Technical Downloads

VHP* rich-burn engine meets ultra-low emissions standard while providing more than 40 percent cost savings.

Waukesha engines are hard at work powering the world’s energy infrastructure – driving compressors in gas-gathering, processing and transmission operations and providing electrical power for oil and gas fi elds in remote corners of the globe.

An engine is only as good as the parts inside it, and major engine failures are often the result of a single part out of sync.

Gas Compression & Mechanical Drives Natural Gas Fueled Engines Continuous Duty

natural gas Enginator* systems | remote radiator cooling | 130˚F (54˚C) intercooler water inlet temperature

Enginator* systems | remote radiator cooling 130˚F (54˚C) intercooler water inlet temperature

VHP engines have been powering the world’s energy infrastructure—driving compressors in gas gathering, processing and transmission operations and providing electrical power for oil and gas fields in remote corners of the globe for over five decades.

VHP engines have been powering the world’s energy infrastructure―driving compressors in gas gathering, processing and transmission operations and providing electrical power for oil and gas fi elds in remote corners of the globe for over fi ve decades.

VHP engines have been powering the world’s energy infrastructure―driving compressors in gas gathering, processing and transmission operations and providing electrical power for oil and gas fi elds in remote corners of the globe for over fi ve decades.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

Reliable 12 cylinder VHP generator sets, rated at 500-1100 kWe at 50 Hz (1000 rpm) continuous duty to 1200 kWe at 60 Hz (1200 rpm) intermittent duty, are ideal for remote sites.

GE’s Waukesha VHP generator sets are built for efficiency, durability and longevity providing reliable power for continuous and intermittent power applications. Reliable 12 cylinder VHP generator sets, rated at 500-1100 kWe at 50 Hz (1000 rpm) continuous duty to 1200 kWe at 60 Hz (1200 rpm) intermittent duty, are ideal for remote sites.

GE’s Waukesha VHP generator sets are built for efficiency, durability and longevity providing reliable power for continuous and intermittent power applications. Reliable 12 cylinder VHP generator sets, rated at 500-1100 kWe at 50 Hz (1000 rpm) continuous duty to 1200 kWe at 60 Hz (1200 rpm) intermittent duty, are ideal for remote sites.

Reliable 12 cylinder VHP generator sets, rated at 500-1100 kWe at 50 Hz (1000 rpm) continuous duty to 1200 kWe at 60 Hz (1200 rpm) intermittent duty, are ideal for remote sites.

GE’s Waukesha Series Four rich-burn engines are the engines of choice for the harshest and most demanding gas compression, power generation and mechanical drive applications.

GE’s Waukesha Series Four rich-burn engines are the engines of choice for the harshest and most demanding gas compression, power generation and mechanical drive applications.

GE’s Waukesha Series Four rich-burn engines are the engines of choice for the harshest and most demanding gas compression, power generation and mechanical drive applications.

GE’s Waukesha Series Four rich-burn engines are the engines of choice for the harshest and most demanding gas compression, power generation and mechanical drive applications. The Series Four engines can reliably produce more power on hot fi eld gases, at high altitudes, and in remote locations, all while delivering low emissions when paired with a 3-way catalyst (NSCR).

GE’s Waukesha Series Four rich-burn engines are the engines of choice for the harshest and most demanding gas compression, power generation and mechanical drive applications.

GE’s Waukesha 275GL+ represents the most advanced generation of high-horsepower engines designed for optimum performance in gas compression and other mechanical drive applications.

GE’s Waukesha 275GL+ represents the most advanced generation of high-horsepower engines designed for optimum performance in gas compression and other mechanical drive applications.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF Series simplifi es maintenance procedures. The engine design allows easy access to the oil pump, main bearings and rod bearings―without the need to lower the oil pan.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF Series simplifi es maintenance procedures. The engine design allows easy access to the oil pump, main bearings and rod bearings―without the need to lower the oil pan.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

The VGF18 generator set is designed for standby and continuous power applications and is rated at 220-255 kWe at 50 Hz (1500 rpm) and 265-310 kWe at 60 Hz (1800rpm).

GE’s Waukesha VGF generator sets off er a compact, fuel-flexible package delivering exceptional performance in prime power, cogeneration, peak shaving and stand-by power applications.

GE’s Waukesha VGF generator sets off er a compact, fuel-flexible package delivering exceptional performance in prime power, cogeneration, peak shaving and stand-by power applications.

