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Overview of current Leak Detection Research at C-FER Technologies
ISA Oil Pipeline Leak Detection Meeting
Chris Appsc.apps@cfertech.com
C-FER Technologies27 February, 2017
Calgary, AB
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Agenda
• Introduction to C-FER Technologies (brief)• Motivation for Leak Detection Research• In-ground Leak Detection • Airbourne Leak Detection JIP• Oil-on-Water Leak Detection
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C-FER Technologies
• Independent engineering consulting and testing
• Not-for-Profit subsidiary of Alberta Government
• Self-sustaining, fee-for-service operation
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Simulating Field Conditions
Environment
Pressure
Temperature
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Leak Detection Research Motivation
• Enhance leak detection for small releases (<1% of flow) where current CPM technologies are weakest
• C-FER research focus– External leak detection (ELD) systems– Small releases
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Research Projects
• In-ground leak detection• Airbourne leak detection• Oil-on-Water leak detection
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In-ground Leak Detection
• Objective– Experimentally evaluate performance of a range of commercial
ELD technologies for continuous in-ground monitoring of buried hydrocarbon liquid pipelines
• Focus– Distributed sensing systems buried on/near pipe
• Distributed Temperature Sensing(fiber optic cables)• Distributed Acoustic Sensing(fiber optic cables)• Hydrocarbon liquid sensing (electrical cables)• Hydrocarbon vapour sensing (permeable tubes)
• Participation– JIP on-going (Enbridge Pipelines, TransCanada Pipelines, Kinder Morgan Canada)
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Technology Overview (DTS)
• Distributed Temperature Sensing (DTS)– Uses fiber optic cable– Uses backscattered light to measure temperature along the length of the cable– Brillouin or Raman bands are used
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Technology Overview (DAS)
• Distributed Acoustic Sensing (DAS)– Also Uses fiber optic cable– Uses backscattered light to measure acoustics along the length of the cable– Rayleigh band is used
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Technology Overview (HSC)
• Hydrocarbon Sensing Cable (HSC)– Proprietary Cable– Cables electrical properties are affected when they come into contact with
hydrocarbons
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Technology Overview (VST)
• Vapour Sensing Tube (VST)– Proprietary Tube– Tube is permeable to hydrocarbon vapours– Periodically purged and run past a gas sensor– Leaks are located using the time it takes for the higher concentrations to reach the
analyzer
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Experimental Design Considerations
• Simulate leaks under real world operating conditions– Realistic soil conditions and sensor placement configurations– Realistic temperature differentials between oil and soil– Realistic release events (pressures, hole sizes and orientations)
• Facilitate unbiased evaluation of ELD technologies– Matching conditions for competing technologies– Provisions to ensure ‘blind testing’ from vendor perspective
• Ensure safe handling and disposal of hydrocarbons– Apparatus to accommodate full range of LVP hydrocarbon liquids– Near-term focus on diluted bitumen (dilbit)
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Test Apparatus
Soil Containment Tank
Retractable Enclosure
Product Storage Vessel
Test Pipe with Release Ports
Spill Containment Berm
Pump Skid with Acoustic Enclosure and Base Isolation System
Catalytic Oxidizer
High Pressure Product Discharge Vessel
Product Filter and Circulation Piping, Discharge Piping,
Vessel Pressurization Systems, Control Valves, Pressure Regulators and Flow Meter Not Shown
External Leak Detection Experimental Research (ELDER) Apparatus
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Test Preparation
2016 Pipeline Safety Trust Conference 14
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In-ground Leak Detection
• JIP Status– Phase 1 (completed): evaluate and compare system performance
(i.e. probability of detection and time to detect) as a function of release parameters and sensor cable position in a single representative soil environment
– Phase 2 (ongoing): further explore system performance (including systematic evaluation of detection floor) for selected technologiesin two distinct soil environments
– Phase 3: TBD based on level of interest and support
• Other opportunities– ELDER apparatus available for work outside JIP
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Airborne Leak Detection
• Objective– Evaluate performance capabilities of selected commercial ELD
technologies for periodic above-ground monitoring of buriedhydrocarbon liquid pipelines
• Focus– Development of analytical models for key phenomena
• Hydrocarbon liquid migration through soil• Hydrocarbon vapour (VOC) migration through soil• Hydrocarbon vapour (VOC) dispersion in atmosphere
– Evaluation of point sensing systems intended for airborne deployment• Atmospheric VOC sensing (light absorption sensing or flame ionization detection)• Ground temperature sensing (thermal imaging)
• Participation– JIP on-going (Enbridge Pipelines, TransCanada Pipelines, Kinder Morgan Canada)
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Release Modeling
Temperature change
Vapour flux
• Magnitudes of temperature change and vapour flux at surface• Dominant species of gases generated by subsurface leaks• Vapour concentrations above ground surface
Atmospheric vapourconcentration
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Vapour Flux using ELDER
• Added Flux Chambers to the soil surface to validate Models
• Took Air Samples during a test and analyzed the concentrations of various species of hydrocarbons
• The results were compared to the modelling.
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Field Trials –Example VOC Detection Systems
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Airborne Leak Detection
• JIP Status– Phase 1 (completed): develop and exercise models for subsurface liquid &
vapour migration, atmospheric vapour dispersion and ground temperature changes resulting from subsurface releases
– Phase 2 (ongoing): evaluate detection capability of selected atmospheric vapour sensing and ground temperature monitoring systems through field trials involving controlled gas releases from surface and selective ground heating
– Phase 3: TBD based on level of interest and support• Expanded field trails – more technologies deployed on more realistic platforms• Generate vapour flux & thermal gradients from actual subsurface liquid releases
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On-water Leak Detection
• Objective– Experimentally evaluate performance of selected commercial ELD
technologies for continuous monitoring of hydrocarbon liquid releasesinto fresh water environments
• Focus– Point sensing systems intended for deployment on/above water surface
• Electromagnetic field (EMF) sensing• Hydrocarbon florescence sensing• Hydrocarbon liquid contact sensing
– Range of hydrocarbons• Light and heavy oils, dilbit, condensate and surrogate fluid
• Participation– Program under development
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Test ApparatusConfiguration for Phase 1 - idealized lab-scale testing
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On-water Leak Detection
• Program Status– Phase 1 (solicitation pending): evaluate detection capability of selected
systems through idealized lab-scale tests involving incremental and continuous releases of a range of hydrocarbon liquids
– Phase 2: TBD based on level of interest and support• More realistic lab-scale testing (e.g. moving water, surface waves, wind and precipitation)
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AdvancingEngineering
FrontiersChris Apps
c.apps@cfertech.comwww.cfertech.com
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