk assessment methods with examples from the pipeline industry. In recent years, the pipeline engineering and construction community has gained valuable experience associated with routing, design and construction of new major pipeline projects in challenging environments, and in meeting the heightened expectations of ensuring the integrity of aging operating systems. World-wide, regulatory agencies are raising their expectations of the pipeline industry to deal more rigorously with Geohazards including landslides, erosion and seismicity. The topics addressed in this course have recently seen significant advances that have redefined the state-ofpractice in how to design, construct and ensure the integrity of operating pipelines in areas prone to Geohazards. An important guiding philosophy for practically managing these hazards in a responsible yet cost-effective manner is to consider Geohazard effects from the pipeline out, as opposed to a purely geotechnical treatment of Geohazard occurrence independent of the pipeline.

Lecturers Moness Rizkalla is president of Visitless Integrity Assessment Ltd. in Calgary. Prior to forming VIA he held positions with WorleyParsons, TransCanada / NOVA, and PRCI. Mr. Rizkalla is a recognized specialist in pipeline design and integrity management. His experience includes several management and senior technical roles in pipeline design, project management, pipeline risk assessment and integrity management planning, operations support, and associated technology development and applications. His professional experience has been gained in both Canadian and international settings. Within the pipeline integrity management area, Mr. Rizkalla has specialized in the management of external load hazards – geotechnical and mechanical damage. He has been involved in a wide range of pipeline geotechnics with an extensive list of associated publications. In 2000 he founded Visitless Integrity Management, a company that delivers commercial proactive prevention solutions to the pipeline industry’s mechanical damage challenges. Mr. Rizkalla holds a BS in Civil Engineering and an MS in Civil Engineering (Geotechnical). Dr. Rodney S. Read is a practicing consulting engineer specializing in applied rock mechanics and geotechnical engineering. He is president of RSRead Consulting, Inc., based in Okotoks, Alberta. Dr. Read has been involved in projects ranging from concepts for nuclear waste disposal to geohazard assessments for pipelines in challenging physiographic environments. He was geotechnical lead on the Turtle Mountain monitoring project at the historic Frank Slide in southern Alberta, the site of Canada’s deadliest landslide. His current interests involve geotechnical risk assessment of linear systems in difficult terrain. Dr. Read holds a BS in Geological Engineering and a Ph.D. in Civil & Geological Engineering. Continuing Education Units: 1.4

Who should attend? Supervisors, engineers and technicians responsible for ensuring the adequate protection of pipeline assets; regulators.

Course notes All delegates will receive a detailed set of lecture notes on cd providing an invaluable reference document. The course documentation also includes the reference book Pipeline Geo-Environmental Design and Geohazard Management edited by Moness Rizkalla (2008) as well as the 2009 PRCI study Guidelines for Constructing Natural Gas and Liquid Hydrocarbon Pipelines Through Areas Prone to Landslides and Subsidence Hazards, a combined $225 value.

Syllabus DAY 1 1. Introduction 2. An overview of regional Geohazards – focusing on the more commonly encountered hazards such as landslides, seismic, subsidence and water course related integrity issues 3. Data Management Requirements and Utilization 4. Hazard Assessment Methodologies – Prioritizing and Addressing risk 5. Hands-on Exercise

DAY 2 6. Monitoring – An overview of options 7. Design and Operational Mitigation - an overview of options 8. Hazard Reduction strategies during design and construction 9. The Geohazard Management Planning Process – Integration of components 10. Hands-on Exercise 11. Conclusion

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Onshore Pipeline Engineering

Course Program Day 1

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HERE ARE millions of kilometers of onshore oil and gas pipelines around the world. As the industry expands and new staff are introduced into it, there is an increasing need for full appreciation of the engineering design of pipelines. Additionally, many staff in the pipeline industry have not received basic pipeline engineering training, and some staff are only exposed to specialized areas. This course is a formal introduction to pipeline engineering.

Who should attend? “I really liked the information, pictures and illustrations of actual execution of pipeline construction and operational activities - a lot of this is not taught in school.” —Samantha Choi, ConocoPhillips

• Engineers who are new to the pipeline business and those who wish to update their knowledge, including: • Pipeline engineers, pipeline construction engineers, project managers, maintenance engineers, contractors, supervisors, inspectors, operators, equipment suppliers, inspection and quality engineers, pipeline design engineers. • Engineers who need a wider appreciation of onshore pipeline engineering.

Documentation Included with the course fee is a detailed set of lecture notes (700 pages, COLOR) and a CD containing an additional 300 pages of text reference material. Continuing Education Units: 3.0

“Good experience and lots of knowledge for someone new to pipeline engineering like me. All topics covered were very informative and thoroughly explained, regardless of time constraints. Dr. King and Prof. Hopkins did an excellent job. Thanks to Clarion and GPM for this great course.” “The instructors’ knowledge and experience are first rate.”

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• Lecturers

Dr Phil Hopkins is a consulting engineer with more than 35 years’ experience in pipeline engineering. Phil formed his consultancy company in 2015, after being Technical Director with Penspen Ltd in the UK, and previously Managing Director of Andrew Palmer and Associates, in the UK. He has worked with most of the major oil and gas companies and pipeline companies around the world, providing consultancy on management, business, design, maintenance, inspection, risk analysis and safety, and failure investigations. He is the past-chairman of the ASME Pipeline Systems Division, and is a Fellow of ASME. More than 15,000 engineers and technical personnel around the world have attended his courses. He also teaches extensively on masters’ programmes at Newcastle and Northumbria Universities in the UK. Dr Roger King has over 30 years’ experience of corrosion in the oil, gas, civil, and nuclear industries. He has specialist knowledge of sweet and sour corrosion and its prevention by chemical inhibition, monitoring of corrosion, microbiological corrosion, and the design of efficient cathodic-protection systems for flowlines, structures, and seabed installations. He has been an independent consultant since September, 1989, and prior to this was a founder member of the Corrosion and Protection Centre Industrial Service (CAPCIS) at the University of Manchester Institute of Science and Technology (UMIST). Tom Miesner is a pipeline industry consultant providing management consulting and technical training through his company, Pipeline Knowledge & Development. He spent 25 years with Conoco Pipe Line Company, where he held multiple engineering, operations, joint-venture, business development, and executive positions, serving for six years as President. Tom is a past chairman of AOPL and has also been active in the API’s Pipeline Committee. He has worked extensively with FERC in areas of liquid pipeline rate matters and is the author of the popular book Oil and Gas Pipelines in Non-Technical Language and co-author of the PRCI report The Role of Energy Pipelines and Research in the United States.

“The course is great ... knowledgeable and experienced lecturers. What I liked most was the information from the presentation slides ... very useful to me.”

Pipeline Engineering Basics (HOPKINS) • Basics of Oil and Gas • The Petroleum Industry • Introduction to Pipelines • Basic pipeline and material parameters • Pipeline Safety • History of Pipelines Pipeline Materials Selection (KING) • Steels used for Line pipe • Compositional Limitations, Mechanical Properties, Grades • Fabrication of Line pipe – Seamless, Longitudinal Welded, ERW, Spiral • Toughness and Weldability • Improving Corrosion Resistance • Solid Corrosion Resistant Alloy Pipe • Internally Clad Pipe • New Materials Pipeline Design (HOPKINS) • Legislation and regulations • Development of pipeline design codes • Design Process • Detailed design: • Pipeline Crossings • Pipeline Valves

Day 2 Other Pipeline Design Considerations (HOPKINS) • Surges/overpressures • Bends • Pipe protection • Fracture control • Fluids and Hydraulics Pipeline Welding (KING) • Basics of Welding • Types of Welding Processes • Effects on Line pipe of the Welding Process • Welding Procedures • Inspection of Welds Design Exercise Part 1 Pipeline Routing and Construction (HOPKINS) • Basics of routeing • Classification schemes • Easements and rights of way • Legislation and permits • Routeing methodologies • Pipeline construction Internal Pipeline Corrosion (KING) • Why Pipes Corrode • Sweet Corrosion, Sour Corrosion, Microbiological Corrosion • Cracking Mechanisms • Calculating Corrosion Rates • Effect of Flow on Corrosion • Water Injection Pipelines

Day 3 Monitoring of Internal Pipeline Corrosion (KING) • Inhibition of Corrosion • Biocide Treatment of Pipelines

• Monitoring Internal Corrosion • Supplementary Inspection Techniques Pipeline Testing, Operation, Inspection (Hopkins) • Pressure Testing • Batching • Incorrect operation • Control Systems, Leak Detection • Inspection and monitoring of operational pipelines Pipeline Project Control (HOPKINS) • Management • Scheduling and resource planning • Execution • Contracting strategies External Pipeline Corrosion and its Prevention (KING) • External Corrosion in Soils • Coatings and their Application • Field Joints • Interaction of Coatings and Cathodic Protection Design Exercise Part 2

“A great course...I’m glad to have had the opportunity to attend”

Day 4 Cathodic Protection (KING) • How Cathodic Protection Works • Monitoring of CP at Test Points • Full Line Surveys with CIPS and Instant Off Surveys • Coating Surveys using Pearson and DCVG Techniques • Interference from Third Party Lines and DC/AC systems Utility and Intelligent (Smart) Pig Inspection (HOPKINS) • The History of Internal Inspection • Why ‘Pig’? • Types of Pig • The History of Internal Inspection • Why ‘Pig’? • Types of Pig • Intelligent (Smart) Pigs: • What do they find and how accurate are they? • Pigs versus Hydrotest Pipeline Equipment and Systems – (Miesner) • Hydraulic tools • Equipment – pumps, compressors, motors, pressure control devices • SCADA • Leak detection

Day 5 Pipeline Engineers (HOPKINS) • Responsibilities, duties and ethical behavior Pipeline Repair (HOPKINS) • Pipeline Defects • Pressure reductions prior to repair • Repair methods Pipeline Integrity Management (HOPKINS) • Risk and risk analysis • Integrity management methods: • Class tutorial – risk analysis of 3 pipelines Close with Question and Answer Session (HOPKINS & KING)

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Pipeline Pigging and ILI

Practical Pigging Operations

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HE USE of in-line tools for inspection and cleaning is accepted as essential for the safe and profitable operation of all pipelines. internal inspection is required for detecting changes in circumference, anomalies, or wall loss due to corrosion. Pipeline operators offshore wage a constant battle for flow assurance against paraffin, hydrate, and asphaltene formation in deepwater lines, and pigging, combined with chemical treatment, is their primary weapon. The course is designed to provide a comprehensive introduction to all aspects of utility and in-line inspection pigging.

“Time well spent!! Very comprehensive and detailed. Don’t change a thing!” — J. Ryman, BP

“I came with very high expectations and was not disappointed. I have been presenting adult education for 10 yrs. Very professional from introduction to closing”

—D. Hennerbichler, ESSO

“Good speakers who know their stuff.”

—I. King, ConocoPhillips

“A solid overview of ILI tools and processes. The speakers were exceptionally knowledgeable in their subject areas.” —Erin Wishart, Union Gas Ltd.