The VGF48 generator set is designed for standby and continuous power applications and is rated at 610-685 kWe at 50 Hz (1500 rpm) and 730-825 kWe at 60 Hz (1800 rpm).

GE’s Waukesha VHP generator sets are built for effi ciency, durability and longevity providing reliable power for continuous and intermittent power applications.

GE’s Waukesha VHP generator sets are built for effi ciency, durability and longevity providing reliable power for continuous and intermittent power applications.

GE’s Waukesha VHP generator sets are built for effi ciency, durability and longevity providing reliable power for continuous and intermittent power applications.

GE’s Waukesha VHP generator sets are built for effi ciency, durability and longevity providing reliable power for continuous and intermittent power applications.

The 16 cylinder VHP 9500, with continuous rating of 1175 kWe at 50 Hz and 1400 kWe at 60 Hz, is suitable for prime power, cogeneration, peak shaving and standby power applications.

GE’s Waukesha Series Four rich-burn engines are the engines of choice for the harshest and most demanding gas compression, power generation and mechanical drive applications.

Designed to demanding specifi cations of the gas compression industry, GE’s Waukesha 275GL+ Enginator is the right choice for rugged oilfi eld power generation and associated gas applications.

Designed to demanding specifi cations of the gas compression industry, GE’s Waukesha 275GL+ Enginator is the right choice for rugged oilfi eld power generation and associated gas applications.

Reliable six cylinder VHP generator sets, rated at 315-540 kWe at 50 Hz and 345-600 kWe at 60 Hz, are ideal for remote applications.

VHP engines have been powering the world’s energy infrastructure―driving compressors in gas gathering, processing and transmission operations and providing electrical power for oil and gas fields in remote corners of the globe for over fi ve decades.

The VGF18 generator set is designed for standby and continuous power applications and is rated at 220-260 kWe at 50 Hz (1500 rpm) and 265-315 kWe at 60 Hz (1800 rpm).

GE’s Waukesha VGF generator sets off er a compact, fuel-flexible package delivering exceptional performance in prime power, cogeneration, peak shaving and stand-by power applications.

The VGF36 generator set is designed for standby and continuous power applications and is rated at 500-535 kWe at 50 Hz (1500 rpm) and 590-645 kWe at 60 Hz (1800 rpm).

GE’s Waukesha VGF generator sets off er a compact, fuel-flexible package delivering exceptional performance in prime power, cogeneration, peak shaving and stand-by power applications.

The VGF Series simplifi es maintenance procedures. The engine design allows easy access to the oil pump, main bearings and rod bearings―without the need to lower the oil pan.

The VGF series of high-speed engines are built with the durability expected from a medium-speed engine. This series of engines is designed for a wide range of stationary, spark-ignited, gaseous fuel applications and has a high power-to-weight ratio operating up to 1800 RPM.

Natural gas fueled continuous duty engine ratings for oilfi eld power generation, gas compression, and mechanical drives

Increasingly stringent emissions standards play a more prominent role in purchasing strategies for new engines.

A combined heat, cooling and power (CHCP) plant has been installed in Slovenia for the first time. The Jenbacher plant serves a shopping mall and movie center in the town of Celje, near Maribor, for the TUS company, Slovenia’s second-largest grocery chain, and has been operating since February 2003.

At the Arpley landfill site, 18 Jenbacher JGC 320 GS-L.L containerized gas engines generate power from landfill gas.

Ханчейское месторождение Установка комплексной подготовки газа Ямало-Ненецкий автономный округ

Van der Arend Roses, a grower that produces 14 million cut roses every year, has installed two natural gas-powered Jenbacher cogeneration systems to provide power for assimilation lighting, heat and CO² to increase its greenhouse rose production capabilities.

Chenab Ltd., located in the city of Faisalabad in the province of Punjab, is part of the Chenab Group and one of the country’s largest composite, textile companies.

In August 2003, the last two of six Jenbacher J320 GS engine sets were installed at the Marcopolo Environmental Group Inzago landfill site, in the northern Italian city of Milan.

The Russian company Khancheyneftegas operates the complex Khanchey gas conditioning plant in the Purovsky Region of the Russian Federation, near the town of Tarko-Sale in the Yamal-Nenets Autonomous Okrug (Area). Situated in Tyumen Oblast (Province) in northwestern Siberia and abutting the Kara Sea, the 750,000-square-kilometer Yamal-Nenets Autonomous Area produces nearly 90% of Russia’s natural gas.

