Post on 16-Jan-2016
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Compressor technologyCompressor technology
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BarrelBarrel Horizontal SplitHorizontal Split
Pipeliner - Axial InletPipeliner - Axial Inlet Pipeliner - Horizontally Opposed FlangesPipeliner - Horizontally Opposed Flanges
Centrifugal compressorCentrifugal compressor
009662/01 PPT26/03/99
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Compressor experienceCompressor experience
Installed or on order
Pipeline Centrifugal 835
Multi-Stage Centrifugal 687
Total Achievement 1522
Installed or on order
Pipeline Centrifugal 835
Multi-Stage Centrifugal 687
Total Achievement 1522
009661/02 PPT26/03/99
end
Multi-Stage barrel centrifugal compressorsMulti-Stage barrel centrifugal compressors
Over 480 sold since 1957
Vertical split barrel-type design
Designed for a broad range of oil and gas applications
Four frame sizes
Standard impeller selections for performance predictability
Maximum working pressure up to450 bar
Suitable for direct-drive by Cooper Rolls/Allison gas turbines,without the need for a gearbox
Uses same lube oil as power turbines -no requirement for separate oil systems
Over 480 sold since 1957
Vertical split barrel-type design
Designed for a broad range of oil and gas applications
Four frame sizes
Standard impeller selections for performance predictability
Maximum working pressure up to450 bar
Suitable for direct-drive by Cooper Rolls/Allison gas turbines,without the need for a gearbox
Uses same lube oil as power turbines -no requirement for separate oil systems
009661/01 PPT26/03/99
end
009661/03 PPT26/03/99
Multi-Stage barrel compressorsMulti-Stage barrel compressors
Full range of hydrocarbon gases
High pressure ratio/head capability
Up to highest operating pressures
Cast/forged steel casings
Custom casing design within established frame sizes
Full range of hydrocarbon gases
High pressure ratio/head capability
Up to highest operating pressures
Cast/forged steel casings
Custom casing design within established frame sizes
end
RBBRBB RCBRCB RDBRDB REBREB
Maximum Pressure RatingMaximum Pressure Rating [BAR][BAR][PSIG][PSIG]
45045065006500
23023032003200
15015022002200
838312001200
Number of StagesNumber of Stages 1 – 81 – 8 1 – 81 – 8 1 – 81 – 8 1 – 81 – 8
Max. Design Inlet FlowMax. Design Inlet Flow [m³/h][m³/h][ACFM][ACFM]
102001020060006000
23000230001350013500
37500375002200022000
600006000035,30035,300
Max. Running SpeedMax. Running Speed [RPM][RPM] 1455014550 1100011000 78507850 65006500
Standard Impeller DiametersStandard Impeller Diameters [mm]/[IN][mm]/[IN] 351 / 13.75351 / 13.75381 / 15.0381 / 15.0419 / 16.5419 / 16.5
521 / 20.5521 / 20.5559 / 22.0559 / 22.0
673 / 26.5673 / 26.5711 / 28.0711 / 28.0
864 / 34.0864 / 34.0
009661/07 PPT26/03/99
Active barrel compressor frame sizesActive barrel compressor frame sizes
end
Multi-Stage barrel compressorsMulti-Stage barrel compressors
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end
Front-to-BackFront-to-Back Back-to-BackBack-to-Back
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Multi-Stage centrifugal impeller arrangementsMulti-Stage centrifugal impeller arrangements
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009662/02 PPT26/03/99
Barrel and horizontally split combinationBarrel and horizontally split combination
end
Pipeline compressorsPipeline compressors
Over 800 sold since 1955
Seven different models suitable for direct-drive by Cooper Rolls Gas Turbines
Tilt-pad journal and thrust bearings
Designed to API 617
Dry gas seals
Up to five impellers
Uses same lube oil as power turbine,no requirement for separate oil system
Choice of axial inlet or opposed-flangecasings
Over 800 sold since 1955
Seven different models suitable for direct-drive by Cooper Rolls Gas Turbines
Tilt-pad journal and thrust bearings
Designed to API 617
Dry gas seals
Up to five impellers
Uses same lube oil as power turbine,no requirement for separate oil system
Choice of axial inlet or opposed-flangecasings
009661/09 PPT26/03/99
end
Conventional
Horizontally opposed nozzles/side inlet
Beam-style (and overhung) rotor designs