14 “Good knowledge of ILI tools and excellent explanations”

—Osaze Uwagboe, ExxonMobil

Lecturers Dr. Tom Bubenik is Vice President of Integrity Services at CC Technologies Services, Inc. He has more than 20 years of experience in pipeline integrity assessments, in-line inspection tools and their capabilities, direct assessment techniques and methodologies, field data collection, and the impact of defects and inspection on pipeline operations and maintenance. Dr. Bubenik’s research experience covers inspection technologies for pipelines, analysis tools for corroded and damaged pipelines, and repair techniques for pipelines. Pam Moreno has over 25 years experience assisting clients in getting the most from their pipeline integrity efforts, including Inline Inspection programs. She specializes in conducting risk and threat assessments of pipeline facilities. She is involved in all aspects of Asset Risk Management of Pipelines and Facilities, evaluating risk of pipeline segments based on multiple integrity threats and data sets, assisting clients in developing their Integrity Management Programs and more specifically their Inline Inspection programs. Gary Smith is president of Inline Services, a Houstonbased company specializing in pigging equipment and services. He has 27 years experience in the pipeline pigging industry, working in services such as commissioning and maintenance of pipelines as well as with designing and manufacturing pigging equipment. George Williamson is currently Segment Engineering Technical Authority – Inspection, for the Upstream Global Projects group within BP. He has more than 25 years of Operations, Maintenance and Integrity Management experience. He is a registered professional engineer, NACE certified corrosion and a cathodic protection specialist. He has managed compliance and integrity programs for production facilities, gathering systems, liquid and gas transmission pipelines. Chris Yoxall is Executive Vice President, ROSEN USA/ Mexico and ROSEN Asia Pacific. He commenced his career in South Africa and thereafter relocated to Perth, Australia and now also resides in Houston, USA. Chris remains globally active with industry memberships and committees as is involved in development and oversight of standards and practices related to pipeline inspection and integrity assessment, including PRCI, ASME, NACE, and APIA. Chris is on the APIA RSC executive committee and has a passion for supporting and mentoring newly inducted professional engineers into our industry. Chris, with a mechanical and metallurgical engineering background, has more than 20 years of industry experience and has worked throughout Africa, Asia, Europe and North America.

Who should attend? The course is specially designed for project managers, engineers, maintenance, and technical personnel responsible for pipeline integrity assurance, flow assurance, corrosion control, and safety.

Course Program DAY 1 Pipeline safety and regulations • Brief history of pipeline failures • Impact of recent legislation and regulations • Review of inspection and maintenance compliance • What to expect in pending regulations Pigging for operation and maintenance • Pigging during construction • Pigging during operation Utility pigs • Cleaning pigs, Sealing pigs, Gauging pigs • Dual diameter pigs, Magnetic cleaning pigs • Designing a pipeline for pigging • Pig traps, pigging stations, Location, tracking devices In-line inspection (ILI) tools • Line pipe integrity threats • ILI tools available to the operator • Metal loss inspection, Deformation tools, Crack detection, Movement and pipeline mapping

DAY 2 Designing and implementing an ILI program • Selecting an ILI tool • Specific design considerations for running ILI tools • Launch and receive trap design • Bends, tees, and valves, Issuing an enquiry • Schedule requirements, Preparation for ILI • Controlling operational parameters • Strategy for contract development and negotiations • Developing a good specification • Contingency planning for a stuck pig • Offshore risers, Onshore flowlines Post in-line inspection issues • The inspection report, Responding to the report • Response prioritization • Validation of the inspection report • Acceptance of the report • Re-assessment intervals - risk and probabilities

Documentation Included with the course fee is a detailed set of lecture notes and the reference handbook Pipeline Pigging & Integrity Technology, 4th Edition (2013).

Continuing Education Units: 1.4

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HIS NEW TRAINING COURSE is being developed to provide a wide-ranging overview of all aspects of pigging operations. The course will be held at several different pressurized pipeline test loop facilities around the world (see below for locations).

Who should attend? Engineers and technical personnel involved in field pigging operations.

Course Notes The classroom portions of the course will be fully documented with all slides and related documents printed in a durable 3-ring binder for reference during and after the course.

Syllabus The syllabus will include both hands-on exercises using the test loop(s), and classroom instruction, and include full documentation. The content of the course is being developed jointly by Penspen, Rosen Engineering, and Clarion/Scientific Surveys Ltd. Rosen Engineering, through its Rio de Janeiro office, has agreed to provide cleaning-, geometry-, and intelligent tools for use during the course, along with its expert technicians. Among subjects that the syllabus will cover are: • Pig trap doors: design, operation • Types of utility tool • Types of intelligent tool • Launch/receive trap design • Launching and receiving utility and intelligent tools • How to assess a tool’s performance • Signaling and pig location • Locating and reporting sample defects • Site safety: procedures and performance The syllabus will include both hands-on exercises using the test loop(s), and classroom instruction, and include full documentation.

Lecturers Nancy Leek is a pipeline integrity engineer with over 5 years’ experience in integrity management for onshore and offshore oil and gas pipelines. Nancy has worked on a wide range of pipeline integrity projects for numerous operators around the world. Her focus has mainly been on defect assessments, risk based inspection, IMR planning and pipeline strain assessment. She previously worked for an intelligent pigging inspection company and has extensive knowledge in interpreting magnetic flux signals and intelligent pig capabilities. John Simon has specific knowledge of Pigging Operations for both onshore and offshore pipelines and worked in Pipeline Operations & Maintenance, Pigging Product Development, Business Management and Pigging Business Development. John has held senior manager positions and has more than 25 years international experience including Planning, Engineering Studies, Supervision and Project Management of Pipeline Pigging operations for Oil, Gas and Product pipelines. John has provided training for pigging and was a developer of the Practical Pigging Training Course. Peter Smith is a UK Chartered Engineer MIMechE with over 23 years of experience working within the Pigging and ILI inspection industry, starting his career with British Gas Online Inspection Centre (OLIC) in 1990. He has operated globally both offshore and onshore as an ILI Field Inspection Technician, Field Engineer, Operations Manager, Project Manager and Senior ILI Applications Engineer for North America for one of the major inline inspection companies. Peter is presently the North American General Manager for Penspen Integrity and a senior ILI Consultant.

“A great course with lots of useful information and practical advice. I would recommend it to anyone interested in the subject.”

“I learned a lot more than I expected.”

“Wonderful - it is a complete basic course. Nice simulations and a marvelous staff.”

Test loop operators: Centro de Tecnologia em Dutos (CTDUT) (Pipeline Technology Center, Rio de Janeiro) Greene’s Energy Group, Houston KTN, Bergen A. Hak Industrial Services, Amsterdam (Tricht) Continuing Education Units 3.0

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Defect Assessment in Pipelines

M “Surpassed my best expectations” “I found the course to be extremely educational and well presented.” “Dr. Hopkins is very knowledgeable, and he communicates the course content well... makes it easy to understand.” —Ricardo Montes, Southern California Gas Co.

“The broad subject matter approach filled a lot of knowledge gaps” —Charles Bartunek, Tesoro SoCal Pipeline Company

“Good lecturer, attentive to students’ queries and knowledgeable of the pipeline business.”

—Preston Smith, Engineer in Materials/Corrosion/ Inspection/Structural [company name withheld by request]

ANY TRANSMISSION pipelines are now over 50 years old. This is “middle aged” in pipeline terms, and even the best-designed and -maintained pipeline will become defective as it progresses through its design life. Therefore, operators need to be aware of the effect these defects will have on their pipeline, and — more importantly — be able to assess their significance in terms of the continuing integrity of the pipeline. The increasing use of high-technology maintenance (for example, intelligent pigs) is helping pipeline owners to assess the condition of their lines, and if these modern maintenance methods are combined with modern defectassessment methods, they can provide a very powerful, and cost-effective, tool. This course will present the latest defect-assessment methods to pipeline engineers and managers. These methods will range from simple, quick, assessment methods, to the more-detailed —fitness for purpose— analysis. The course is highly interactive and takes the form of lectures, workshops, and case studies. The course will cover methods available to assess the significance of defects detected in onshore and offshore pipelines. It will introduce simple analytical methods used to assess internal and external corrosion, dents and gouges, cracks (e.g. SCC), weld defects, and fatigue. The course is unique as it is a holistic approach to defect assessment, and it ensures the student appreciates all aspects of the subject, including repair and risk management.

Who should attend? Pipeline engineers, designers and service professionals who are involved with the maintenance, inspection, and repair of pipelines.

Documentation All participants will receive a detailed set of lecture notes (700 pages in COLOR) plus a CD containing 500 pages of documents for further reference.

Lecturer Dr. Phil Hopkins is a consulting engineer with more than 35 years’ experience in pipeline engineering. Phil formed his consultancy company in 2015, after being Technical Director with Penspen Ltd in the UK, and previously Managing Director of Andrew Palmer and Associates, in the UK. He has worked with most of the major oil and gas companies and pipeline companies around the world, providing consultancy on management, business, design, maintenance, inspection, risk analysis and safety, and failure investigations. He is the past-chairman of the ASME Pipeline Systems Division, and is a Fellow of ASME. More than 15,000 engineers and technical personnel around the world have attended his courses. He also teaches extensively on masters’ programmes at Newcastle and Northumbria Universities in the UK. Continuing Education Units: 1.7 (1.4 for the 2-day version)

16 “Great presenter. Good at keeping the class’s attention and making the information interesting.” —Alexander Woll

Course Program DAY 1 Introduction to basic pipeline engineering principles • Basic pipeline design principles • Stresses in pipelines • Routing of pipelines • Basic pipeline operating and maintenance parameters • Maintenance and inspection methods Introduction to pipeline defects – why pipelines fail • How safe are pipelines? • How often do they fail? • What causes pipelines to fail? • Pipeline risks • History of pipeline defect assessment Introduction to fracture mechanics (handouts and notes only, no lecture) • Basic theory • Brittle and ductile fracture • K, J, and CTOD

• Assessing non planar defects in welds • The EPRG girth weld defect guidelines • Fatigue design of girth welds Setting intelligent pig inspection levels • Pigs — where they came from and what they can do • Basic theory • Magnetic, ultrasonic pigs – their accuracy and limitations. • What pigs can detect • What operators want to detect • Setting intelligent pig inspection levels Workshop: setting intelligent pig inspection levels How to assess fatigue (handouts and notes only, no lecture) • Why do pipelines fatigue? • Basic fatigue theory • Fatigue assessment – design • Fatigue assessment – service

Fundamental pipeline defect failure relationships • Why pipeline defects fail • Fundamental failure relationships • Explanation of key parameters

Fracture propagation and arrest • Why fractures propagate • Brittle and ductile propagation • Fracture arrest • Calculating toughness requirements

DAY 2

DAY 3

How to assess corrosion defects • Introduction to basic theory • Background, strengths and weaknesses • Methods to assess corrosion • ASME B31.G and RSTRENG methods • DNV, BG, etc., methods • Interacting defects • Universal curves for assessing corrosion defects.

Pipeline repair and rehabilitation • Repair and rehabilitation strategy • Response to discovering defects • What are the cost implications? • Repair methods: grinding, weld deposition, sleeves, clamps, hot tapping, composite wraps • Time to repair

Workshop: corrosion assessment using fitness for purpose How to assess gouges • Introduction to basic theory • Methods to assess gouges • Additional problems and concerns with gouges How to assess dents • Introduction to basic theory • Methods to assess dents • Methods to assess dents containing gouges • Rock dents • Problems with fatigue loadings How to assess cracks • Basic theory • The problems with cracks in pipelines • Stress corrosion cracking (low and high ph) How to assess weld defects • Welds in pipelines • Assessing defects in pipeline girth welds

“Great Course... teacher Phil Hopkins very patient and knowledgeableexplained difficult concepts very well.”

“Excellent class, good blend of teaching and student participation” —M. Odigie Elf Petroleum Nigeria Limited

Risk and integrity management and analysis • What is risk and risk analysis? • Risk management around the world • Risk management in the USA • Risk management methods – API 1160 and ASME B31.8 • Baseline and direct assessment – discussion item • Integrity management programs • Prioritization schemes Workshop: setting priorities “I appreciated the instructor’s ability to answer technical, metallurgical questions..it’s critical that the person teaching the course is able to do this, to expand on the concepts discussed beyond the information presented in the slides. Phil did a great job of this.” “I thoroughly enjoyed the content and the presentation. Hats off to Prof. Hopkins” —A. Ellison Pipeline Integrity Coordinator Centurion Pipeline L.P.

