directed inspection and maintenance (di&m) at gas processing plants
DESCRIPTION
Directed Inspection and Maintenance (DI&M) at Gas Processing Plants. Lessons Learned from Natural Gas STAR Partners Processors Technology Transfer Workshop Pioneer Natural Resources, Inc., Gas Processors Association and EPA’s Natural Gas STAR Program September 23, 2004. - PowerPoint PPT PresentationTRANSCRIPT
Directed Inspection and Maintenance Directed Inspection and Maintenance (DI&M) at Gas Processing Plants(DI&M) at Gas Processing Plants
Lessons Learned fromLessons Learned fromNatural Gas STAR PartnersNatural Gas STAR Partners
Processors Technology Transfer WorkshopProcessors Technology Transfer Workshop
Pioneer Natural Resources, Inc., Pioneer Natural Resources, Inc., Gas Processors Association andGas Processors Association andEPA’s Natural Gas STAR ProgramEPA’s Natural Gas STAR Program
September 23, 2004September 23, 2004
Page 2Reducing Emissions, Increasing Efficiency, Maximizing Profits
DI&M at Gas Processing Plants: AgendaDI&M at Gas Processing Plants: Agenda
Methane LossesMethane Losses
Methane Recovery Methane Recovery
Is Recovery Profitable?Is Recovery Profitable?
Industry ExperienceIndustry Experience
Discussion QuestionsDiscussion Questions
Page 3Reducing Emissions, Increasing Efficiency, Maximizing Profits
Methane LossesMethane Losses
Estimated 585 processing plants nationallyEstimated 585 processing plants nationally Estimated 5,000 compressors in processing Estimated 5,000 compressors in processing
sectorsector National fugitive and compressor seal National fugitive and compressor seal
methane emissions from processing plants is methane emissions from processing plants is estimated to be 25 billion cubic feet per year estimated to be 25 billion cubic feet per year (Bcf/yr)(Bcf/yr)
Estimated 43 million cubic feet (MMcf) per Estimated 43 million cubic feet (MMcf) per plant-yr methane emissionsplant-yr methane emissions Worth $130,000/plant-yrWorth $130,000/plant-yr
Page 4Reducing Emissions, Increasing Efficiency, Maximizing Profits
What is the Problem?What is the Problem?
Gas leaks are Gas leaks are invisibleinvisible, , unregulated unregulated andand gogo unnoticedunnoticed
Gas STAR Partners find that valves, connectors, Gas STAR Partners find that valves, connectors, compressor seals and open-ended lines (OELs) are compressor seals and open-ended lines (OELs) are major sourcesmajor sources 27 Bcf of methane emitted per year by reciprocating 27 Bcf of methane emitted per year by reciprocating
compressors seals and OELs, each contributing equally compressors seals and OELs, each contributing equally to the emissionsto the emissions
Gas plant fugitive methane emissions depend on Gas plant fugitive methane emissions depend on operating practices, equipment age and maintenanceoperating practices, equipment age and maintenance
Page 5Reducing Emissions, Increasing Efficiency, Maximizing Profits
What are the Sources of Emissions?What are the Sources of Emissions?