Wide pressure ratio/head flexibility - up to five stages
High aerodynamic efficiencies
Fixed casing design per frame size
Fixed pressure ratings up to 155 bar
Axial inlet
Highest aerodynamic efficiencies: Near 90% isentropic
Limited to single-stage designs
Overhung rotor design
Pressures up to 125 bar
Fixed casing design per frame size
Conventional
Horizontally opposed nozzles/side inlet
Beam-style (and overhung) rotor designs
Wide pressure ratio/head flexibility - up to five stages
High aerodynamic efficiencies
Fixed casing design per frame size
Fixed pressure ratings up to 155 bar
Axial inlet
Highest aerodynamic efficiencies: Near 90% isentropic
Limited to single-stage designs
Overhung rotor design
Pressures up to 125 bar
Fixed casing design per frame size
Pipeline compressor typesPipeline compressor types
009663/01 PPT26/03/99
end
RC14 RF20 RF30 RF36 RF42 RFA24RFA36
Nozzle Arrangement Side Inlet Side Inlet Side Inlet Side Inlet Side Inlet Axial InletAxial Inlet
Bearing Arrangement O’Hung Beam O’Hung O’Hung O’Hung O’HungO’Hung
& Beam & Beam & Beam & Beam
Number of Stages 1 - 3 1 - 4 1 - 4 1 - 4 1 - 5 1 1
Max. Casing Rating [BAR] 105 105 100 95/155 105 103105/125 [PSIG] 1500 1500 1440 1380/2250 1500 1500 1500/1800
Max. Design Inlet Flow [m³/h] 11300 22000 52300 77000 107000 43000103000 [ACFM] 6640 13000 30800 45400 62800 2530060500
Max. Operating Speed [RPM] 14500 14500 7000 7000 7000 14500 7000
Max. Impeller Diameter [mm] 495/457 660/533 1230/1050 1230/1050 1230/1050 7101230
[INCH] 19.5/18 26/21 48.5/41.5 48.5/41.5 48.5/41.5 28.0 48.5
RC14 RF20 RF30 RF36 RF42 RFA24RFA36
Nozzle Arrangement Side Inlet Side Inlet Side Inlet Side Inlet Side Inlet Axial InletAxial Inlet
Bearing Arrangement O’Hung Beam O’Hung O’Hung O’Hung O’HungO’Hung
& Beam & Beam & Beam & Beam
Number of Stages 1 - 3 1 - 4 1 - 4 1 - 4 1 - 5 1 1
Max. Casing Rating [BAR] 105 105 100 95/155 105 103105/125 [PSIG] 1500 1500 1440 1380/2250 1500 1500 1500/1800
Max. Design Inlet Flow [m³/h] 11300 22000 52300 77000 107000 43000103000 [ACFM] 6640 13000 30800 45400 62800 2530060500
Max. Operating Speed [RPM] 14500 14500 7000 7000 7000 14500 7000
Max. Impeller Diameter [mm] 495/457 660/533 1230/1050 1230/1050 1230/1050 7101230
[INCH] 19.5/18 26/21 48.5/41.5 48.5/41.5 48.5/41.5 28.0 48.5
009661/06 PPT26/03/99
Active pipeline booster frame sizesActive pipeline booster frame sizes
end
009661/10 PPT26/03/99
Pipeline centrifugal compressorsPipeline centrifugal compressors
end
009659/02 PPT26/03/99
Pipeliner cross sectionPipeliner cross section
end
009663/05 PPT26/03/99
Typical RFA 36 pipeline booster performance mapTypical RFA 36 pipeline booster performance map
end
Rotor supported by a hydrodynamic pressurized
oil film generated between the rotor & white metal
lined bearing pads
Well established & accepted technology
Compact cartridge design
High stiffness & damping capabilities
High load capacities
High reserve capacities - Resistant to upsets
Requires complex oil supply & control system
Rotor supported by a hydrodynamic pressurized
oil film generated between the rotor & white metal
lined bearing pads
Well established & accepted technology
Compact cartridge design
High stiffness & damping capabilities
High load capacities
High reserve capacities - Resistant to upsets
Requires complex oil supply & control system
Fluid film tilting pad bearingsFluid film tilting pad bearings
009665/05 PPT26/03/99
end
Bushing Seals: Principle: Injection of regulated high pressure oil between two
adjacent cylindrical white metal / aluminum lined
rings at each end of compressor
Config’s: - Single breakdown seals up to ~ 140 bar
- Double breakdown seals for higher pressures
Dry Gas Seals: Principle: Use cleaned & dried process gas at discharge
pressure bleeding across highly polished &
profiled radial faces separated by very small
clearances
Config’s: - Tandem seal with second stage as safety
back-up
- Triple seal required above 140 bar
Bushing Seals: Principle: Injection of regulated high pressure oil between two
adjacent cylindrical white metal / aluminum lined
rings at each end of compressor
Config’s: - Single breakdown seals up to ~ 140 bar
- Double breakdown seals for higher pressures