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Pipeline Defect Assessment Workshop

The Pipeline Defects Clinic

including corrosion mechanisms and control

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his course is a follow-on to the famous Defect Assessment in Pipelines course. It takes those who want to take their defect assessment knowledge to the next level; it goes into greater depth on the various defect assessment methodologies and provides participants with hands-on practical experience performing calculations based on them. Participants will become comfortable performing and reviewing a wide variety of anomaly assessment methodologies and will understand when to best apply them within an Integrity Management Program. Cases and problems worked in class will be based on actual inspections of working pipeline systems. The course addresses both traditional pipeline methodologies as well as recent innovations, including the API 579 Fitness-for-Service Standard.

“Very good course, venue, and experienced speaker”

—Osaze Uwagboe, ExxonMobil

Who should attend? • Pipeline engineers • Designers and service professionals involved with the maintenance, inspection, and repair of pipelines.

Documentation and materials “Great course - a good refresher... very knowledgeable instructor”

—Lionel Blin, Société du Pipeline Sud-Européen

(LAPTOP REQUIRED) All presentation material will be documented in an Adobe Acrobat PDF provided by download prior to the class. For this reason it is necessary to bring your laptop or tablet computer. In addition participants will receive macro-enabled Excel spreadsheets that perform various calculations, including effective area metal loss assessment and pressure-cycle fatigue analysis.

Instructor Ian Smith is a consulting engineer with over 20 years in the pipeline industry. He formed his own consulting company in 2016 after having leadership roles within inline inspection, pipeline operating, and Fitness-forService consulting organizations. This has provided Ian with a unique perspective on the complete process of pipeline integrity from data collection to defect Fitness-for-Service assessment through to integrating assessment results into integrity management programs. He is a Professional Engineer and a member of ASME. Continuing Education Units: 1.4

Syllabus 1. Introduction to Pipeline Integrity a. The aging pipeline infrastructure. b. Common flaw types and failure mechanisms. c. Overview of inspection technology d. Overview of available assessment methodologies. e. Introduction to risk assessment. f. The ever-changing regulatory environment. 2. Assessment of Metal Loss a. The original and modified B31.G method. b. The RSTRENG effective area method. c. The API 579 Level 1 and Level 2 method. d. Comparison of B31.G, RSTENG, and API 579 e. Finite element analysis. f. Example problems (worked in class). 3. Assessment of Cracks a. Introduction to fracture mechanics b. The NG-18 equation. c. The API 579 failure assessment diagram (FAD) d. Finite element analysis e. Pressure cycle fatigue analysis f. Hydrostatic testing versus ILI as a means to address cracks g. Example problems (worked in class) 4. Assessment of Dents a. Rule-based assessment methodologies b. API 579 methods c. Finite element analysis d. Example problems (worked in class) 5. Interacting Anomalies a. Dents with wall loss b. Dents with cracks c. Wall loss + cracks

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his course examines how the manufacturing and corrosion defects identified by intelligent pigging may arise, and how they may develop. With a solid understanding of the ways in which these defects originate, course participants will be better equipped to characterize and prioritize them in review and analysis of inspection reports, and to minimize defects in the fabrication process. The course is a “linking” course between the Pigging & ILI course and the Pipeline Defect Assessment course.

Who should attend? • Engineers, designers, service professionals and pipe manufacturers who are involved with pipeline fabrication, inspection, and fitness-for-service assessments. • ILI data specialists. • Corrosion and materials specialists.

Course Program Day 1 • • • • •

Documentation All participants will receive a detailed set of lecture notes (400pp approx.) in ring binder format.

Lecturers Dr Michael Beller has more than 28 years’ experience in the pipeline inspection industry. Having served in both technical and management positions with Preussag Pipeline Services, Pipetronix, PII and NDT Systems & Services, he is currently Director of Corporate Strategy - Pipelines with Rosen Technology & Research Center in Karlsruhe, Germany. Michael holds a master’s degree in mechanical engineering, and obtained his PhD in fracture mechanics. He has been involved with a large number of inspection projects all around the world, including on- and offshore inspection work. Michael has considerable experience as a presenter and trainer, and in lecturing. He has authored more than 75 papers on the subject of pipeline inspection and intelligent pigging, and is also co-author of a German reference book on pigging technology. Currently, Michael serves on a number of Technical Committees and is also a member of the editorial board of The Journal of Pipeline Integrity. He is a former president of the Pipeline Products and Services Association. Dr Roger King has over 30 years experience of corrosion in the oil and gas, civil, and nuclear industries. He has specialist knowledge of sweet and sour corrosion and its prevention by chemical inhibition, monitoring of corrosion, microbiological corrosion and the design of efficient cathodic protection systems for flowlines, structures and seabed installations. He has been an independent consultant since September 1989, prior to which he was a founder member of the Corrosion and Protection Centre Industrial Service (CAPCIS) at the University of Manchester Institute of Science and Technology (UMIST). Continuing Education Units: 3.0

Creating a “virtual” pipeline Manufacturing defects in pipeline materials Testing for defects in the steel and pipe mill Construction defects NDT methods utilized during pipeline construction and commissioning; creation of the “virtual” pipeline

Day 2 • Internal corrosion in water injection pipelines • Overview of pipeline inspection techniques • Identification and sizing of metal loss defects in liquid pipelines • Corrosion Risk Assessment • Corrosion Risk Assessment of water pipelines • Internal corrosion in oil production pipelines

Day 3 • Identification and sizing of metal loss defects: resolution, accuracy and Special Issues • Corrosion Risk Assessment • Internal corrosion in gas production pipelines • Identification of metal loss defects in gas pipelines

Day 4 • Crack Detection in High Pressure Pipelines • Introducing Combo and Multi-Technology Inspection Tools • Corrosion Risk Assessment • External corrosion of onshore and offshore pipelines • Identification of defects in onshore and offshore pipelines • Verification of Inspection Results, Measurement Errors and Input for Integrity Assessment

Day 5 • • • •

Corrosion risk assessment of onshore pipelines Corrosion risk assessment of offshore pipelines Integrating defects into the “virtual” pipeline Inspection of Non-Piggable Pipelines

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Introduction to Excavation Inspection

Advanced Pipeline Risk Management

and Applied NDE for Pipeline Integrity Assessment

O “The course was an excellent overview of the tasks of a pipeline integrity engineer, reinforcing the confidence and intellect behind daily project decisions. It also provided a forum for recent developments in the industry, as well as share thoughts with others.” “Great topics and use of case studies and actual hands on NDE equipment…. Presenters were extremely knowledgeable and took the time to explain things. The hands on was great.”

—Brian Bruce

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N completion of the course, participants will have a solid understanding of the minimum requirements to ensure maximum correlation with ILI and Direct Assessment results during an excavation program. In addition, each participant will receive a general understanding of the available technology and procedures to implant contracts, increase quality, and reduce overall project costs. The course had been designed around the critical step of excavation inspection and documentation or, more recently termed by DA, as the ‘third step. Focus will be on the validation and correlation of both ILI results and/or Direct Assessment techniques through non-destructive testing in the excavation. Comprehensive course notes as well as reference material will be provided, a valuable guide for future applications. “The pig is wrong” is not often the case: “No anomalies found” is not enough information.

Who should attend? The course is specifically designed for project managers, engineers and technical personnel responsible for the management, implementation and reporting of pipeline integrity inspection activities.

Syllabus Importance of data collection and correlation • What / why information to collect. • Industry guidelines • General work flow • Reporting requirements Contract considerations for ILI and or DA vendors • Reporting format • Delectability tolerances • Sizing tolerances • Re-grading of the logs Contract considerations for NDT vendors • Qualifications • Available technology • Abilities and limitations NDT inspection techniques. • Procedure demonstration • Documentation Optimize NDT results with ILI or DAresults • Excavation location verification • Universal naming system for anomalies • Universal location and sizing system for anomalies • Reporting format What do you do if you don’t find an anomaly in the excavation • General procedures • ILI tool-specific procedures (MFL, UT, mechanical) Advanced NDT techniques and technology • Corrosion • SCC • Mechanical • ERW and girth welds Specialized excavations • Pre 1970 ERW • SCC soils modeling


Lecturers Jim Marr is President of Marr Associates Pipeline Integrity Ltd. Marr Associates has been in the pipeline integrity business since 1992. For the last eight years he was the SCC Program Planning Manager for TransCanada Pipelines. Jim has worked in pipeline integrity for the past 30 years, focusing on SCC, external corrosion, direct assessment, direct examination, ILI development and correlation, data management and integration and the characterization of the environment around the pipeline. He graduated with a degree in earth sciences in 1986 from the University of Guelph, Ontario. He is a member of NACE and a past vice-chair of the NACE SCCDA committee. Rick Desaulniers is currently Line Product Manager (Analysis) with Baker Hughes Management Group. He has been involved in the pipeline industry for the past 24 years in the Data Interpretation Department analyzing 1000’s of miles of pipelines around the world, specifically in Magnetic Flux Leakage type tools. He has been involved in past NACE conference as Chairman of the Pipeline Integrity Symposium and presented/ co-write papers on Excavation Data Collection and Data Analyst Qualification Processes. He was on the Standards Development Committee for ANSI/ASNT ILI-PQ-2005 In-Line Inspection Personnel Qualification and Certification Standard. He received his Bachelor of Science in Geology from McMaster University in Hamilton, Ontario.

From the National Transportation Safety Board Safety Study Integrity Management of Gas Transmission Pipelines in High Consequence Areas, January 27, 2015: “The study did find that IM programs... require expert knowledge and integration of multiple technical disciplines including... probability and statistics, and risk management.... The study found that aspects of the operators’ threat identification and risk assessment processes require improvement.” In 2017 PHMSA will implement a wide range of stricter regulations for improving pipeline safety. At the top of the list are these: • Requirements for conducting risk assessment for integrity management, including seismic risk. • Expanded mandatory data collection and integration requirements for integrity management, including data validation and seismicity. • Increased focus on a data- and risk-informed approach to safety by requiring integration of available data, including data on the operating environment, pipeline condition, and known manufacturing and construction defects. • Required annual evaluation of protective measures in High Consequence Areas, with established deadlines for internal inspections where possible for any new or replaced pipeline that could affect an HCA. Are you ready for these new rules? The Advanced Risk Management course will get you there.

Who should attend? Anyone requiring a general knowledge of pipeline risk concepts and how they can be practically integrated into pipeline operations, maintenance, design, or regulation.

Documentation Participants will receive a detailed set of course notes for reference after the course. Also included is the recently-published third edition of the definitive reference book, Pipeline Risk Management Manual, by W. Kent Muhlbauer, as well as a comprehensive course notebook for future reference.

Lecturer W. Kent Muhlbauer is a principal of WKM Consultancy and is the author of the widely-respected reference book Pipeline Risk Management Manual. Since it’s inception in 1994, WKM has been an advisor to government regulatory agencies and academia as well as the primary consultant in numerous pipeline technical projects for more than 50 clients, including many major US and international pipeline-operating companies. Continuing Education Units: 1.4

Course Program DAY 1 Introduction • Methodology quickview • Objectives of risk management • Gathering and effectively utilizing information • Using model results in decision-making Definitions • Risk assessment concepts • Tools • Methodology choices • Choosing the optimum approach • Data collection issues • A proposed methodology— the basic algorithm with assumptions • Customizing the methodology for specific applications • Sensitivity analyses • Databases and software issues • Tips and learning experiences in practicing risk assessment

“A good opportunity to learn and discuss new ways to think about risk.” —Charlie Childs, Kinder Morgan

“Very good presentation and overview of risk.” —Jan VYTRISAL SEPS, a.s.