PCPC PCPC
CompressorCompressor
FCFC
DCDC LCLC TCTC
VCVC
FTSFTS
FCFC LCLC
LCLCCon
tact
or
Con
tact
or
Energy Energy Exchange Exchange
PumpPump
DehydratorDehydrator
ReboilerReboiler
PressureReliefValve
DrainValve
Compressor Seal
Pneumatic Controller
Page 6Reducing Emissions, Increasing Efficiency, Maximizing Profits
Distribution of Losses by Source CategoryDistribution of Losses by Source Category
Source: Clearstone Engineering, 2002Source: Clearstone Engineering, 2002
Combustion Equipment9.9%
Amine Vents0.5%
Flare Systems
24.4%
Non-leaking Components0.1%
NRU Vents0.3%
Storage Tanks11.8%
Leaking Components53.1%
Page 7Reducing Emissions, Increasing Efficiency, Maximizing Profits
Distribution of Losses from Distribution of Losses from Equipment Leaks by Type of ComponentEquipment Leaks by Type of Component
Control Valves
4.2%
4.0%
Open-Ended Lines11.1%
Other Flow Meters0.2%
Orifice Meters0.1%
Pressure Relief Valves3.5%
Valves26.0%
Blowdowns0.8%
Connectors24.4%
Compressor Seals23.4%
Crankcase Vents
Pump Seals1.9%
Pressure Regulators0.4%
Source: Clearstone Engineering, 2002Source: Clearstone Engineering, 2002
Page 8Reducing Emissions, Increasing Efficiency, Maximizing Profits
How Much Methane is Emitted?How Much Methane is Emitted?
Methane Emissions from Leaking Components at Gas Processing Plants
Component Type % of Total Methane
Emissions
% Leakers
Estimated Average Methane Emissions per Leaking
Component (Mcf/Yr)
Valves (Block & Control) 26.0 % 7.4 % 66
Connectors 24.4 % 1.2 % 80
Compressor Seals 23.4 % 81.1 % 372
Open-ended Lines 11.1 % 10.0 % 186
Pressure Relief Valves 3.5 % 2.9 % 844 Source: Clearstone Engineering, 2002, Identification and Evaluation of Opportunities to Reduce Methane Losses at Four Gas Processing Plants. Report of results from field study of 4 gas processing plants in WY and TX to evaluate opportunities to economically reduce methane emissions.
Page 9Reducing Emissions, Increasing Efficiency, Maximizing Profits
DI&M - Partner ExperienceDI&M - Partner Experience
Four gas processing plants were selected for joint Four gas processing plants were selected for joint EPA/GTI study of DI&M using high volume samplerEPA/GTI study of DI&M using high volume sampler
Initial estimates have been shown to be 40% lower Initial estimates have been shown to be 40% lower than actual component count during baseline studythan actual component count during baseline study
Final component countFinal component count Plant 1 - 16,050 componentsPlant 1 - 16,050 components Plant 2 - 14,424 componentsPlant 2 - 14,424 components Plant 3 - 56,463 componentsPlant 3 - 56,463 components Plant 4 - 14,168 componentsPlant 4 - 14,168 components
Page 10Reducing Emissions, Increasing Efficiency, Maximizing Profits
How Much Methane is Emitted?How Much Methane is Emitted?
Summary of Natural Gas Losses from the Top Ten Leakers1.
Plant No. Gas Losses From Top 10
Leakers (Mcf/d)
Gas Losses From All Equipment
Leakers (Mcf/d)
Contribution By Top 10 Leakers
(%)
Contribution By Total Leakers
(%) 1 43.8 122.5 35.7 1.78
2 133.4 206.5 64.6 2.32 3 224.1 352.5 63.6 1.66
4 76.5 211.3 36.2 1.75 Combined 477.8 892.84 53.5 1.85
1Excluding leakage into flare system
Page 11Reducing Emissions, Increasing Efficiency, Maximizing Profits
Methane RecoveryMethane Recovery
Fugitive losses can be dramatically reduced Fugitive losses can be dramatically reduced by implementing a DI&M programby implementing a DI&M program
Voluntary program to identify and fix leaks Voluntary program to identify and fix leaks that are cost effective to repair that are cost effective to repair
Survey cost will pay out in the first yearSurvey cost will pay out in the first year
Provides valuable data on leakers with Provides valuable data on leakers with information of where to lookinformation of where to look
Page 12Reducing Emissions, Increasing Efficiency, Maximizing Profits
What is DI&M ?What is DI&M ?