Cerámica Fusté, S.A. es un fabricante de cerámica para la construcción que cuenta con un sistema de cogeneración Jenbacher que cubre la demanda de calor y energía eléctrica de su proceso de producción. Situada en el municipio de Fondarella, en la provincia de Lérida

Near the city of Durban, two containerized Jenbacher gen-sets with a total electrical output of 1,590 kW generate electricity out of landfill methane gas. Instead of flaring the collected landfill methane, the gas is fueled into the Jenbacher gas engines,

La planta de tratamiento de purines de Ágreda, en la provincia de Soria, entró en funcionamiento en junio de 2000. Los seis motores Jenbacher instalados, de 2.620 kW de potencia eléctrica cada uno, permiten a un tiempo tratar 200.000 toneladas de purín cada año, producir 6.000 toneladas de abono para la agricultura, y eliminar el impacto medioambiental de estos residuos.

La empresa Tracjusa, promovida por Sener, SGT (grupo Corporació AGE) y la agrupación de ganaderos de Les Garrigues (Lérida) ha construido la planta de tratamiento y reducción de purines procedentes de noventa granjas de cerdos de la zona. Ubicada en la localidad de Juneda, esta planta cuenta con seis motores Jenbacher del tipo JMS 620 GS-N/B.L de 2.722 kWel c/u. De esta energía eléctrica generada, la mayor parte se exporta a la red y el resto cubre el autoconsumo de la planta. Por otro lado, la potencia térmica de los gases de escape y del circuito de agua caliente de los motores Jenbacher se aprovecha para el proceso de tratamiento de purines.

Koipe (GRUPO SOS) es en la actualidad una de las empresas más importantes dentro del sector de la industria aceitera en España. Su afán de innovación le ha llevado a instalar motores de cogeneración Jenbacher para las diferentes fases de sus procesos. Dicha instalación la ha llevado a cabo la empresa Sinae Energía y Medioambiente, que ha construido así una de las mayores plantas de cogeneración hasta la fecha en España con motores Jenbacher.

Por cada tonelada de acero generada mediante el proceso LD (Linz-Donawitz) – uno de los métodos de producción de acero refinado más comunes, también empleado en la factoría siderúrgica Arcelor Mittal, en Avilés – se liberan aproximadamente 50 m3 N de gas de convertidor.

Since April 2006 a Jenbacher cogeneration plant has been generating power and heat at a Wisconsin 1,100 cow dairy farm, fueled by biogas from cow manure digestion. The digester of the cogeneration system was designed, built and operated by Microgy Inc.

Since April 2006 a Jenbacher cogeneration plant has been generating power and heat at a Wisconsin 1,100 cow dairy farm, fueled by biogas from cow manure digestion. The digester of the cogeneration system was designed, built and operated by Microgy Inc.

In der Rheinisch-Westfälischen Technischen Hochschule (RWTH) Aachen werden mit einem Jenbacher Blockheizkraftwerk (BHKW) Klimatisierungskälte, Wärme und Strom aus Erdgas erzeugt.

Under challenging climatic conditions, five Jenbacher gas engines provide an independent and cost-efficient power supply at the Severnaya Neft crude oil pumping station.

La empresa española Energia sur de Europa, S.E. dedica a la promoción, diseño, construcción, operación y mantenimiento de sistemas de extracción de biogás en vertederos de residuos urbanos, así como de sistemas de generación de electricidad a partir de la combustión de dicho biogás

At The Natural Palm Oil factory a Jenbacher JGS 320 GS-B.L supplies power at maximum availability and reliability despite hot and humid tropical climate using biogas from the effluent of oil extraction.

In Slowenien ist 2003 erstmals eine kombinierte Kraft-Wärme-Kälte-Kopplungsanlage (KWKK) installiert worden.

Per ton of steel produced through the LD (Linz-Donawitz) process – which is one of the most common production methods to produce raw steel and is as well used in the Arcelor Mittal steel factory in Avilés – approximately 50 m3n converter gas are released. LD converter gas typically has a high carbon monoxide content, low combustion speed and is very harmful.