“Great class, great instructor. Kent did a great job of providing and explaining the formulas.” —Shawnna Poor, Valero Corp.

“The course covered the risk assessment approach in a very comprehensive way.” —Alex Izadpanah

DAY 2 Risk management • Data analysis • Data-based decision making • Project prioritization based on risk assessments • Building a resource allocation model • Correlating relative risk scales with absolute risk

DAY 3 Administrative processes— ingredients for continued success • Administrative support structures • Data maintenance • Reporting • Procedures • Training • Performance measurements

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Introduction to In-Line Inspection of Pipelines

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HIS SPECIALIST COURSE provides an in-depth introduction to in-line inspection of pipelines, covering in detail the role that in-line inspection plays in the overall pipeline inspection and maintenance procedures. The course introduces the flaws and anomalies observed in pipelines. The tools used for in-line inspection, and the various physical principles they employ, are covered in depth. The course goes on to cover the details of pipeline inspection operations, including pipeline preparation, cleaning, and gauging. Final reports and their reporting formats are discussed, and the course also includes a short introduction to data analysis and run comparisons.

Who should attend? • Pipeline engineers, technicians and other operator personnel • Engineering consultants active in the field of NDT and integrity assessment • Personnel from the authorities, regulatory, and certification bodies involved with pipeline inspection and assessment.

Documentation Participants will receive a full set of the course notes and slides in ring-binder format.

Lecturers Dr Michael Beller (see opposite page) Dr. Konrad Reber studied physics and material science at the University of Mainz and Erlangen. For his Ph.D. thesis he worked on stray flux methods for the testing of magnetic materials. At Pipetronix he was responsible for the development of data analysis algorithms and the design of MFL-pigs. After moving to NDT Systems & Services AG in 2000, his focus changed to defect assessment and integrity management. Between 2006 and 2008 Konrad was with TÜV Rheinland as an expert within the Pipeline Technology Group. Since 2008 he has been head of research and development for the Innospection Group. His department is responsible for designing new inspection equipment for the oil and gas industry. His focus is on the development and refinement of testing technologies with applications for underwater and otherwise difficult-to-inspect structures.

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Course Program DAY 1 Flaws and defects in pipelines • Pipeline materials • Types of pipeline • Geometric anomalies • Metal loss • Cracks and crack-like defects • Leaks • Failure modes Pipeline inspection • Hydro- and stress testing • In-line inspection • External inspection Non-destructive testing and ILI • Magnetic-flux leakage tools • Ultrasonics • Inertia or mapping tools • Caliper tools ILI tools • Free-swimming in-line inspection tools • Tethered and cable operated tools • Overview of vendors

DAY 2 Pipeline inspection procedures • Planning an inspection • The technical questionnaire Preparing the pipeline for an inspection • Tool traps • Pipeline cleaning • Overview of caliper tools Performing the inspection • Batching, Tracking, Safety • Launching, receiving, etc. • Data check Reporting • Data evaluation • Sample report • Feature localization • Assessing inspection data • Introducing POF • MAOP • Run comparison • Data management and archiving The course also includes a workshop session and exercises covering the following topics: • Which tool does what? • How to read tool data and defect specific.sheets • Preparing an inspection project • Data analysis and MAOP

Advanced In-Line Inspection of Pipelines

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HE COURSE PROVIDES a broad introduction to the issue of pipeline inspection, to a level beyond the introductory course; it also covers aspects of external inspection as well as pipeline protection methods. The course further includes an introduction to pipeline materials, typical failure modes, flaws, and defects in pipelines; the subjects of corrosion and cracks are also covered. The syllabus includes an overview of in-line inspection technologies, although not covering the same aspects discussed in the introductory course. Here, the emphasis is on such issues as verification of ILI data provided by vendors in the final report, and assessment of data covering integrity assessment and fitness-for-purpose. Finally, the course discusses aspects of preparing a tender and evaluating a bid. The emphasis on bid evaluation is focused more on technical issues.

Who should attend? Pipeline engineers, corrosion engineers, integrity specialists, consultants active in the fields of pipeline inspection and assessment, personnel from certification and regulatory bodies involved with pipeline inspection and pipeline integrity.

Lecturers Dr. Michael Beller has more than 28 years’ experience in the pipeline inspection industry. Having served in both technical and management positions with Preussag Pipeline Services, Pipetronix, PII and NDT Systems & Services, he is currently Director of Corporate Strategy - Pipelines with Rosen Technology & Research Center in Karlsruhe, Germany. Michael holds a master’s degree in mechanical engineering, and obtained his PhD in fracture mechanics. He has been involved with a large number of inspection projects all around the world, including on- and offshore inspection work. Michael has considerable experience as a presenter and trainer, and in lecturing. He has authored more than 75 papers on the subject of pipeline inspection and intelligent pigging, and is also co-author of a German reference book on pigging technology. Currently, Michael serves on a number of Technical Committees and is also a member of the editorial board of The Journal of Pipeline Integrity. He is a former president of the Pipeline Products and Services Association. Dr Konrad Reber (see opposite page)

The course will include a workshop session with exercises based on the course material.



Course Program DAY 1 Inspection of special types of pipe • Types of special pipe in the oil and gas industry (clad pipe, flexible risers, martensitic pipe, etc.) • Inspection challenges and solutions Loading conditions and pipeline materials • Pipeline materials • Loading due to pressure • Secondary stresses • Implications for defect formation (indirect, direct flaws) Defects in the pipe wall and failure modes • Flaws and defects in pipeline • Plastic collapse and fracture • Corrosion and metal loss • Cracks and crack-like features CP and its inspection • CP systems • CP inspection methods

DAY 2 External inspection methods • Electromagnetic (SLOFEC, NoPig) • Ultrasonic (guided-wave, etc.) Overview of in-line inspection methods • Metal loss • Cracking • Mapping • Geometry tools • Leaks • Combo tools Verification of in-line inspection results • How to find a defect? • Verification methods (MP, TOFD, laser scanning) • Correlating to the ILI report Assessment of defects based on ILI • Methods (metal loss, cracks) • Implications of ILI measurement errors • Further conclusions Preparation of a tender and contract for ILI • How to prepare a tender • Critical information • Contractual issues • Understanding the vendor

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“The course was very informative. It was a great learning experience and look forward to future courses with Clarion.”

Stress-Corrosion Cracking in Pipelines

Microbiological Corrosion in Pipelines: Prevention, Detection, Mitigation

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LTHOUGH stress-corrosion cracking (SCC) is responsible for a very small percentage of pipeline failures each year, it continues to be a safety concern to pipeline operators, and it must be treated in integrity management plans. This course will provide a detailed description of what is known about its appearance and causes, and it will discuss various approaches to mitigating and managing the problem. Practical information on recognizing and dealing with SCC will be presented, along with descriptions of research results that have led to our current understanding of causes and methods of management.

Who should attend? “I was very impressed with the depth and quality of the information presented. The presentation was top notch. “

—B.C. Mittelstadt Senior Engineer El Paso Pipeline Services

“Thoroughly enjoyed the course. Was very applicable to my line of work! I felt the course was well balanced between theory and experience. It also left a lot of room for my own conclusions, thoughts, and approaches.”

—R. Lee Pipeline Integrity EIT TransCanada Pipelines Ltd.

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• Pipeline engineers, designers, and service professionals who are involved with the maintenance, inspection, and repair of pipelines • Researchers who want to be aware of the current understanding of SCC in pipelines

Documentation Participants will receive a full set of the course notes and slides in COLOR, in ring-binder format. Continuing Education Units: 1.4

Lecturers The course is taught by John Mackenzie based on materials developed by Dr. Raymond Fessler and Mr. Mackenzie. Dr Raymond R Fessler worked on the Pipeline Research Committee project on SCC since its inception in 1965. He personally conducted most of the early field investigations of SCC, from which he identified the major factors that cause high-pH SCC in pipelines. He also managed the laboratory portion of that program from 1965 to 1982, which added significantly to an understanding of the phenomenon, and explored a number of possible solutions to the problem. For the past several years, he has been the SCC consultant for GRI and PRCI. He recently completed a comprehensive gap analysis on SCC, and he actively participated in drafting the NACE Recommended Practice on SCC Direct Assessment.

John Mackenzie is a senior pipeline specialist with Kiefner & Associates, focusing on the areas of Integrity Management Plans and Stress-Corrosion Cracking. John is also President of NorthAm Energy Solutions Ltd, and CEO of Direct Assessment Partners LLP (DAP), both located in Bellingham, WA. DAP provides interactive databases for the capture and integration of pipeline dig-site data as well as training for field technicians. Prior to joining Kiefner & Associates, John was with TransCanada Pipelines for 25 years, where he was responsible for the company’s original investigation into SCC (1986-1990). This work led to the discovery of near-neutral pH SCC and identified the conditions under which it occurs. He also served as Chair of the PRCI’s SCC Subcommittee for two years.

Course Program DAY 1

DAY 2

Description of SCC • Definition, Causes, Appearance • Other forms of environmental-assisted cracking History of SCC in pipelines • High-pH SCC, Near-neutral-pH SCC, Internal SCC Stages of SCC • Pre-initiation, Initiation • Growth models • Early growth, Dormancy and re-initiation • Late growth • Final fracture Test techniques to study SCC • Accelerated testing • Electrochemical tests • Cracking tests, Measuring crack growth Environmental factors • Field observations • Liquid composition and concentration • Electrochemical potential, Temperature Stress factors • Field observations • Importance of strain rate • Cyclic loading • Sources of stress

Metallurgical factors • Pipe grade, Steel composition • Mechanical properties • Microstructure, Manufacturer Mechanisms of SCC • High-pH SCC, Near-neutral-pH SCC Likely locations for SCC • Geographical, Proximity to compressor or pump stations, Proximity to other SCC • Soil, terrain, moisture level • Gas versus liquid pipelines • Coating types and conditions • Pressure history, Corrosion history • Pipe manufacturer SCC detection and integrity assurance • B31.8S • Hydrostatic testing • In-line inspection, Direct assessment Mitigating SCC • Operating existing pipelines • Designing new pipelines, Repair methods Integrity management plans • Regulations, Approaches SCC Direct Assessment technology demonstration

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ICROBIOLOGICALLY-INFLUENCED corrosion (MIC) caused by sulfate-reducing bacteria has been found to be a serious threat to pipeline integrity, safety, and reliability. Numerous pipeline failures have been attributed to sustained, localized pitting corrosion. Bacterial colonies that can form in some pipelines will produce combinations of products that pit the metal. Preventing, detecting, and mitigating this type of pitting is often difficult and requires monitoring of the physical, chemical, and biological characteristics of the pipeline. This course will address these issues in detail, with particular emphasis on prediction and monitoring, and testing methods for managing MIC.

Who should attend? • Pipeline engineers, technicians, and service professionals who are involved with the maintenance, inspection, and repair of liquids, gas and products pipelines, storage tanks, and related components • Project and facility managers concerned with system integrity assessment • Researchers who want to be aware of the current understanding of MIC in pipelines


Lecturer Dr Roger King (see page 6)



DAY 2

Basics of Corrosion and Microbiology Sulfate-reducing bacteria (SRB) • Historical data • Occurrence • Mechanism

Predicting internal corrosion of pipelines by SRB • Pipelines at risk • Checklist for evaluation of risk of SRB corrosion • Limitations of growth and activity • Location of growth of SRB • Pipeline profile • Water cut • Product flow rate and water settlement • Effect of internal roughness • Re-population • Typical pipeline failure mechanisms

Ecosystems Corrosion by SRBs • Theory • Reservoir souring by SRB • Sources of the organisms • Reservoir cooling • Sulfide production • SRB corrosion and growth • Redox potentials • Checklist for evaluating sediments and soils Case histories • External corrosion and internal corrosion • Typical corrosion rates experienced • Operator methods used to prevent continued corrosion.