Dry Gas Seals: Principle: Use cleaned & dried process gas at discharge
pressure bleeding across highly polished &
profiled radial faces separated by very small
clearances
Config’s: - Tandem seal with second stage as safety
back-up
- Triple seal required above 140 bar
Shaft sealing technologiesShaft sealing technologies
009665/01 PPT26/03/99
end
Advantages Oil Free
Simple, low maintenance control system
Limitations Tandem seals limited to 140 bar
No rotor damping
Limited axial travel
Requires clean & dry sealing gas
Sensitive to lube oil migration - Requires buffer
air and barrier seal
Complex design
No on-site maintenance
Requires high installation skill
Sticking problems
High cartridge cost
Advantages Oil Free
Simple, low maintenance control system
Limitations Tandem seals limited to 140 bar
No rotor damping
Limited axial travel
Requires clean & dry sealing gas
Sensitive to lube oil migration - Requires buffer
air and barrier seal
Complex design
No on-site maintenance
Requires high installation skill
Sticking problems
High cartridge cost
Dry gas sealsDry gas seals
009665/04 PPT26/03/99
end
Carbon Faces(Stationary)
Primary Rings(Rotating)
Tandem dry gas face sealTandem dry gas face seal
009665/03 PPT26/03/99
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Magnetic Rotor supported by electromagnetic fields
Requires significant air cooling for power outages
Requires auxiliary bearings
Promising technology - Fairly new to large
industrial turbo machinery (1988)
Large bearing dimensions
Reduced stiffness & damping capabilities
Limited load capacities
Limited reserve capacities - Easy to upset
Requires complex digital control system
Requires careful system tuning
Magnetic Rotor supported by electromagnetic fields
Requires significant air cooling for power outages
Requires auxiliary bearings
Promising technology - Fairly new to large
industrial turbo machinery (1988)
Large bearing dimensions
Reduced stiffness & damping capabilities
Limited load capacities
Limited reserve capacities - Easy to upset
Requires complex digital control system
Requires careful system tuning
Active magnetic bearingsActive magnetic bearings
009665/06 PPT26/03/99
end
Magnetic and auxiliary journal bearingsMagnetic and auxiliary journal bearings
009665/09 PPT26/03/99
Magnetic and auxiliary journal bearings
Magnetic and auxiliary journal bearings
Magnetic and auxiliary journal bearings
Magnetic and auxiliary journal bearings
end
RF2BB30 with magnetic bearingsRF2BB30 with magnetic bearings
009665/07 PPT26/03/99
end
009664/01 PPT26/03/99
Inlet guide vanesInlet guide vanes
end
009664/03 PPT26/03/99
Inlet guide vane performanceInlet guide vane performance
end
Type of test Purpose
• Modified ASME PTC 10 Class 3: • Performance Validation - Typical on Pipeline Compressors
• Full ASME PTC 10 Class 3: • Performance Validation - All Compressors
• Full ASME PTC 10 Class 1: • Performance Validation on High Pressure Multistage Compressors
•Confirmation of Rotor Stability
•Absence of Rotating Stall
Type of test Purpose
• Modified ASME PTC 10 Class 3: • Performance Validation - Typical on Pipeline Compressors
• Full ASME PTC 10 Class 3: • Performance Validation - All Compressors
• Full ASME PTC 10 Class 1: • Performance Validation on High Pressure Multistage Compressors
•Confirmation of Rotor Stability
•Absence of Rotating Stall
Compressor running testsAerodynamic performanceCompressor running testsAerodynamic performance
009668/05 PPT26/03/99
end
Type of test Purpose
• Standard API-617 Mechanical: • Confirmation of Mechanical Performance - All Compressors
• Full Density & Speed String: • Confirmation of Mechanical Performance - High Pressure Multistage Compressors
• Confirmation of Rotor Stability • Absence of Rotating Stall
• Full ASME PTC 10 Class 1 String: • Same as Above
Type of test Purpose
• Standard API-617 Mechanical: • Confirmation of Mechanical Performance - All Compressors
• Full Density & Speed String: • Confirmation of Mechanical Performance - High Pressure Multistage Compressors
• Confirmation of Rotor Stability • Absence of Rotating Stall
• Full ASME PTC 10 Class 1 String: • Same as Above