Direct Inspection and MaintenanceDirect Inspection and Maintenance Cost-effective practice by definitionCost-effective practice by definition Find and fix significant leaksFind and fix significant leaks Choice of leak detection technologiesChoice of leak detection technologies Strictly tailored to company’s needsStrictly tailored to company’s needs
DI&M is DI&M is NOTNOT the regulated volatile organic the regulated volatile organic compound leak detection and repair (VOC compound leak detection and repair (VOC LDAR) programLDAR) program
Page 13Reducing Emissions, Increasing Efficiency, Maximizing Profits
How Do You Implement DI&M?How Do You Implement DI&M?
SCREEN and MEASURE leaks
ESTIMATE repair cost, fix to a payback criteria
DEVELOP a plan for future DI&M
RECORD savings/REPORT to Gas STAR
CONDUCT baseline survey
FIX on the spot leaks
Page 14Reducing Emissions, Increasing Efficiency, Maximizing Profits
How Do You Implement DI&M?How Do You Implement DI&M?
Screening - find the leaksScreening - find the leaks Soap bubble screeningSoap bubble screening Electronic screening Electronic screening
(sniffer)(sniffer) Toxic Vapor Analyzer Toxic Vapor Analyzer
(TVA)(TVA) Organic Vapor Analyzer Organic Vapor Analyzer
(OVA)(OVA) Ultrasound Leak Ultrasound Leak
Detection Detection Acoustic Leak DetectionAcoustic Leak Detection Optical Leak ImagingOptical Leak Imaging
Acoustic Leak Detection
Toxic Vapor Analyzer
Page 15Reducing Emissions, Increasing Efficiency, Maximizing Profits
How Do You Implement DI&M?How Do You Implement DI&M?
Evaluate the leaks detected - measure resultsEvaluate the leaks detected - measure results
Leak Measurement Using a High Volume Sampler
High Volume SamplerHigh Volume Sampler
Toxic Vapor Analyzer Toxic Vapor Analyzer (correlation factors)(correlation factors)
RotametersRotameters
Page 16Reducing Emissions, Increasing Efficiency, Maximizing Profits
How Do You Implement DI&M?How Do You Implement DI&M?
Summary of Screening and Measurement Techniques
Instrument/
Technique Effectiveness
Approximate
Capital Cost1
Soap Solution
$
Electronic Gas Detectors
$$
Acoustic Detection/ Ultrasound Detection
$$$
TVA (FID)
$$$
Bagging
$$$
High Volume Sampler
$$$
Rotameter
$$
Source: EPA’s Lessons Learned Study
Page 17Reducing Emissions, Increasing Efficiency, Maximizing Profits
Estimating Comprehensive Survey CostEstimating Comprehensive Survey Cost
Cost of complete screening using High Cost of complete screening using High Volume SamplerVolume Sampler Ranges $15,000 -$20,000 per medium size plantRanges $15,000 -$20,000 per medium size plant Rule of Thumb: $1 per component for an Rule of Thumb: $1 per component for an
average plantaverage plant
25 - 40% cost reduction for follow-up survey25 - 40% cost reduction for follow-up survey
Page 18Reducing Emissions, Increasing Efficiency, Maximizing Profits
Cost-Effective ExamplesCost-Effective Examples
Repair the Cost Effective Components
Component Value of
Lost gas1 ($)
Estimated Repair cost
($)
Payback (Months)
Plug Valve: Valve Body 12,641 200 0.2
Union: Fuel Gas Line 12,155 100 0.1
Threaded Connection 10,446 10 0.0
Distance Piece: Rod Packing 7,649 2,000 3.1
Open-Ended Line 6.959 60 0.1
Compressor Seals 5,783 2,000 4.2
Gate Valve 4,729 60 0.2
Source: Hydrocarbon Processing, May 2002 1Based on $3/Mcf gas price
Page 19Reducing Emissions, Increasing Efficiency, Maximizing Profits
Total Loss Reductions that are Cost-Total Loss Reductions that are Cost-Effective to Find and Fix for Gas PlantsEffective to Find and Fix for Gas Plants