Monitoring and testing methods for SRB Control of SRB • Chemical treatment to control SRB • Biocide treatments in water systems • Biocide treatment of oil systems • Effectiveness of corrosion inhibitors • Use of pigging as an adjunct to chemical • Re-establishment of corrosion inhibitor films Prevention of external corrosion by SRB • Impact of SRB on coatings • Calcareous backfill in the pipeline trench • Cathodic protection • Consumption of sacrificial anodes by SRB in sour sediments • Options for protecting non-piggable pipelines • UV sterilization Internal inspection and defect assessment • Internal inspection methods for detecting MIC damage • Prioritizing inspection of pipeline networks • Assessing reported defects

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Pipeline Repair Methods, Hot Tapping, & In-Service Welding

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HE various aspects of pipeline repair using weld and non-weld methods will be covered, as will the concerns for welding onto in-service pipelines and the approaches used to address them.

Who should attend? Pipeline engineers, operations and maintenance personnel, inspectors, and welders. “Great Course! Bill Bruce did an excellent job. I look forward to future courses” —P. Kenny Welding Opeartions Lead National Grid

“Found the information on Procedure Development & Qualification very useful for practical application”

—C. Hartig Sr. Specialty Engineer Xcel High Pressure Gas

“Bill Bruce is an obvious expert on in-service welding. Confident delivery of presentation. I enjoyed learning from him.” —D. M. Halferty Plains All American, Pipeline Integrity Specialist

“Excellent course! This is a must attend for anyone involved in welding on in-service pipelines.” —Jonathan Spronk, Access Pipeline

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Documentation All delegates will receive a detailed set of lecture notes containing more than 250 pages, providing an invaluable reference document. Continuing Education Units: 1.7 (1.4 for the 2-day version)

Lecturers Bill Bruce is director of welding technology with DNV Columbus (formerly CC Technologies). Prior to joining CCT, he was a technology leader at Edison Welding Institute and a senior engineer at Panhandle Eastern Pipeline Co. He is a member of the American Petroleum Institute API 1104 Committee and is the chairman of the Maintenance Welding Subcommittee. Dr. Chris Alexander is a principal at Stress Engineering Services, Inc. He has been integrally involved in assessing the effects of dents and mechanical damage on the structural integrity of pipelines. Mr. Alexander has also been involved in assessing the use of composites in repairing pipelines and has published numerous papers and made international presentations on this subject.


Day 2

Defect assessment prior to repair • Reason for assessment • Types of pipeline defects • Pressure reduction requirements • Corrosion measurement methods • Corrosion assessment methods Selecting an appropriate repair method • Pipeline repair manual • Detailed selection criteria Burnthrough and related safety concerns • Factors affecting burnthrough • Effect of wall thickness • Effect of heat input • Effect of flow rate/pressure • Avoiding burnthrough Hydrogen cracking concerns • Recent significant incidents • Common factor/recommendation • Hydrogen cracking requirements • Welding metallurgy 101 • Prevention of hydrogen cracking Full encirclement repair sleeves • Full encirclement sleeve types • Principle of operation • Assuring effective reinforcement • Sleeve design • Sleeve fabrication Hot tap branch connections • Branch connection design • Reinforcement types • Integrally reinforced Pipeline repair by weld deposition • Physical concept • History of weld deposition repair • Burnthrough risk • Integrity restoration • Practical application

Non welded repairs • Repair by grinding • Composite repairs • Epoxy filled shells • Visit to testing facility for demonstration of repair methods and testing for qualification of repairs Code and regulatory requirements • Recent changes to API 1104 • Code requirements for weld deposition repair

DAY 3 Procedure selection for hot tap and repair sleeve welding • Burnthrough risk summary • Prevention of hydrogen cracking • Welding procedure options • Welder/procedure qualification • Predicting required heat input • Selecting an appropriate procedure Practical aspects of hot tap and repair sleeve welding • Proper electrode handling • Proper fitup • Proper welding sequence • Control of heat input levels • Inspection and testing Lessons to be learned from past pipeline repair incidents • Reported incidents • Previously unreported incidents • Ten commandments of inservice welding

Performing Pipeline Rehabilitation

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his course is centered on the practical aspects of pipeline rehabilitation and covers both internal and external rehabilitation. The course goes into depth on how to safely rehabilitate operating pipelines using manual and automated equipment. Movement of in-service pipelines is analyzed in detail including the application and methodology of recommended practice API 1117. Other industry standards applicable to pipeline rehabilitation are discussed as well as how they should be incorporated into project specifications. Approximately half of the course is spent in analyzing case studies of field rehabilitation projects from around the world. Over 400 photographs are used to illustrate how the work was performed and the results obtained. The course presents techniques for performing the work with a combination of in-house personnel and outside contractors to minimize costs while maintaining clear lines of responsibility.

Who should attend?

Lecturer

Field Operations Personnel and contractors who need to be aware of many alternatives techniques available for pipeline rehabilitation and their cost impact.

Sidney A Taylor is president of Incal Pipeline Rehabilitation, Inc. He has over 30 years’ experience in the design and development of automated highpressure water jet cleaning and coating systems. Prior to Incal, Sid worked with Schlumberger as a designer and manufacturer of well-logging tools and equipment, with MW Kellogg as a senior regulatory attorney, with Weatherford as general manager of water jetting systems, and with CRC-Evans as vice-president, engineering and marketing, where he was responsible for engineering design, manufacturing, and world-wide marketing of pipeline rehabilitation systems.

Inspection Personnel involved in evaluation of defects and selection of proper repair techniques.

Continuing Education Units 1.4

Engineers involved in: • Determining the best way to rehabilitate a section of pipeline, • Preparing the project specifications, • Performing the necessary engineering calculations to insure the project is carried out safely, • Health and safety issues specific to rehabilitation projects.

Documentation All delegates will receive a detailed set of lecture notes providing an invaluable reference document.

Course Program Day 1 Introduction Rehabilitation Options In-Plant Rehabilitation of Pipeline Out of the Ditch Rehabilitation Projects In-situ and Short Segment Rehabilitation Projects

Day 2 New Approach to In-Situ Rehabilitation Internal Pipeline Rehabilitation Projects Inspection of the pipeline Making necessary repairs Environmental Issues Industry Standards to be incorporated in Job Specifications

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Visit www.clarion.org for the complete program details

Pipeline Integrity Management

NEW PIPELINE REGULATIONS IMPACTS & GUIDELINES FOR COMPLIANCE

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he seminar provides a sound review of Pipeline Integrity Management strategies, in compliance with regulatory requirements, including self assessment. It is highly interactive and takes the form of lectures and case studies. On completion of the seminar, participants will have a solid understanding of the procedures, strengths, limitations, and applicability of the main issues that comprise a Pipeline Integrity Management Program.

“The course content is diversified and very beneficial. The instructor is knowledgeable and capable, and he made the course interesting.” —Mohammed Al-Qallaf, Saudi Aramco

“Pleasant, interactive, sincere and extremely knowledgeable are all qualities that help make an instructor good. Dr. Murray was great.” —Travis Hallam

The instructor was excellent. I like that he pushed us hard to maximize value.” —Olin Valby

Course Objectives To provide attendees with the latest techniques used to develop a comprehensive integrity management program covering both pipelines and their associated facilities. The necessary elements of such a program are described in detail with examples of typical program content including an overarching view of where detailed Risk Analysis and Defect Assessment fits in the Program.

Documentation The accompanying course notes, in ring-binder format, are written in such a manner as to provide a starting point for a company in either developing its own integrity management plan or updating its current plan. The course documentation also includes the newly published reference book Pipeline Integrity Assurance: A Practical Approach, by Alan Murray, Mo Mohitpour, Michael McManus, and Iain Colquhoun, a $159 value.

Who should attend? Supervisors, engineers and technicians responsible for ensuring the adequate protection of pipeline assets; maintenance planners, regulators and service-providers to the pipeline industry will also benefit from attending the course. On completion of this course you will be able to understand: • Codes used in developing Integrity Management Plans • The elements of an Integrity Management Plan • Threat assessment • Critical aspects of risk assessment. • Prevention and mitigation measures • Characteristics and limitations of different inspection methods • A risk- based approach to maintenance

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Continuing Education Units: 1.7 (1.4 for the 2-day version)

Lecturer Dr. Alan Murray is a consulting engineer with Principia Consulting in Calgary, AB. Prior to forming Principia in 2010, he was Chief Engineer at the Canadian National Energy Board. Dr. Murray’s industry experience has included a number of senior management positions with a large pipeline operating company in North America with responsibility for system planning, construction, maintenance and contracting functions. His 42 years of work experience spans research, regulation, third-party assessment, design and development in pipelines and offshore structures. He was the founding chairman of the ASME Pipeline Systems Division and is the co-author of the ASME Press text books Pipeline Design and Construction – A Practical Approach and Pipeline Integrity Assurance and is a Fellow of the ASME.

Course Program DAY 1 Introduction Elements of an Integrity Management Plan (IMP) Conducting an assessment Case study

DAY 2

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he course will bring you up to speed on these sweeping changes in the regulations affecting gas and hazardous liquids pipelines, expected in 2017: • Pipelines built before 1970 must now be tested. • New repair and replacement criteria for pipelines inside and outside of High Consequence Areas. • Tightened standards for pressure tests PHMSA guidance on how to evaluate internal inspection results to identify anomalies. • Requirements for conducting risk assessment for integrity management, including seismic risk. • Expanded mandatory data collection and integration requirements for integrity management, including data validation and seismicity. • Additional post-construction quality inspections to address coating integrity and cathodic protection issues. • Required new safety features for pipeline launchers and receivers. • Required systematic approach to verify MAOP and report exceedances. • Required leak-detection systems, and timelines for inspections of affected pipelines following an extreme weather event or natural disaster. • Required annual evaluation of protective measures in High Consequence Areas, with established deadlines for internal inspections where possible for any new or replaced pipeline that could affect an HCA. • Increased focus on a data- and risk-informed approach to safety by requiring integration of available data, including data on the operating environment, pipeline condition, and known manufacturing and construction defects.

Special attention will be given to requirements for Operator Qualification and Integrity Management Plans.

Who should attend? This course is designed for pipeline company personnel in regulatory compliance, operational, or engineering roles.

Documentation Participants will receive a detailed set of course notes in

PDF format for reference after the course.


Approaches to Risk Assessment Analysis Prevention and Mitigation Measures Inspection Methods: Characteristics and Limitations Case study

DAY 3 Integrity Management Plans for Facilities

Visit www.clarion.org for the complete program details

“Very focused, excellent presenters”

—Brandon Cox, Magellan Midstream Partners

“Great course, well presented”

—Peter Smith, Penspen Integrity

“The instructor had good knowledge and understanding of the codes...” —Jimmy Quintana, SPEC Services

Lecturers David E. Bull, ARM, is well known throughout the gas industry for outstanding training programs, development of the odorization audit and expertise in regulatory compliance, and evaluating damageprevention programs. His experience includes risk assessments for over 75 gas utilities for AEGIS Insurance Services, membership on the Damage Prevention Quality Action Team (Dig Safely), and as a staff member at the Transportation Safety Institute, Pipeline Division. David has over 30 years’ experience helping pipeline operators to assess and manage their risk and liability exposures. He is also a principal in ViaData LP, publisher of WinD.O.T., The Pipeline Safety Encyclopedia. George Williamson is currently Segment Engineering Technical Authority – Inspection, for the Upstream Global Projects group within BP. He has more than 25 years of Operations, Maintenance and Integrity Management experience. He is a registered professional engineer, NACE certified corrosion and a cathodic protection specialist. He has managed compliance and integrity programs for production facilities, gathering systems, liquid and gas transmission pipelines.

