Managing Pipeline Threats
John Tiratsoo, Editor
Complete list of QR codes
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1
QR 1-1. Learning from other Industries [1]
2
QR 2-1. Constructing Pipelines
QR 2-2. Pipeline Safety
QR 2-3. Pumps and Compressors
QR 2-4. Pipeline Stresses
QR 2-5. More about pipeline principles
3
QR 3-1. Figure 3.7
QR 3-2. Europipe-u-forming
QR 3-3. Europipe-o-forming
QR 3-4. Europipe-welding-inside
QR 3-5. Europipe-welding-outside
QR 3-6. Europipe-expander
QR 3-7. Tube ring hydraulic pressure tests
QR 3-8. Ductile fracture propagation
QR 3-9. Offshore applications
4
QR 4-1. Flowchart on accessibility, negotiability, and propulsion
QR 4-2. tool selection
5
QR 5-1. Additional information on external corrosion
QR 5-2. Additional information on CP potential surveying
QR 5-3. Additional information on corrosion caused by SRB.
QR 5-4. Microbiological corrosion
QR 5-5. Additional information on carbonate cracking.
6
QR 6-1. Additional information on sweet corrosion
QR 6-2. Additional information on sour service
QR 6-3. Additional information on bacterial corrosion
QR 6-4. Additional information on top of the line corrosion
QR 6-5. Additional information on corrosion inhibitors
7
QR 7-1. Images of Cracks in Pipelines
QR 7- 2. Gouges and Hard Layers
QR 7-3. Fatigue in Pipelines
QR 7-4. Stresses in Pipelines Caused by Internal Pressure
8
QR 8-1. Photos of damage to pipelines
QR 8-2. Gouges and Hard Layers
QR 8-3. Assessment of Gouges
QR 8-4. Fatigue Assessment of Dents
QR 8-5. Dent Assessment using Strain
QR 8-6. Corrosion Assessment
QR 8-7. Protecting Pipelines
9
QR 9-1. Comparison between threats to onshore and submarine pipelines
QR 9-2. HIPPS
QR 9-3. Waves, tides and currents
QR 9-4. Stability
QR 9-5. General Imaging Surveys
10
QR 10-1. Fluvial hazards
QR 10-2. Landslides
QR 10-3. Fault movement
QR 10-4. Liquefaction
QR 10-5. Natural subsidence
QR 10-6. Mining subsidence
QR 10-7. Lateral spreading
QR 10-8. Onshore Soil Erosion
QR 10-9. Pipeline monitoring
QR 10-10. Soil-pipe interaction
QR 10-11. Pipeline performance limits
QR 10-12. Inclinometers
11
QR 11-1. Steps in Pipe Making
QR 11-2. Pipeline Construction Primer
QR 11-3. History and Background to Materials & Construction Defects
QR 11-4. Primer on Collapse- and Fracture-Controlled Failure
QR 11-5. Components and Loads Primer
QR 11-6. Inclined Laminations
QR 11-7. Early ERW Seam Processes
QR 11-8. HF vs LF ERW Seams
QR 11-9. Hook Cracking
QR 11-10. DSAW Pipe Production
QR 11-11. Geographic Barriers
QR 11-12. Failure Mechanisms
QR 11-13. Defect Response to Increasing Pressure
QR 11-14. Codes and Margins of Safety
QR 11-15. Illustrations of Some Pipeline Defects
QR 11-16. Degradation and Related Cracking
12
QR 12-1. Mexican Oil and Drug Cartels: Cocaine & Crude.
QR 12-2. Manual hand tap machine hot tapping.
QR 12-3. Video
13
QR 13-1. Case studies in pipeline failures
QR 13-2. ‘Mechanics’ and properties of materials
QR 13-3. Fracture mechanics
QR 13-4. Pipeline defect assessment
14
QR 14-1. Probability
QR 14-2. Why do ‘Incidents’ Occur?
QR 14-3. Safety Management Systems
QR 14-4. Safety Culture
QR 14-5. Threats to Onshore and Subsea Pipelines.
QR 14-6. Prescriptive versus Risk-based (goal-setting) Approaches to Integrity Management
QR 14-7. Example of a Qualitative and Quantitiative Risk Assessment
QR 14-8. Data Management in Pipeline Integrity Management
QR 14-9. Cost of life
QR 14-10. ‘Zero Failures’
QR 14-11. Uncertainty, and the ‘Rare Event’
QR 14-12. Inspection and Surveillance of Pipelines
QR 14-13. New Threats to Pipelines
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QR 10-7. Lateral spreading
Ch10-QR7