The LM2500 DLE Gas Turbine is an advanced power generation unit designed to deliver high efficiency while significantly reducing emissions. Utilizing cutting-edge Dry Low Emissions (DLE) technology, it precisely controls fuel and air mixing to minimize nitrogen oxide (NOx) emissions.

The LM2500 DLE utilizes a single-rotor gas generator with a 16-stage compressor and a two-stage high-pressure turbine, coupled with cutting-edge DLE combustion technology to reduce nitrogen oxide emissions. It supports dual-fuel operation on a wide variety of fuels, including natural gas, diesel, aviation fuel, LPG, and even hydrogen blends with concentrations ranging from 5% to 95%. The turbine’s open configuration allows for faster maintenance and quicker engine replacement, minimizing downtime.

Its key benefit is utilizing advanced aeroderivative gas turbine technology with dual-fuel Dry Low Emissions (DLE) capability, achieving ultra-low emissions of just 15 ppm NOx on gas fuel, combined with broad fuel flexibility—making it ideal for meeting strict environmental regulations while providing fast, reliable power for dynamic grid demands.

The LM2500 exhaust system is an essential part of the LM2500 gas turbine, designed to handle the hot gases produced during turbine operation. Made from high-quality stainless steel, it is built to withstand extreme temperatures and harsh conditions, ensuring long-lasting durability.

The main purpose of the exhaust system is to safely direct these hot gases away from the turbine while reducing back pressure. Back pressure is the resistance the turbine faces when pushing out exhaust gases—lower back pressure means the turbine can run more efficiently, producing more power with less stress on its components.

This exhaust system is carefully designed to match the specific needs of the LM2500 turbine, ensuring smooth and efficient gas flow. It often works together with silencers or emission controls to release gases safely into the atmosphere while meeting environmental standards.

You would look for a new or replacement LM2500 exhaust system when installing a new turbine, upgrading to improve performance, replacing worn or damaged parts, or meeting updated environmental regulations. Choosing the right exhaust system is crucial because it directly affects the turbine’s performance, reliability, and maintenance costs. A well-designed exhaust system helps keep the turbine running efficiently and reduces the chance of costly downtime—critical factors for operations in oil and gas industries where reliability and efficiency are vital.

The 2″ Gas Metering Valve is designed to precisely control the flow of gas fuel in aero-derivative gas turbines, including the LM2500. By adjusting fuel delivery based on operating conditions, it maintains the optimal fuel-to-air ratio essential for safe, efficient, and reliable turbine operation.

Fuel metering valves act as the throttle control for gas turbines. Since turbines generate power by burning fuel mixed with compressed air, accurate regulation of this mixture directly impacts power output, efficiency, and emissions such as nitrogen oxides (NOx) and carbon monoxide (CO).

This valve delivers exceptional accuracy within ±1% of the flow point, ensuring consistent fuel delivery and optimal combustion. It is built to perform reliably in demanding environments and meets safety standards including ATEX, PED, and UL, certifying it for use in hazardous and extreme conditions.

The fuel metering valve is a two-inch right-angle style valve commonly used on aero-derivative turbines. It integrates easily into existing systems without requiring hydraulic or electrical changes. With millions of hours of proven field performance, it offers dependable, precise fuel control that enhances turbine efficiency and reduces fuel consumption.

The Bearing, Roller, Cylindrical No. 6R is a precision-engineered component used in LM2500 aero-derivative gas turbines commonly employed in the oil and gas sector. Installed at the No. 6R position, this cylindrical roller bearing supports the turbine’s rotor shaft by carrying radial loads and maintaining accurate shaft alignment during high-speed operation.

Its specialized roller design allows it to withstand intense mechanical stresses and thermal changes typical in demanding oil and gas environments. By reducing vibration and ensuring smooth rotation, the bearing contributes to stable and efficient turbine performance, which is critical for continuous operation in upstream, midstream, and downstream applications.

The No. 6R bearing’s role in maintaining precise shaft positioning supports the overall durability and reliability of LM2500 turbines used in gas compression, power generation, and offshore platforms, making it a key element in sustaining safe and efficient operations within the oil and gas industry.

The LM2500+ DLE in a 1x1 combined cycle configuration—one gas turbine, one heat recovery steam generator (HRSG), and one steam turbine—delivers significantly higher efficiency, exceeding 50% in combined cycle mode.

Designed for high thermal efficiency, fast start capability, and reduced emissions, the LM2500 family is widely used across onshore and offshore environments, including industrial plants, pipeline stations, CHP systems, and utility-scale power production.

The DLE combustion system enables the LM2500+ to maintain low NOx and CO emissions without the need for water or steam injection—simplifying operations and reducing water-related maintenance.

Key features include:

• Triple annular combustor design for even temperature distribution and lower emissions across the power range
• Electrically actuated DLE fuel valves replacing traditional electro-hydraulic SAC valves for better control
• 75 pre-mixers in 30 external modules, creating a consistent lean fuel/air mixture
• NOx emissions ≤15–25 ppm and CO emissions ≤25 ppm (on natural gas, full load)

With fast ramp-up—achieving base load from cold start in under five minutes—the LM2500 is an ideal choice for fast-start and cycling applications. This performance makes it well suited to dynamic grid environments and industrial use cases requiring quick responsiveness.