“A very good introduction to the gas and liquids regulations”

—Margaret Schafer, Colonial Pipeline

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Subsea Pipeline Engineering

Course Program

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HE COURSE will provide a complete and up-to-date overview of the area of subsea pipeline engineering, taking delegates through the pre-design phase, design, construction, installation, operation and maintenance. It will give a complete picture of the work of design engineers and pipeline construction companies, using actual case studies from around the world to highlight the topics discussed. While the course requires no previous experience, this is not a superficial overview. The lecturers are experts in their fields and have vast experience in lecturing on the subject of subsea pipeline engineering. Places will be strictly limited to ensure maximum individual attention.

“Excellent course which delivers technical backgrounds required for pipeline project management as advertised.”

—G. Wiechers Acergy Group

“This was a very informative and thorough course, covering not just theoretical aspects of pipeline design and installation but also practical examples of various techniques.”

—Mohammad Haider, BP

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Who should attend? Engineers from oil and gas companies, construction companies, pipe and service suppliers, and regulatory authorities, who are newly qualified, have recently moved into pipeline engineering, or hold broad responsibilities that include pipelines.

Documentation Participants receive a sturdy ring binder containing more than 700 pages in COLOR, plus the 650-page reference book Subsea Pipeline Engineering by Andrew Palmer and Roger King.

Lecturers Professor Andrew Palmer is a consulting engineer. He retired in September 2005 as the Jafar Research Professor of Petroleum Engineering at Cambridge University, UK. Professor Palmer is a Fellow of the Royal Society, a Fellow of the Royal Academy of Engineering, and a Fellow of the Institution of Civil Engineers. He has been engaged in marine pipeline engineering for 35 years. He has taken a leading part in many pipeline projects in the North Sea, the Middle East, Canada, and the Far East, and is active as an expert witness. He is the author of more than 170 published papers on pipeline engineering, structures and geotechnics, of a book on structural mechanics, and with Dr Roger King of the new reference book, Subsea Pipeline Engineering. Dr Roger King has over 30 years’ experience of corrosion in the oil, gas, civil, and nuclear industries. He has specialist knowledge of sweet and sour corrosion and its prevention by chemical inhibition, monitoring of corrosion, microbiological corrosion, and the design of efficient cathodic-protection systems for flowlines, structures, and seabed installations. He has been an independent consultant since September, 1989, and prior to this was a founder member of the Corrosion and Protection Centre Industrial Service (CAPCIS) at the University of Manchester Institute of Science and Technology (UMIST).


R. J. “Bob” Brown has over 46 years’ experience in the offshore pipeline industry. Among his many awards and recognitions, he has received the OTC Heritage, ASCE Stephen D. Bechtel, and “Pipeliner of the Year” Awards for his outstanding contributions to the oil and gas industry. Bob is currently director of RJ Brown Deepwater, Inc., which is part of the Technip Offshore Group, who is playing an important role in the development of pipeline installations for offshore energy projects. (Lectures on the US course only.) Michael Coyne has worked for Shell Oil Company for 29 years. He has worked mainly in the Transportation organization in the construction and operations sides of the pipeline business. Mike has also had two assignments in the E&P organization within Shell. He has an undergraduate degree from the University of Virginia in Mechanical Engineering and a graduate degree from the University of New Orleans also in Mechanical Engineering. Mike’s current assignment is Manager for the Offshore Projects Group in Shell Pipe Line where he supervises a group of engineers working on an assortment of export pipeline related projects in the Gulf of Mexico and Louisiana. Brian McShane has 19 years of experience in the engineering, construction and project management of subsea pipelines and field developments within the oil and gas industry. Currently, he is Vice President of INTECSEA’s Marine Pipeline Systems department. Brian has a broad range of experience in subsea pipeline and riser consultancy and design including arctic, deepwater and high pressure/high temperature pipeline systems. Recent project experience has included leadership of INTECSEA teams for the Neptune Suez LNG Offloading port in Massachusetts and also BP’s Mardi Gras large diameter deepwater transmission system in the Gulf of Mexico.

DAY1 (USA syllabus is shown: the program will be modified when offered in the UK) System configuration Route selection • Principles of route selection • Constraints imposed by oceanographic, geotechnical, environmental, safety and political factors • Case studies from Canada, Spain, England Shore approaches • Influence of coastal topography, geotechnics tides andwaves • Alternative construction techniques • Horizontal drilling and tunnels • Case studies

DAY 2 Materials selection • Fabrication of API pipe • Increasing the strength of pipeline steel • Balancing strength, toughness and weldability Hydraulics and flow assurance • Single-phase flow, oil and gas • Pressure drop and effect on optimal line size • Influence of compressibility, temperature change Increasing corrosion resistance • Increasing the corrosion resistance of carbon steels • Limitations of use of solid corrosion resistant alloys • Internally clad pipe • Flexible pipe Design for strength • Internal pressure, code requirements • External pressure; bending; bending buckling; collapse and buckle propagation; denting and gouging; allowable strain design; impact damage Lateral and upheaval buckling • Driving force for upheaval and lateral buckling • Analysis of risk buckling • Alternative design and construction options • Case studies Materials for sour service • Pipeline steels for sour service: sulfide stress cracking and HIC • Appropriate specification of pipe material Microbiological corrosion • Sulphate-reducing bacteria • Microbiological corrosion mechanisms • Evaluation of the problem • Housekeeping and treatment

DAY 3 Case study: Thunder Horse Internal corrosion • Sweet corrosion mechanisms • Evaluating a suitable corrosion allowance • Effects of flow on corrosion • Moderators of corrosion • Corrosion inhibition and flow morphology

External corrosion and coatings • Coating for submarine pipelines • Inspection of coating integrity • Concrete weight coatings • Field joints and infills Cathodic protection • Mechanism of CP • Design of sacrificial anode CP systems • Thermal effects on CP performance • Interactions between CP systems Design for stability • Hydrodynamic forces: steady & unsteady flow • Lateral resistance • Design for stability - RPE305 • Interaction with seabed instability Environmental design criteria • Design currents • Waves • Geotechnics and earthquakes Trenching and burial • Trenching and burial methods, jetting, mechanical cutting, ploughing, etc. • Case studies

“This was an excellent overview course with a good blend of technical and practical knowledge.”

DAY 4 Mishaps, risk, and repair • Safety of marine pipeline systems • Case studies of failures • Quantitative risk assessment & acceptable risk • Integrity management Case study: Mardi Gras Design exercise

DAY 5 Construction • Laybarge, S-Lay and J-Lay • Reelship • Mid-depth tow, bottom tow and surface tow • Pros and cons of different methods • Alternative contracting strategies Spans • Span occurrence and possible systems • Vortex-excited oscillation, overstress, hooking • Span monitoring and correction Welding • Welding of carbon manganese pipeline steels • Welding of duplex and clad pipe • Inspection of weldments Codes • Design codes • Trends in code development • Limit-state designs • API RP1111 and DnV 101 Decommissioning • Legislation • Decay mechanisms • Methods of recovery • Alternatives to recovery • Disposal materials • Costs

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Subsea Production Systems Engineering

Deepwater Riser Engineering

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HIS course provides an overview of the key processes, technologies and equipment that comprise contemporary subsea production developments. It also provides experienced-based details of actual projects, from the drilling of the well to bringing the system into production. The course focuses on how subsea hardware, pipelines, riser systems, and other equipment relate to design philosophies, and how to establish a basis for subsea production system design. Lectures, devoted to system development issues, will be complemented by a plant tour to establish familiarity with specific hardware items, as well interactive design exercises in class.

“Excellent course, learned a lot in a short time. Strongly recommend to subsea or aspiring subsea engineers.”

—T. Kissoonsingh BPTT “

Just right - an excellent overview.” —Mark Susich, BP

“All of the presenters were very knowledgeable about their topics. Great course. Lots of really good information for an engineer new to this field.” —Anon.

“Excellent course! Would strongly advise other industry personnel to attend.” —Jeff Swain, Husky Energy

“Overall, a very good class, with a unique angle…very much needed.”

—Anon.

32 “Very Interesting and enjoyable course.”

—D. Davies Technical Director NDE Technical Services GmbH

Who should attend? • Project managers who want to know more about the technology they are directing • Project engineers who specialize in a specific area, but need to know about how other technologies interface with their own • Engineers from other disciplines who are moving into the subsea area • Newly qualified engineers who just coming into the offshore industry

Documentation Course participants receive a all lecture slides and reference materials in a ring binder. Continuing Education Units: 2.5

Summary syllabus - 4 days For the complete syllabus, visit www.clarion.org • Concept selection interfaces: the keys to an integrated subsea system • Various perspectives on the “system” • The components of a subsea production system • Production system compatibility • Management of interfaces • Field development options • Economic and risk variations • Economic decision-making: the factors • Cost vs schedule vs quality • Economic decisions: different results from different operators • Establishing field architecture: • Drilling, completion, and production • Reservoir, bathymetry, and geohazard considerations • Flow assurance considerations • Host facility, mooring, and metocean drivers • Flowlines and risers • Myths and legends: why equipment is designed the way it is • Equipment selection - trees and jumper systems • Equipment selection - controls and umbilicals • High pressure and temperature (HP/HT) designs • New technology • Subsea engineering practice - case studies “Really fit my initial needs. Very knowledgeable course lectures that have real world experience.” —J. N. Lauterbach Technical QA/QC Manager NDE Quality Systems, Inc.

Lecturers David Fudge has a 30-year career in control engineering, including 20-years’ experience of management and system engineering of diver/diverless subsea field developments, embracing conceptual design through to field commissioning, including operations and intervention with a core specialization in subsea control systems and umbilicals. He is presently with Subsea Control Services, London, and Deepwater Technology Co, Houston. Tommy Golczynski has 16 years of experience in the upstream and downstream oil and gas industry, and is a Principal and Director at Assured Flow Solutions in Houston. Prior to forming the company, he served as Vice President with Multiphase Solutions (now Msi Kenny), where he managed the flow-assurance department and was responsible for technical and commercial aspects of all projects. Tommy provides technical support on flow assurance issues, in particular, a wide range of thermal and hydraulic, transient, multiphase flow analyses. Projects range from early conceptual to detailed FEED studies, as well as development of guidelines and flow assurance specifications for successful field operations. Bil Loth has 40 years’ experience in design, engineering, and management of subsea development projects. His career has included positions with Esso Production Research (now Exxon Upstream Research), Exxon USA, Esso Europe, and Shell Expro Central Engineering, where as head of subsea engineering he was responsible for prospect evaluation and front-end engineering for all subsea developments, including Osprey and Gannet. In 2001 ExxonMobil Development Co assigned Bil as the lead engineer for its Erha subsea systems concept selection and design. Steve Sasanow has been editor of Subsea Engineering News since its birth in 1984. In addition to being one of the leading offshore technology writers (he has contributed to almost every offshore magazine in print) Steve has carried out consultancy work for many of the leading companies. Ruxin Song (see page 34) Bobby Voss has 35 years’ experience in design engineering of subsea production systems. He has served in several technical positions starting with Vetco Offshore and continuing with ABB VetcoGray and now GE Oil and Gas. Bobby has performed the Project Engineer role on multiple subsea production systems located around the globe, and had worked out of Houston, Ventura California, Rio de Janerio, and Aberdeen. His previous assignments have also included subsea bid technical manager, subsea product line manager, and R&D director for Subsea production. Bobby is currently the GE Chief Consulting Engineer for subsea trees and intervention systems.