78.0%92.3% 93.1% 94.5%
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
< 6 Months <1 Year <2 Years <4 Years
Page 20Reducing Emissions, Increasing Efficiency, Maximizing Profits
Economics Analysis of DI&M of Open- Ended Lines at Large and Small Gas Plants1
Large Small
Inspection of Plants OELs
(Man-day/yr) 1 1
Inspection of Booster OELs
(Man-day/yr) 2 3
Inspection Prep and Record
(Man-day/yr) NA 3
Repairs & Maintenance
(Man-days) 1 2
Labor Cost ($/day) 500 500
Total Labor Cost ($/yr)
2,000 4,500
Methane Savings (Mcf/yr) 3,319 4,526
Gas Savings (Mcf/yr)2 3,688 5,029
Gas Saving Value $/yr) 11,064 15,087
Payback (yr) <1 <1
Economic Analysis of DI&M of OELsEconomic Analysis of DI&M of OELs
11 Assumes two inspections per year Assumes two inspections per year22 Gas values based on $3/Mcf Gas values based on $3/Mcf
Page 21Reducing Emissions, Increasing Efficiency, Maximizing Profits
Case Study: DynegyCase Study: Dynegy
Surveyed components in two processing Surveyed components in two processing plants: 30,208 plants: 30,208
Identified leaking components: 1,156 ~ Identified leaking components: 1,156 ~ 3.8%3.8%
Repaired components: 80-90% of the Repaired components: 80-90% of the identified leaking componentsidentified leaking components
Annual methane emissions reductions: Annual methane emissions reductions: 100,000 thousand cubic feet per year 100,000 thousand cubic feet per year (Mcf/yr)(Mcf/yr)
Annual savings: $300,000 / year (at Annual savings: $300,000 / year (at $3/Mcf)$3/Mcf)
Page 22Reducing Emissions, Increasing Efficiency, Maximizing Profits
DI&M Partner Experience: BPDI&M Partner Experience: BP
One large gas plant to date - 40,000 One large gas plant to date - 40,000 componentscomponents
ResultsResults 938 equipment leaks identified – 37 MMcf/yr938 equipment leaks identified – 37 MMcf/yr
• 50% of volume from top 31 leaks50% of volume from top 31 leaks• 75% of the volume from top 83 leaks75% of the volume from top 83 leaks
48 compressor seals checked – 20 MMcf/yr48 compressor seals checked – 20 MMcf/yr• 16 leaks16 leaks• 50% of volume from top 2 seals50% of volume from top 2 seals• 80% of volume from top 6 seals80% of volume from top 6 seals
One “water” tank issue found – 66 MMcf/yrOne “water” tank issue found – 66 MMcf/yr Ten-year net present value is $2.4 MM; Ten-year net present value is $2.4 MM;
Payout is 2 monthsPayout is 2 months
Page 23Reducing Emissions, Increasing Efficiency, Maximizing Profits
DI&M - Partner ExperienceDI&M - Partner Experience
Success #1:Success #1: A leaking cylinder head was A leaking cylinder head was tightened, which reduced methane emissions tightened, which reduced methane emissions from almost 64,000 Mcf/yr to 3,300 Mcf/yr. from almost 64,000 Mcf/yr to 3,300 Mcf/yr. The repair required 9 man-hours of labor, and The repair required 9 man-hours of labor, and the annualized gas savings were the annualized gas savings were approximately 60,700 Mscf/yr. The estimated approximately 60,700 Mscf/yr. The estimated value of the gas saved was $182,100/yr.value of the gas saved was $182,100/yr.
Success #2:Success #2: A one-inch pressure relief A one-inch pressure relief valve emitted almost 36,774 Mcf/yr. Five valve emitted almost 36,774 Mcf/yr. Five man-hours of labor and $125 of materials man-hours of labor and $125 of materials eliminated the leak. The annualized value of eliminated the leak. The annualized value of the gas saved was more than $110,300.the gas saved was more than $110,300.