Compressor running testsMechanical and rotordynamic performanceCompressor running testsMechanical and rotordynamic performance
009668/06 PPT26/03/99
end
Continuous Stage Efficiency Improvement
Allison Compressor Frame Size Development
Cycle Time Cost Reduction
Continuous Stage Efficiency Improvement
Allison Compressor Frame Size Development
Cycle Time Cost Reduction
Major compressor development programsMajor compressor development programs
009668/01 PPT26/03/99
end
Development Plan
Select / develop new advanced aerodynamic design software
Calibrate the new software with development testing
Perform parametric studies necessary to define basic stage geometry
Redesign both barrel and pipeline compressor families as
necessary to upgrade performance
Populate each family with standard designs
Development Plan
Select / develop new advanced aerodynamic design software
Calibrate the new software with development testing
Perform parametric studies necessary to define basic stage geometry
Redesign both barrel and pipeline compressor families as
necessary to upgrade performance
Populate each family with standard designs
Compressor stage efficiency improvementCompressor stage efficiency improvement
009668/02 PPT26/03/99
end
RCBB-14 RFBB-20 RFA-24 RBB
Flange Size, in. 14 20 24 6-12No. Stages 1-3 1-4 1 1-8Max. Power 7500 15000 18000 35000
Design Speed 9000-13800 9000-11500 9000-13800 9000-13800
Max. Design PointFlow (ACFM) 6640 13000 25300 6000 (m3/h) 11300 22000 43000 10200
Optimum Eff’cy 83-85% 83-85% 86-88% 78-80%
Typical Driver 501-KC5 601-KC9 501-KC5 501-KC5501-KC7 601-KC11 501-KC7 501-KC7601-KC9 601-KC9601-KC11 601-KC11
MWP, psig 1500 1500 1500 4000
bar 105 105 105 275
RCBB-14 RFBB-20 RFA-24 RBB
Flange Size, in. 14 20 24 6-12No. Stages 1-3 1-4 1 1-8Max. Power 7500 15000 18000 35000
Design Speed 9000-13800 9000-11500 9000-13800 9000-13800
Max. Design PointFlow (ACFM) 6640 13000 25300 6000 (m3/h) 11300 22000 43000 10200
Optimum Eff’cy 83-85% 83-85% 86-88% 78-80%
Typical Driver 501-KC5 601-KC9 501-KC5 501-KC5501-KC7 601-KC11 501-KC7 501-KC7601-KC9 601-KC9601-KC11 601-KC11
MWP, psig 1500 1500 1500 4000
bar 105 105 105 275
Compressors for the CR-501 and CR-601Compressors for the CR-501 and CR-601
009668/03 PPT26/03/99
end
Lead time
Objective: Start 1-Jan-98 100%
Target 65%
Measures:
Improved Engineering Tools
Rationalization of Supplier Base
Expansion of Manufacturing Cells concept to all
components
Improved Fabrication & Packaging Techniques
Lead time
Objective: Start 1-Jan-98 100%
Target 65%
Measures:
Improved Engineering Tools
Rationalization of Supplier Base
Expansion of Manufacturing Cells concept to all
components
Improved Fabrication & Packaging Techniques
Cycle time and cost reductionCycle time and cost reduction
009668/04 PPT26/03/99
end
SummarySummary
50 years of experience in centrifugal compressors
Concentration on oil and gas applications since 1972
Broad model range for all natural gas applications
High, field-proven efficiency and dependability
Single to multiple unit trains, gas turbine or motor driven
(including variable speed motors up to 30MW)
Early introduction and leadership in the use of advanced shaft
sealing and bearing technology, eg
- more than 200 compressors with dry gas seals since 1985
- 24 pipeline compressors with active magnetic bearings
- 5 to 25MW, 8500 to 5000 rpm
State-of-the-art fabrication, testing and packaging techniques
Compliance with all major international technical standards
50 years of experience in centrifugal compressors
Concentration on oil and gas applications since 1972
Broad model range for all natural gas applications
High, field-proven efficiency and dependability
Single to multiple unit trains, gas turbine or motor driven
(including variable speed motors up to 30MW)
Early introduction and leadership in the use of advanced shaft
sealing and bearing technology, eg
- more than 200 compressors with dry gas seals since 1985
- 24 pipeline compressors with active magnetic bearings
- 5 to 25MW, 8500 to 5000 rpm
State-of-the-art fabrication, testing and packaging techniques
Compliance with all major international technical standards
009668/07 PPT26/03/99
end
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