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HE COURSE PROVIDES an overview of marine risers focusing on deepwater application from material selection to offshore installation. Detailed lectures cover design and analysis methods with particular attention to top-tensioned risers (TTR) and steel-cantenary risers (SCR), and go on to review and compare riser design codes and industrial standards; field applications are discussed throughout the lecture program.

Who should attend? • Engineers from oil companies, engineering service companies, construction companies, pipe and service suppliers and regulatory authorities, who are newly qualified, have recently moved into riser engineering or hold broad responsibilities that include risers. The course is especially suitable to those who wish to broaden their knowledge of deepwater riser engineering or deepen their technical understanding of specific riser types. In particular: • Newly qualified riser engineers (designers and analysts) • Experienced riser project engineers who want to expand their knowledge • Sub-project managers (of subsea contractors including risers) • Subsea supervisors / managers • MSc students in offshore engineering

Documentation Participants receive a sturdy ring binder containing all the lecture slides with notes and illustrations supporting the lectures. Continuing Education Units: 3.0

Lecturers

“Enjoyed the course. The presenters cared and did a great job... lots of good history/ mitigations/ problems/ lessons learned. The information is very valuable.”

Erin Balch is a senior specialist at MCS Kenny with broad engineering experience of floating production riser and mooring systems. She has considerable experience in the specification, design, verification, installation, and integrity management of floating production risers. She has worked extensively in flexible risers, umbilicals and drilling risers, and has a keen understanding of the design, manufacturing, and testing challenges associated with these risers. Before working for MCS, she gained valuable experience in the design of —Travis Wallace, floating production mooring systems Wood Group Kenny Enrique Banda is a Senior Specialist with MCS Kenny and has extensive experience in SCR design, drilling riser analysis, top tensioned riser analysis, and hybrid riser “Excellent course. analysis. Key projects include Independence Hub SCR The presenters design, Perdido Riser Deisgn verification and Cascadeare top class.” Chinook hybrid riser verification. Mr. Banda is currently —Ehsan Heshmati, Det Norske Veritas a Riser Lead in the MCS Kenny Houston riser group. AS Dr. Kenneth Bhalla is currently a Principal with Stress Engineering Services, Inc., working primarily in the Floating Systems Practice supporting drilling riser, completion and intervention riser services and operation. He has more than 20 years of industry experience. Patrick Boster is president of RTI Energy Systems, a supplier of production riser systems and engineering solutions such as subsea tiebacks utilizing tapered stress joints of both steel and titanium. Prior to joining RTIES, Patrick worked for ABB as manager of the materials and welding group, and then started his own company, Weld-Tech Engineering, supplying materials technology, manufacturing, welding and related services. Weld-Tech was acquired by RTI International Metals in 1998. Early Denison is a consulting engineer with 42 years’ experience in the oil and gas industry, 33 of which focused on deepwater riser system design, analysis, fabrication, and operation. He retired from Shell in 1999. Dave Madden, is Technical Operations Manager with DUCO, Inc. in Houston, where he oversees engineering activities relating to product design and manufacture on current projects and future prospects. He has more than 28 years’ experience in subsea umbilical project 33 engineering, management and product design. He was involved in many of the early subsea developments in the North Sea, and he worked for more than three years at the Technip center for product development in Le Trait (France), where he was responsible for umbilical R&D activities within the group. David is a member of the Technip “group of experts” and currently participates in the API17E working group who are editing the joint API17E/ISO13628-5 Subsea Umbilical Specification for the industry. continued on page 34

Deepwater Riser Engineering (continued from page 33) Dr Ruxin Song has more than 15 years’ experience inrisers and pipelines. He has been the lead engineer for some large well-known riser and pipeline projects in North Sea , Gulf of Mexico, and offshore Brazil, including the EMDC Kizomba Tower riser, Statoil’s Gullfaks pipeline and riser bundles, BP’s Thunder Horse risers, and Petrobras’ Roncador risers. Ruxin has published 30 technical papers in international journals and conferences, and been actively involved in design code development. Currently Ruxin is a principal associate in the riser technology department of Genesis Oil & Gas Consultants, Houston. Dr Paul N. Stanton is vice president of the riser technology and well systems department of Genesis Oil & Gas Consultants, Houston. He has 36 years of experience in deepwater floating drilling research and engineering, subsea production research, TLP and Spar well systems’ research and development, and riser engineering management. Paul is active in development of API and ISO standards for dynamic riser systems.

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Summary syllabus - Days 1-5 For the complete syllabus, visit www.clarion.org • Overview • Fundamentals of riser engineering • Design codes and regulations • Top tensioned risers • Hybrid riser systems • Steel catenary risers • Flexible risers Drilling risers • Riser design methods overview • Riser system analytical tools • Functional requirements and design drivers • Design basis development • TTR analysis and design methods • Hybrid riser analysis and design methods • TTR component design • Flexible riser analysis and design methods Umbilicals • SCR analysis and design methods • SCR component design • Materials selection • Fabrication, welding, and NDE • Installation design • Group design exercise - interactive • Deepwater riser projects and lessons learned • Project histories (from invited operator representatives)

Engineering for Arctic Environments

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HE ARCTIC REGIONS have enormous resources of oil, gas, minerals and fish. They are politically, strategically and economically important to the all the circumpolar countries and to the world as a whole. They are also environmentally and socially sensitive, and any development requires a careful balance between the interests of outside investors, the local communities, the indigenous peoples, the regulatory environment and the natural environment. The objective of this course is to be an introduction to Arctic engineering, most in the context of the production and transportation of oil and gas, but at the same time considering broader infrastructure. The course is not merely a ‘familiarization’ course with no technical content; but it will instead examine recent developments in critical technical areas such as ice mechanics, permafrost, ships in ice, and codes, in particular the recently-published ISO 19906. The course will be illustrated by the lecturers’ experience of completed projects and case studies in many parts of the world, among them the Canadian and Alaskan Arctic, Sakhalin and Kazakhstan.

Who should attend? Most of the participants are expected to be engineers engaged with current or future projects in the Arctic regions, concerned with broad planning, conceptual design, and detailed engineering. The course will also be relevant to people who are not engineers but want to understand what engineers are planning, among them public officials, regulators, specialists in the environment, lawyers and potential investors.

Lecturers Dr. Roger Basu is a structural engineer with more than 35 years’ experience. Before joining ABS in 1997, where he is currently Director of Research & Development, he worked in Canada for a naval architectural firm on ship design projects. He leads the harsh environment technology program in ABS, the main objective of which is to develop state-of-the-art methodologies and tools for the assessment of ships and offshore structures in ice covered waters. Dr. Basu holds a Ph.D. in structural engineering from the University of Western Ontario, London, Canada where he worked on wind effects on structures. Dr. Ken Been is a Principal with Golder Associates in Houston. He played a leading role in investigation, design and construction in support of offshore exploration in the Canadian and Alaskan Beaufort Sea in the 1980s, including pipelines, sand and gravel islands, hybrid structures and spray ice islands. Dr. Been has been involved in design of offshore pipelines (mainly in ice environments) since 1989, most recently including projects off Sakhalin island and in the Caspian Sea. After graduating with a B.Sc. degree in civil engineering from the University of Cape Town, Dr. Been obtained a Ph.D from the University of Oxford where he was a Rhodes Scholar. He is Chairman of the Technical Committee for CSA S472 – Foundations for Offshore Structures and has contributed to the draft ISO Standard for Arctic Offshore Structures. Ken Croasdale been active since 1969 in developing the technology for offshore oil and gas operations in arctic environments. He spent 18 years with Imperial Oil managing their Frontier Technology Group and several years with Dome Petroleum and Petro Canada when they were active in the Beaufort Sea and East Coast Canada. He has specialized in ice interaction with offshore platforms. The experience gained in

Canada has been applied to the Russian and Kazhakstan Offshore. He advised Public Works Canada on ice issues and ice loads on the Confederation Bridge. He is currently President of K.R. Croasdale & Associates. Mr. Croasdale has authored more than 80 technical papers on Arctic & offshore technology. Glenn A. Lanan is a Marine Pipeline System Technical Advisor for INTECSEA/Worley Parsons Group in Houston, Texas. Mr. Lanan has more than 33 years of experience with the design and construction of offshore pipelines and related facilities. His career focus has been on specialized pipeline applications such as deep water, environmentally sensitive areas, and marine pipelines with other technical and economic challenges. He has participated in all phases of international offshore Arctic pipeline engineering projects, starting in 1980. Career highlights for offshore Arctic pipelines include serving as INTECSEA’s Project Manager for the BP Alaska Northstar pipeline project, the Sakhalin 1 De-Kastri terminal subsea loading line, Pioneer Natural Resources’ Oooguruk offshore Arctic flowlines, the Eni Nikaitchuq Beaufort Sea flowlines and multiple offshore Arctic pipeline studies. He is presently working on a major pipeline FEED project in the Northern Caspian Sea. Professor Andrew Palmer is currently Keppel Chair Professor in the Centre for Offshore Research and Engineering of the Department of Civil Engineering at the National University of Singapore. He has divided his career equally between practice as a consulting engineer and university teaching. In 1985 he founded Andrew Palmer & Associates, a company of consulting engineers who specialize in marine pipelines. In 1996, Professor Palmer returned to research and university teaching as Research Professor of Petroleum Engineering at Cambridge University in the UK. He was a Visiting Professor in the Division of Engineering and Applied Sciences at Harvard University from 2002 to 2003. Professor Palmer is a Fellow of the Royal Society, a Fellow of the Royal Academy of Engineering, a Fellow of the Institution of Civil Engineers, and current chairman of the DNV Pipelines Committee. He has been engaged in marine pipeline engineering for 39 years and has taken a leading part in many pipeline projects in the North Sea, the Middle East, Canada and the Far East. Professor Palmer is the author of three books and more than 180 published papers on pipeline engineering, structures and geotechnics, including the textbook Subsea Pipeline Engineering, which was co-authored with Dr. Roger King. Continuing Education Units: 2.5

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API Recommended Practice 1173 Pipeline Safety Management System Requirements

R “Excellent course; very helpful summary of the RP, especially the sections on history and how to comply.” – Jake Murray

“The instructor was excellent with relative experiences and stories.” – Gary Peterson

ecent incidents in the pipeline industry have led to recommendations for pipeline operators to adapt safety management systems as a means of targeting a zero incidents goal. American Petroleum Institute (API) Recommended Practice (RP) 1173 – Pipeline Safety Management System Requirements is a result of a substantial effort by the pipeline industry to provide guidance for the development and maintenance of a pipeline safety management system. The result of this effort, API RP 1173, which is set to be released at the end of 2014, has been supported by the regulatory agencies and has been developed with input gathered from two workshops in 2014, as well as a public hearing. This course is designed to provide attendees with an overview of API RP 1173 and an understanding of safety management systems. By understanding the requirements to develop and maintain a safety management system, participants will learn about how a safety management system can help them towards the industry-wide goal of zero incidents. By understanding safety management systems, participants will gain an understanding as to how activities such as pipeline design, operations, maintenance, and inspections are managed and linked together as processes within the safety management system.

Target Audience This course is designed for individuals that require a detailed understanding of management system concepts and, more specifically, an understanding of how to develop and implement a safety management system that meets the intent of API RP 1173. The course will be structured to be relevant for both practicing management system practitioners and beginning management system practitioners.

Course Objective After attending the course, attendees will have the necessary knowledge and tools to develop a safety management system or strengthen their existing safety management system according to the guidelines of API 1173.

