LM6000PC Aeroderivative Gas Turbine - Baker Hughes
LM6000PC aeroderivative gas turbine Field-proven with over 20 million hours total fleet experience Copyright 2021 Baker Hughes Company. All rights reserved. The information contained in this document is company confidential and proprietary property of Baker Hughes and its affiliates. It is to be used only for the benefit of Baker Hughes and may not be distributed, transmitted, reproduced, altered, or used for any purpose without the express written consent of Baker Hughes.
Industry leader in gas turbine technology kW Frame 9 Frame 7EA Frame 6 Frame 5/2D Frame 5/2E Frame 5/2C Frame Frame 5/1PA Aeroderivative LMS100-PB Industrial LMS100-PB LM9000 LM6000 PF LM6000 PG LM6000 PC LM6000 PF LM2500/PGT25 G5 LM2500/PGT25 G4 LM2500 /PGT25 LM2500 /PGT25 Xtend 9ppm LM2500/PGT25 NovaLT16-2 NovaLT12 NovaLT5-1 - 2 20,000 Copyright 2021 Baker Hughes Company. All rights reserved. 40,000 60,000 80,000 100,000 120,000 140,000
LM6000PC The best-selling LM6000 With over 720 engines worldwide across all applications, the LM6000 PC fleet has more than 20 million total hours, and a fleet leader with 190,000 hours. It’s ideal for offshore applications, with the simpler single annular combustion system and well-referenced dual-fuel capability and wide fuel flexibility. With 44 MW shaft power and 42% simple-cycle efficiency, this turbine can quickly ramp up and down to match demanding operating requirements. Key features Double co-axial shafts Aeroderivative compressor design has 5 low-pressure and 14 highpressure stages for outstanding efficiency, and adjustable vanes for best operating flexibility Single annular combustor technology with dual fuel capability, 40–60 modified Wobbe Index flexibility, and 30% vol hydrogen capability 2-stage high-pressure turbine and 5-stage low-pressure turbine with optimized airfoils for high efficiency and reduced CO2 emissions 3 Copyright 2021 Baker Hughes Company. All rights reserved.
Package Onshore and offshore solutions Optimized slide-off turbine design with mini-skid concept for engine swap in less then 24 hours for maximized availability Multipoint AVM for lightweight single-lift design and uniformly distributed load Remote I/O panel available Onshore mechanical drive Aerosol fire-protection system to minimize footprint and weight by eliminating interconnecting piping and cables Optimized offshore arrangement Minimized distance between units Shared maintenance area 4 units in 40 m: a game-changer in the FPSO market Single-lift power generation 4 Copyright 2021 Baker Hughes Company. All rights reserved.
LM6000PC datasheet Mechanical drive Power MW 44 Efficiency % 42 Exhaust C 460 Speed rpm 3,600 Power generation Single-lift power generation package LxWxH m 20x5 Weight ton 280 Capability highlights Ideal for offshore application thanks to the well-referenced and simple single annular combustor technology with dual-fuel capability Reduced CO2 emissions thanks to the high simple-cycle efficiency Gas turbine package 40–60 MWI fuel flexibility with more than 10%/min rate of change LxWxH m 12x4.8 Ready to burn up to 30% vol H2 Weight ton 160 Power MWe 43.3 Efficiency % 41.1 Main inspections Exhaust C 454 HGP hr 25,000 Speed rpm 3,600 Major insp. hr 50,000 Single annular combustion technology 5 Copyright 2021 Baker Hughes Company. All rights reserved. Performances @ ISO conditions with natural gas fuel, ambient temperature 15ºC, no inlet or exhaust losses, sea level, 60% relative humidity. Mechanical package dimensions driven equipment excluded.
Projects Upstream power generation Downstream power generation Dual-fuel offshore power generation Venezuela USA United Kingdom 6 Copyright 2021 Baker Hughes Company. All rights reserved.
Frame kW - 20,000 40,000 60,000 80,000 100,000 120,000 140,000 NovaLT5-1 NovaLT12 NovaLT16-2 LM2500/PGT25 LM2500 /PGT25 Xtend 9ppm LM2500 /PGT25 LM2500/PGT25 G4 LM2500/PGT25 G5 LM6000PF LM6000PC LM6000PG LM6000PF LM9000 LMS100-PB LMS100-PB Frame 5/1PA Frame 5/2C Frame 5/2E Frame 5/2D Frame 6 Frame 7EA Frame 9 Industry leader in gas turbine .
AERODERIVATIVE GAS TURBINES GEA34130 CHEAPER POWER HIGHER EFFICIENCIES When comparing heat rates or efficiencies between aeroderivative gas turbines and reciprocating engines, three important points must be emphasized: 1. Reciprocating engines have a 5% fuel consumption tolerance, while gas turbines in simple cycle, by applicable standards, do
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aeroderivative (for weight considerations) gas turbine in simple cycle operation. (Source: GE Power Systems) In marine applications, the gas turbine is generally driving the ship’s or ferry’s propellers, via a gear box. Fig. 11. Gas turbines in marine service: SGT-500 Industrial Gas Turbine – 17 MW, Application: Two SGT-500 power packages for FPSO vessel in the Leadon oilfields (Note the .
A gas turbine is an extension of the same concept. In a gas turbine, a pressurized gas spins the turbine. In all modern gas turbine engines, the engine produces its own pressurized gas, and it does this by burning something like propane, natural gas, kerosene or jet fuel.
These turbines are utilized in simple cycle, STIG (Steam Injected Gas Turbine) applica-tions for power enhancement, or integrated into cogeneration or combined-cycle arrange-ments. GE also produces a variety of engine-mounted, emissions control technologies, described in Figure 3. Selection of Aeroderivative Engines
Three Spool aero derivative industrial gas turbine hot-end drive. Intake-Radial inlet LP Compressor- Axial compressor 6 stages. Air deliver to an intercooler HP Compressor- 14 stage. Over pressure ratio 42:1 Combustor – SAC/DLE HP Turbine- Two stage IP Turbine- two axial stages that drive the LP /Power Turbine. LP/Power Turbine- five stage free power turbine. 3600 RPM 60-Hz and 3000 RPM 50 .
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this and other articles in this Volume. The dis-cussion in this article is limited to the relation-ship between these factors and the induction coil design. Current Flow in the Part Eddy currents are the primary source of power dissipation in most induction heat treat-ing applications. Eddy currents, just like all