Since 1995, a dozen Jenbacher gas engines have successfully operated at the Profusa S.A. coke factory, one of Spain’s leading producers of coke, in Bilbao, in the North of Spain.

Desde 1995, 12 motores a gas Jenbacher funcionan con éxito en la fábrica Profusa S.A., una de las principales productoras de coque de España, situada en Bilbao.

The successful operation of a JMS 616 GS-N.L Jenbacher cogeneration unit at PT. Indah Jaya, a leading Indonesian manufacturer of high quality towels and knitted fabric, marks the first step of an on-site power generation project aimed to cover the facility's total electricity demand. Founded in 1962.

Im landwirtschaftlichen Betrieb von Schweinezüchter und Weinbauer Franz Kohlroser im steirischen Oberrakitsch wird in einem Jenbacher Blockheizkraftwerk (BHKW) Strom und Wärme aus Biomasse erzeugt.

As its very first gas engine project in the UAE, GE Energy has supplied three Jenbacher generator sets for power generation for continuous operation of compressor chillers to provide chilled water for cooling purposes at Mussafah Industrial City in Abu Dhabi.

Three JGS 320 GS-N.L Jenbacher gas engines improve production process stability at Roshawa Spinning Mills Ltd. by generating 3.1 MW of power directly on-site.

In 2000, the municipality of Madrid awarded engineering companies Vertresa, Cespa and Sufi – that subsequently formed Valdemingómez 2000 SA – to build and operate the Valdemingomez landfill gas-topower plant. By covering an area of 110 hectares and accumulating about 21 million tons of waste over a period of 23 years (1978 – 2000), Valdemingomez is Spain’s largest landfill site.

En el año 2000, el municipio de Madrid adjudicó a las empresas Vertresa, Cespa y Sufi, que posteriormente formaron Valdemingómez 2000 S.A., la construcción y explotación de una instalación de desgasificación con aprovechamiento energético para el vertedero de Valdemingómez.

At the Ano Liossia landfill site – the largest landfill site in Greece and one of the largest in the world - four Jenbacher cogeneration units generate heat and power from municipal solid waste.

Envirogen Pty 有限公司的 Tahmoor 煤矿地处澳大利亚新南威尔士，Envirogen Pty 有限公司是澳大利 亚领先的替代能源开发商，该煤矿安装了七台 颜巴赫 发电机组，利用煤矿瓦斯发电。

Replacing diesel engines at the Moldosa recycling paper site in Santo Domingo, Dominican Republic, a Jenbacher cogeneration system effectively uses cleaner CNG to recycle paper waste products.

Jenbacher natural gas-fueled cogeneration gas engines are ecomagination approved. Ecomagination is GE’s corporate-wide initiative to aggressively bring to market technologies that help customers meet pressing environmental challenges.

A distillery that manufactures industrial alcohol from sugarcane in Maharashtra State, India, has been using GE’s Jenbacher gas engine technology since 2001 to generate 1 MW of electricity from biogas produced from sugarcane waste.

The Coca-Cola Hellenic Bottling Company, one the of the world’s largest bottlers of products of the Coca-Cola company, and the energy development company ContourGlobal opened a new cogeneration plant near Bucharest that is powered by two J620 Jenbacher natural gas engines totaling 3 MW.

Jenbacher gas engines are generating electricity from biogas in a 2 MW power plant at the Kanoria Chemicals & Industries Limited (KCI) manufacturing facility at Ankleshwar, in the state of Gujarat, India.

Back in 2006, ABSA Bank began researching the complete range of power generation options for the 15-story Towers West flagship complex it would build in Johannesburg, South Africa.

A fruit processing plant in Jalgaon, India, is using GE’s ecomagination-qualified Jenbacher combined heat and power (CHP) technology to generate 1.67 MW of power and create steam for refrigeration.

A motley group of farmers, brewers, hospitals and manufacturers are building eco-friendly power plants in their backyards.

GE’s Waukesha 275GL+ represents the most advanced generation of high-horsepower engines in the gas compression segment. A unique combination of robust construction and innovative technology, the 275GL+ lean-burn engine delivers excellence in fuel fl exibility, effi ciency, power output and emissions for unmatched performance.

GE’s Gas Engines business has a track record of more than 170 years of reciprocating engine technology experience. This legacy of innovation goes into each new engine developed to meet the demands of future generations.