Course Overview

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This course will start with a basic introduction to management systems. Objectives, content, and key concepts, including the need for continuous improvement based on the Plan, Do, Check, Act (PDCA) approach, will be discussed. This will be followed by the establishment of a safety management system that fully meets the intent of API 1173, including a life cycle approach to risk management and the integration of existing integrity management programs. The course will include in some details on key components of the system and, in particular, risk management, integrity management, management of change, and safety culture. The emphasis of the course will be somewhat flexible and, as much as possible, be tailored to the actual needs of the course attendees. The course presenter will share their actual experience whereby cost effective and practical management systems have been developed and implemented for pipeline operators. Continuing Education Units: 1.4

Lecturers Ray Davies has 30 years plus experience working in the Oil and Gas Industry in combining the technical, risk and system issues related to the development, implementation and assessment of management systems and programs for operations, mechanical integrity, safety, environment and quality. He has a grounding in technical issues including metallurgical engineering, corrosion, non destructive testing and risk based decision making coupled with a broad management systems experience covering all operational aspects of facilities and pipelines. Mr. Davies is co-author of a management systems book “Safety and the Bottom Line” and was presenter for a series of pipeline web casts organized by the Southern Gas Association in the USA and covering Quality Assurance, Management of Change and Performance Measurement aspects of the gas pipeline standard, ASME B31.8.S. Megan Weichel provides risk management and management system development assistance to clients in the process and pipeline sectors of the Oil & Gas Industry. Her daily activities include performing third party audits of client management systems, including HSE, PSM, and Integrity Management, for compliance with regulations and conformance with internal corporate standards. She also consults with clients to assist them in closing gaps in their management systems and to improve the quality and effectiveness of the system using best engineering practice and industry knowledge.

Course topics • • • • • • • •

Development of API RP 1173 What does API RP 1173 address? Why Safety Management Systems as a solution? How does API RP 1173 compare to existing standards or initiatives? How is API RP 1173 structured? What is required for each elements in API RP 1173 What is a safety culture? How to comply with API RP 1173?

The Pipeline Integrity Master Class

O

ver the last 15 years Clarion-Tiratsoo Technical, Penspen and others have educated thousands of pipeline engineers in the essential tools and methods of pipeline integrity assessment. While there continues to be a need for these training courses, more-experienced engineers, who may have risen to senior technical-management positions, need a ‘next-level’ course that will focus on more complex, sophisticated and nuanced issues - not just in the application of PIM technologies and methods, but in the real management of the asset from a risk and business point of view. That is the objective of The Pipeline Integrity Master Class to be offered for the first time in 2012 in the UK and the USA. The five-day syllabus content will be flexible to match the particular needs and interests of each group of class participants, who will receive a questionnaire in advance of the class. Led by a world-class team of instructors, it will be heavy on group problem-solving exercises and case study analysis and will also feature guest lectures from senior operating-company executives and technical specialists. To facilitate and optimize interaction between participants and instructors, and among the participants themselves, the course will take place at excellent-quality conference centers offering residential accommodation: in the USA,The Woodlands Resort & Conference Center near Houston; in the UK, the Low Wood Bay Hotel on Lake Windermere, near Ambleside in the Lakes District of England. To obtain the full benefits of the class, participants are urged to book in at the class venue for the duration, as discussions and activities will continue into the evenings.

Recommended experience It is strongly recommended that class participants have at least five years’ experience in pipeline integrity management and a minimum of 120 hours instruction in relevant professional courses.

Documentation

Who should attend? The class is recommended for technical team leaders, asset managers, integrity managers, chief engineers, engineering VPs or other experienced personnel who meet the recommended prerequisite criteria above. Continuing Education Units: 3.0

Included with the course fee is a detailed set of lecture notes (600 pages est., COLOR) and a CD containing an additional reference material.

Faculty Dr Jane Haswell is a principal consulting engineer with Pipeline Integrity Engineers in the UK, which she joined in 2001. Prior to this, she had over 20 years’ experience in pipeline transmission engineering, initially involved in pipework / pipeline stress analysis and 3-D FEA for British Gas. She then became responsible for managing a team of specialist engineers, covering defect assessment, stress analysis, and technical input into developing Codes such as IGE/ TD/, TD/12, and BSI PD 6493. Subsequently, she became divisional manager for British Gas’ Engineering Sciences group, with responsibility for 55 engineers. Dr. Phil Hopkins is a consulting engineer with more than 35 years’ experience in pipeline engineering. Phil formed his consultancy company in 2015, after being Technical Director with Penspen Ltd in the UK, and previously Managing Director of Andrew Palmer and Associates, in the UK. He has worked with most of the major oil and gas companies and pipeline companies around the world, providing consultancy on management, business, design, maintenance, inspection, risk analysis and safety, and failure investigations. He is the past-chairman of the ASME Pipeline Systems Division, and is a Fellow of ASME. More than 15,000 engineers and technical personnel around the world have attended his courses. He also teaches extensively on masters’ programmes at Newcastle and Northumbria Universities in the UK.

Dr. Alan Murray is a consulting engineer with Principia Consulting in Calgary, AB. Prior to forming Principia in 2010, he was Chief Engineer at the Canadian National Energy Board. Dr. Murray’s industry experience has included a number of senior management positions with a large pipeline operating company in North America with responsibility for system planning, construction, maintenance and contracting functions. His 42 years of work experience spans research, regulation, third-party assessment, design and development in pipelines and offshore structures. He was the founding chairman of the ASME Pipeline Systems Division and is the co-author of the ASME Press text books Pipeline Design and Construction – A Practical Approach and Pipeline Integrity Assurance and is a Fellow of the ASME. Patrick Vieth is President of Dynamic Risk USA, Inc. Pat has 27 years’ experience in management, research, and technical innovation within the pipeline industry. Some of his accomplishments have provided the foundation to modern pipeline integrity, such as his key contributions to validation and implementation of the RSTRENG corrosion assessment method and development of a Transverse Field Inspection (TFI) program to identify longitudinal seam weld defects.

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Index of courses by topic

(Note: courses are arranged alphabetically in each category, and numbers refer to page numbers in this catalogue)

Advanced Pipeline Risk Management.................................................................... 21 API Recommended Practice 1173: Pipeline Safety Management System Requirements............................................36

Arctic Engineering

Internal Inspection

Engineering for Arctic Environments....................... 35

Defect Assessment in Pipelines............................16-17 Hydrostatic Testing of Pipelines.................................. 6

Deepwater Riser Engineering............................................................................33-34

Inline Inspection of Pipelines.............................. 22, 23 New! Inspection of Challenging Pipelines.................. 4 Inspection of Offshore Pipelines and Structures..... 10 Introduction to Excavation Inspection & Applied NDE for Pipeline Integrity Assessment............... 20 Managing Cracks and Seam Weld Anomalies on Pipelines.................................................................. 5 Pipeline Defect Assessment Workshop..................... 18 The Pipeline Defects Clinic........................................ 19 Pipeline Pigging and In-line Inspection.................... 14 Practical Pigging Operations..................................... 15

Geohazard Management for Pipeline Engineers.................................................. 11

Offshore Operations & Systems

Managing Cracks and Seam Weld Anomalies on Pipelines...................................5

Deepwater Riser Engineering...............................33-34 Inspection of offshore pipelines and structures....... 10 Subsea Pipeline Engineering.................................30-31 Subsea Production Systems Engineering.................. 32

Microbiological Corrosion in Pipelines: Prevention, Detection, Mitigation......25

Regulations

Performing Pipeline Rehabilitation.......................................................................27

Cleaning, Commissioning, & Operations Hydrostatic Testing of Pipelines.................................. 6 Inline Inspection of Pipelines.............................. 22, 23 Performing Pipeline Rehabilitation........................... 27 Pipeline Pigging and In-line Inspection.................... 14 Pipeline Repair Methods, Hot Tapping, & In-Service Welding................................................ 26 Practical Pigging Operations..................................... 15

Corrosion & Materials Defect Assessment in Pipelines............................16-17 Inspection of offshore pipelines and structures....... 10 Managing Cracks and Seam Weld Anomalies on Pipelines.................................................................. 5 Microbiological Corrosion in Pipelines..................... 25 Onshore Pipeline Engineering..............................12-13 Pipeline Defect Assessment Workshop..................... 18 The Pipeline Defects Clinic........................................ 19 Pipeline Repair Methods, Hot Tapping, & In-Service Welding................................................ 26 Stress-Corrosion Cracking......................................... 24 Subsea Pipeline Engineering.................................30-31

Deepwater Riser Engineering...............................33-34 Geohazard Management for Pipeline Engineers...... 11 Onshore Pipeline Engineering..............................12-13 The Pipeline Defects Clinic........................................ 19 Subsea Pipeline Engineering.................................30-31 The Pipeline Integrity Master Class............................ 6

Advanced Pipeline Risk Management....................... 21 API Recommended Practice 1173: Pipeline Safety Management System Requirements.................... 36 Defect Assessment in Pipelines............................16-17 Hydrostatic Testing of Pipelines.................................. 6 Managing Cracks and Seam Weld Anomalies on Pipelines.................................................................. 5 NEW! New Pipeline Regulations: Impacts & Guidelines for Compliance................................... 29 Pipeline Defect Assessment Workshop..................... 18 Pipeline Integrity Management................................ 28

Engineering Assessment

Repair & Rehabilitation

Defect Assessment in Pipelines ...........................16-17 Pipeline Defect Assessment Workshop..................... 18 Introduction to Excavation Inspection & Applied NDE for Pipeline Integrity Assessment............... 20 New! Safety and Engineering Assessment of Onshore Pipeline Gathering Systems.................... 8

Defect Assessment in Pipelines............................16-17 Onshore Pipeline Engineering..............................12-13 Performing Pipeline Rehabilitation........................... 27 Pipeline Repair Methods, Hot Tapping, & In-Service Welding................................................ 26 Subsea Pipeline Engineering.................................30-31

Design & Construction

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Index of courses by title

External Inspection Inspection of offshore pipelines and structures....... 10 Introduction to Excavation Inspection & Applied NDE for Pipeline Integrity Assessment............... 20 Onshore Pipeline Engineering..............................12-13 Subsea Pipeline Engineering.................................30-31

Risk Assessment & Management Advanced Pipeline Risk Management....................... 21 API Recommended Practice 1173: Pipeline Safety Management System Requirements.................... 36 Geohazard Management for Pipeline Engineers...... 11 Pipeline Integrity Management................................ 28 The Pipeline Integrity Master Class ......................... 37

Defect Assessment in Pipelines.........................................................................16-17 Hydrostatic Testing of Pipelines...............................................................................6 In-Line Inspection of Pipelines - Introduction.....................................................22 In-Line Inspection of Pipelines - Advanced...........................................................23 New! Inspection of Challenging Pipelines...............................................................4 Inspection of Offshore Pipelines and Structures.................................................. 10 Introduction to Excavation Inspection and Applied NDE for Pipeline Integrity Assessment......................................20

NEW! New Pipeline Regulations: Impacts & Guidelines for Compliance...........29 Onshore Pipeline Engineering .........................................................................12-13 Pipeline Defect Assessment Workshop..................................................................18 The Pipeline Defects Clinic....................................................................................19 Pipeline Integrity Management.............................................................................28 Pipeline Pigging and ILI.........................................................................................14 Pipeline Repair Methods, Hot Tapping, & In-Service Welding............................26 Practical Pigging Operations..................................................................................15 New! Safety and Engineering Assessment of Onshore Pipeline Gathering Systems......................................................................8 Stress-Corrosion Cracking in Pipelines.................................................................24 Subsea Pipeline Engineering............................................................................. 30-31 Subsea Production Systems Engineering...............................................................32 The Pipeline Integrity Master Class.......................................................................37

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®

Clarion Technical Conferences 3401 Louisiana Suite 110 Houston, TX 77002 USA t: +1 713 521 5929 e: [email protected]

TM

Tiratsoo Technical (a division of Great Southern Press, Melbourne, Australia) PO Box 21 Beaconsfield HP9 1NS, UK t: +44 (0)1494 675139 e: [email protected]

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