Gas values based on $3/McfGas values based on $3/Mcf
Page 24Reducing Emissions, Increasing Efficiency, Maximizing Profits
DI&M - Partner ExperienceDI&M - Partner Experience
Success #3:Success #3: A blowdown valve leaked almost A blowdown valve leaked almost 14,500 14,500 Mcf/yrMcf/yr. Rather than replace the expensive . Rather than replace the expensive valve, the Partner spent just $720 on labor and valve, the Partner spent just $720 on labor and materials to reduce the emissions to approximately materials to reduce the emissions to approximately 100 100 Mscf/yrMscf/yr. The gas saved was approximately . The gas saved was approximately 14,400 Mcf/yr, worth $43,200.14,400 Mcf/yr, worth $43,200.
Success #4:Success #4: A tube fitting leaked 4,121 A tube fitting leaked 4,121 Mcf/yrMcf/yr. . A very quick repair requiring only five minutes A very quick repair requiring only five minutes reduced the leak rate to 10 reduced the leak rate to 10 Mcf/yrMcf/yr. The annualized . The annualized value of the gas saved was approximately $12,300.value of the gas saved was approximately $12,300.
Page 25Reducing Emissions, Increasing Efficiency, Maximizing Profits
DI&M by Leak ImagingDI&M by Leak Imaging
Real-time visual image of gas leaksReal-time visual image of gas leaks Quicker identification & repair of leaksQuicker identification & repair of leaks Screen hundreds of components an hourScreen hundreds of components an hour Screen inaccessible areas simply by viewing themScreen inaccessible areas simply by viewing them
Page 26Reducing Emissions, Increasing Efficiency, Maximizing Profits
Infrared Gas Imaging TechnologyInfrared Gas Imaging Technology
Shoulder- and/or tripod- mountedShoulder- and/or tripod- mounted
Hand-held prototypeHand-held prototype
Aerial surveillance applicationsAerial surveillance applications
Require battery and/or power cordRequire battery and/or power cord
Most very large leaks (> 3cf/hr) clearly seenMost very large leaks (> 3cf/hr) clearly seen
Page 27Reducing Emissions, Increasing Efficiency, Maximizing Profits
Infrared Gas ImagingInfrared Gas Imaging
Video recording of fugitive leak found by Video recording of fugitive leak found by infrared camerainfrared camera
Page 28Reducing Emissions, Increasing Efficiency, Maximizing Profits
DI&M - Lessons LearnedDI&M - Lessons Learned
A successful, cost-effective DI&M program requires A successful, cost-effective DI&M program requires measurement of the leaksmeasurement of the leaks
A high volume sampler is an effective tool for A high volume sampler is an effective tool for quantifying leaks and identifying cost-effective repairsquantifying leaks and identifying cost-effective repairs
Open-ended lines, compressor seals, blowdown, Open-ended lines, compressor seals, blowdown, engine-starter and pressure relief valves represent engine-starter and pressure relief valves represent <3% of components but >60% of methane emissions<3% of components but >60% of methane emissions
The business of leak detection is about to change The business of leak detection is about to change dramatically with new technologydramatically with new technology
Team available to survey limited number of gas plants at discount cost as part of EPA Team available to survey limited number of gas plants at discount cost as part of EPA grant. Call Roger Fernadez at 202-343-9086 for detailsgrant. Call Roger Fernadez at 202-343-9086 for details
Page 29Reducing Emissions, Increasing Efficiency, Maximizing Profits
Discussion QuestionsDiscussion Questions
To what extent are you implementing this BMP?To what extent are you implementing this BMP?
How can this BMP be improved upon or altered for How can this BMP be improved upon or altered for use in your operation(s)?use in your operation(s)?
What are the barriers (technological, economic, lack What are the barriers (technological, economic, lack of information, regulatory, etc.) that are preventing of information, regulatory, etc.) that are preventing you from implementing this technology?you from implementing this technology?