As the original manufacturer, nobody knows your engine better than GE. Our Waukesha gas engines services support delivers comprehensive experience and expertise from both the factory and our network of sales and service providers – enhancing uptime throughout your engine’s lifecycle.

More than 80 years ago, GE’s Waukesha gas engines pioneered a system for fuel rating that today remains the standard for defining the anti-knock qualities of motor fuel gasoline, fuel constituents and alternative fuels.

GE’s Waukesha Series Four rich-burn engines are the engines of choice for the harshest and most demanding gas compression, power generation and mechanical drive applications.

GE’s Waukesha VHP generator sets are built for efficiency, durability and longevity providing reliable power for continuous and intermittent power applications. Reliable 12 cylinder VHP generator sets, rated at 500-1100 kWe at 50 Hz (1000 rpm) continuous duty to 1200 kWe at 60 Hz (1200 rpm) intermittent duty, are ideal for remote sites.

For decades, GE’s Waukesha* VHP* L7042GSI has delivered reliable performance in gas compression, power generation and mechanical drive applications.

With over 100 years of engine design, development and manufacturing experience, GE’s Waukesha gas engines are redefi ning oil fi eld power generation in drill rig applications with a non-road EPA mobile certifi ed solution that provides diesel-like performance, fuel flexibility to run on natural gas/fi eld gas and low emissions output for excellent engine performance.

Com mais de 100 anos de experiência em projeto, desenvolvimento e fabricação de motores, os motores a gás Waukesha da GE estão redefi nindo a geração de energia em sondas de perfuração de petróleo com uma solução móvel, com certifi cação US EPA fora-de-estrada que proporciona desempenho semelhante ao diesel, fl exibilidade de combustível para operar com gás natural/ gás campo, baixas emissões e excelente desempenho.

With over 100 years of engine design, development and manufacturing experience, GE’s Waukesha gas engines are redefi ning oil fi eld power generation in drill rig applications with a non-road US EPA mobile certifi ed solution that provides diesel-like performance, fuel flexibility to run on natural gas/fi eld gas and low emissions output for excellent engine performance.

The emPact Emission Control System from GE Waukesha provides a single source solution that ensures lower emissions. The simple, intuitive interface on the emPact display panel gives real-time engine operating parameters. It also gives users the ability to adjust the system richer or leaner in order to maintain compliance as the engine ages.

With the emPact emission control system for Waukesha VHP gas engines, GE effectively combines all the emissions-related components of an engine into one comprehensive control system that can keep your emissions in compliance. The system is factory-designed to optimize the interaction between components, resulting in excellent system performance.

Using an advanced Constant Volume Combustion Chamber (CVCC) equipped with sensors that collect data during the ignition and combustion phase, the FIT unit is designed and optimized to simulate the conditions of the combustion process of an actual diesel engine.

More than 55 Jenbacher employees and friends took part in the 5th Jenbacher Beach Volleyball Event of GE, which took place last Friday at the Weißlahn lake in Terfens. The sport event was again sponsored by GE in Jenbach and organized in cooperation with the HYPO TIROL Volleyball Team.

La division Distributed Power de GE Power & Water est l’un des plus grands fournisseurs d’équipements d’énergie, de moteurs et de services, axés sur la production d’énergie sur le lieu d’utilisation ou à proximité.

Disposal and treatment of biological waste represent a major challenge for the waste industry. For a wide range of organic substances from agriculture, foodstuff or feed industries, anaerobic fermentation is a superior alternative to composting.

Entsorgung und Aufbereitung biologischer Abfälle stellen für die Abfallindustrie eine große Herausforderung dar. Für ein breites Spektrum organischer Stoffe, die in der Landwirtschaft, Lebensmittel- oder Futtermittelindustrie und anderen Industrien anfallen, ist die anaerobe Vergärung eine hochwertige Alternative zum Kompostieren.

Distributed Power von GE Power & Water, einer der führenden Anbieter von Anlagen, Motoren und Dienstleistungen auf dem Gebiet der dezentralen Energieversorgung, ist auf die Energieerzeugung nahe am oder direkt beim Verbraucher spezialisiert.

Turn sewage gas into power and heat efficiently with Jenbacher gas engines.

La división Gas Engines de GE Energy se dedica a la fabricación de motores a gas, grupos generadores compactos en contenedor, módulos de cogeneración y trigeneración para la producción combinada de calor y electricidad (CHP)

La divisione GE Energy dedicata ai motori a gas Jenbacher è un produttore di motori, gruppi elettrogeni, moduli CHP, sistemi ORC e ausiliari.

Disposal and treatment of biological waste represent a major challenge for the waste industry. For a wide range of organic substances from agriculture, foodstuff or feed industries, anaerobic fermentation is a superior alternative to composting.

Les unités de cogénération, aussi appelées systèmes combinés chaleur électricité CHP, peuvent produire à la fois de la chaleur et de l’électricité. Les équipements CHP Jenbacher utilisent efficacement la chaleur dégagée pendant le fonctionnement du moteur pour permettre un rendement global pouvant dépasser 90%.

GE Energy’s Gas Engines division is a manufacturer of gas-fueled engines, generator sets, Combined Heat and Power (CHP) modules, Organic Rankine Cycle (ORC) systems and auxiliaries.

Fertilisation au CO² dans les serres avec les moteurs à gaz Jenbacher.

Wärme, Licht und Kohlendioxid (CO²) begünstigen das Wachstum von Pflanzen. Diese wachsen, indem sie durch Photosynthese CO² in Kohlenstoff umwandeln. Luft enthält üblicherweise etwa 350 ppm CO². Die optimalen CO² -Werte sind abhängig v onder Pflanzenart und liegen normalerweise über 700 ppm.

La divisione GE Energy dedicata ai motori a gas Jenbacher è un produttore di motori, gruppi elettrogeni, moduli CHP, sistemi ORC e ausiliari. Con una tradizione di innovazione tecnologica lungo 3 linee di prodotti, ossia motori Jenbacher

Газовые двигатели Jenbacher для удобрения углекислым газом (CO²) в теплицах.

L‘élimination du gaz de mine avait initialement pour objectif d‘améliorer la sécurité des ouvriers travaillant dans les mines.

Aprovechamiento del gas de vertedero con motores a gas Jenbacher.

Production d’électricité à partir du gaz de décharge avec les moteurs à gaz Jenbacher.

Produzione di energia da gas di discarica con motori a gas Jenbacher.

Landfill gas is created during the decomposition of organic substances in Municipal Solid Waste (MSW). Depending on the landfill design and its management, as well as waste composition, compaction, moisture and several other factors, thousands of landfills are available worldwide to collect and utilize this valuable energy source for power generation.

High levels of power requirement and rising energy costs represent a major challenge for the steel industry. Gases created as a “free” by-product during steel production processes serve as an attractive energy source option for efficient power generation.

Pro Tonne produzierten Koks werden rund 470 m3 N Koksgas produziert, wobei 60% dieses Volumens normalerweise für interne Prozesse benötigt werden. Der verbleibende Anteil (40%) kann zur Stromerzeugung mit Jenbacher Gasmotoren genutzt werden, was rund 400 kWh elektrische Energie bedeutet

GE Energy’s Gas Engines division is a manufacturer of gas-fueled engines, generator sets, Combined Heat and Power (CHP) modules, Organic Rankine Cycle (ORC) systems and auxiliaries.

Las máquinas de absorción constituyen una alternativa económica y ecológica a la tecnología convencional de refrigeración por compresión.

Комбинированная выработка энергии с помощью газовых двигателей Jenbacher

Avec les moteurs à gaz Jenbacher, transformez efficacement les gaz de station d’épuration en électricité et en chaleur.

煤矿排风处理的发展最初目的是改善在煤矿工人作业的安全状况。煤矿瓦斯富含甲烷，如不进行收集，则会通过煤矿的排 风系统被排放到大气中。

Die Grundstruktur der Jenbacher Blockheizkraftwerke besteht aus einer Motor-Generator-Einheit sowie Wärmetauschern für die Nutzung der Abwärme. Die Einbeziehung von weiteren Wärmequellen wie dem vorhandenen Motorkühlwasser,

Der Geschäftsbereich Gasmotoren von GE Energy stellt Gasmotoren, GenSets, Blockheizkraftwerke, ORC-Systeme und Zubehör her. Mit ihren vielfältigen technischen Innovationen in drei roduktgruppen

GE’s Jenbacher gas engines include gas-fueled reciprocating engines, packaged generator sets, and cogeneration units for power generation.

Landfill gas is created during the decomposition of organic substances in Municipal Solid Waste (MSW). Depending on the landfill design and its management, as well as waste composition, compaction, moisture and several other factors, thousands of landfills are available worldwide to collect and utilize this valuable energy source for power generation.

Jenbacher cogeneration plants have an engine/generator unit and heat exchangers that use the produced heat. These plants can create even more customer value by using other heat sources such as the available engine cooling water, lubricating oil, an air/fuel gas mixture, or exhaust gas.

Возможность производства электроэнергии прямо на месте потребления с использованием газовых двигателей Jenbacher

La cogeneración consiste en la generación simultánea y en un mismo proceso de energía eléctrica y calor útil (combined heat and power (CHP) en sus siglas en Inglés).

Mit unseren Kraft-Wärme-Kopplungs-Anlagen können Sie die Produktivität und Rentabilität Ihrer Gewächshäuser steigern. Denn nicht nur Ihre Pflanzen sollten wachsen.

Our combined heat and power engines can increase the efficiency and profitability of your greenhouses. Because it‘s not just your plants that need to grow.

Wir bitten dich, den Fragebogen auszufüllen und Kopien der Zeugnisse (3. und 4. Klasse Hauptschule bzw. Gymnasium sowie Halbjahreszeugnis der derzeitigen Schule) beizulegen.

Jason Cherry is the Chief Financial Officer for GE Power & Water’s Distributed Power, a leading provider of power equipment and services. Distributed Power’s product portfolio includes highly efficient industrial aeroderivative gas turbines and reciprocating engines that generate 100 kW to 100 MW of power for numerous industries globally.

لً ا كبير يعتمد حل الطاقة السريعة +TM2500 *على توربين الغاز الذي حقق نجاح الطيران LM2500 *بعد توزيع أكثر من 1800 وحدة في أنحاء العالم وما يقرب من 69 مليون ساعة تشغيل

目前，全球有13亿多人口还没用上电。GE正在通过分布式电源 解决方案组合来努力缩小这一差距，GE的技术已经帮助提供全 球四分之一的电力。这些技术使工业企业、发展中的社区和政府 能够在使用地点或使用地点附近安置电源，以满足他们的能源需 求。GE发电与水处理集团的分布式能源业务提供TM2500+快速电

Currently, more than 1.3 billion people globally lack access to electricity. GE, whose technologies already help deliver a quarter of the world’s electricity, is working to bridge the gap through a portfolio of distributed power solutions.

En la actualidad, más de 1.300 millones de personas carecen de acceso a la electricidad a nivel global. GE, cuyas tecnologías contribuyen a suministrar un cuarto de la electricidad del mundo, está trabajando para cerrar la brecha mediante un portafolio de soluciones de potencia distribuida.

À l’heure actuelle, plus de 1,3 milliard de personnes n’ont pas accès à l’électricité dans le monde. GE, dont les technologies fournissent déjà un quart de l’électricité mondiale, s’efforce de combler l’écart grâce à une gamme de solutions de production d’électricité décentralisée

Atualmente, mais de 1,3 mil milhões de pessoas a nível global não têm acesso à eletricidade. A GE, cujas tecnologias já ajudam a distribuir um quarto da energia mundial, está a trabalhar para eliminar esta falha através de um portfólio de soluções energéticas distribuídas.

No momento, mais de 1,3 bilhão de pessoas no mundo todo não tem acesso à eletricidade. A GE, cujas tecnologias já ajudam a distribuir um quarto da eletricidade mundial está trabalhando para fechar a lacuna por meio de um portfólio de soluções de energia distribuída.

Since it began operations in December 2010, the F.lli Boscaro pruning and composting plant in Vigliano Biellese, Italy, has used a superheated water biomass boiler to heat the plant.

Biffa Waste Services Ltd. operates the Risley landfill in Warrington, United Kingdom. For more than 10 years, the company used two of GE’s Jenbacher J320 gas engines to generate power from the landfill’s methane gas. But the leftover heat from that process was being wasted – and with it, the opportunity to create another revenue stream.

Five Jenbacher J620N gas engines from GE’s Distributed Power business have teamed up with two absorption chillers and three electric chillers to provide a trigeneration power plant which saves more than $1.1 million in annual energy costs for Central Park Mall in Jakarta, Indonesia.

Back in 2006, ABSA Bank began researching the complete range of power generation options for the 15-story Towers West flagship complex it would build in Johannesburg, South Africa. The growing cost of power and the frequency of power outages in South Africa have prompted many businesses in the country to look for more efficient and economical alternative energy solutions.

The Coca-Cola Hellenic Bottling Company, one the of the world’s largest bottlers of products of the Coca-Cola company, and the energy development company ContourGlobal opened a new cogeneration plant near Bucharest that is powered by two J620 Jenbacher natural gas engines totaling 3 MW.

Im neuen 21-stöckigen Bürogebäude der Gruppe Deutsche Börse in Eschborn, in der Nähe von Frankfurt, befindet sich auch BHKW-Technologie von GE.

Two of GE’s Jenbacher generator sets burning methane-rich natural gas are providing electricity, heating and cooling for the Johannesburg, South Africa, headquarters offices of MTN Group, a multinational telecommunications company.

Constant electricity shortages are a reality in Indonesia. To provide a continuous power supply to the Plaza Indonesia, a new onsite power plant with Jenbacher gas engines was installed as part of a multi-year expansion of the complex, which features a five-star hotel, shopping and entertainment center, office building, and residential facility.

Operating a hospital is anything but simple. In addition to increasing competition, health reforms and regulations, hospitals face greater cost pressures, so their long-term prosperity requires their administrators to have a deep understanding of operating costs and an awareness of best-in-class, cost-saving solutions.

The 48-acre North Shore-Long Island Jewish Medical Center (NSLIJMC) campus encompasses 1.2 million square feet of clinical space with plans to nearly double in size over the next ten years. In anticipation of the expansion, NSLIJMC constructed a new Energy Center in 2003, which included a footprint for a future cogeneration system.

Thermal Energy Corporation (TECO) provides heating and cooling for buildings in the Texas Medical Center (TMC), the largest concentration of patient care, medical research, and health care education institutions in the world.

Using combined heat and power, effi ciency rate is twice that of a conventional thermal plant

Two Jenbacher J320 gas engines from GE’s Distributed Power business, working in tandem with an absorption chiller, have given Indonesian textile manufacturer WinnerSumbiri Knitting (WSK) a more costeffective, effi cient and lower-emissions power supply.

Only GE Energy offers the Waukesha® CFR® XCP™ Digital Octane Panel with its top level of control and functionality. Since its introduction, the proven XCP Digital Octane Panel has become widely accepted in today’s fuel testing laboratories and is now in ASTM Methods D2699-10 &D2700-10 and conforms to IP237 and IP236.

Operating a hospital is anything but simple. In addition to increasing competition, health reforms and regulations, hospitals face greater cost pressures, so their long-term prosperity requires their administrators to have a deep understanding of operating costs and an awareness of best-in-class, cost-saving solutions.

Der Betrieb eines Krankenhauses ist alles andere als einfach. Zusätzlich zum steigenden Wettbewerb und den Reformen und Richtlinien im Gesundheitsbereich stehen Krankenhäuser unter einem erhöhten Kostendruck: Das erfordert seitens der Verwaltung einen ausgezeichneten Überblick über die Betriebskosten sowie das Bewusstsein, dass es der bestmöglichen, kostensparendsten Lösungen bedarf, um langfristig erfolgreich zu sein.

Operating a hospital is anything but simple. In addition to increasing competition, health reforms and regulations, hospitals face greater cost pressures, so their long-term prosperity requires their administrators to have a deep understanding of operating costs and an awareness of best-in-class, cost-saving solutions.

El funcionamiento de un hospital no es nada simple. Además de aumentar la competencia, las reformas y las regulaciones sanitarias, los hospitales se enfrentan a mayores presiones en los costes, por lo que su prosperidad a largo plazo requiere que los administradores tengan un buen entendimiento de los costes operativos y conozcan soluciones punteras que generen un ahorro en los costes.

Faire fonctionner un hôpital est tout sauf simple. En plus de la concurrence, des réformes et des réglementations accrues dans le domaine de la santé, les hôpitaux doivent faire face à des pressions sur les coûts de plus en plus fortes.

La gestione di un ospedale è tutt’altro che semplice. Oltre alla crescente concorrenza, alle riforme e alle normative nel settore sanitario

Эксплуатация зданий больницы не является простой задачей. Помимо все возрастающей конкуренции, постоянных реформ и законодательного регулирования в области здравоохранения, больницы сталкиваются с все большим объемом затрат. Для обеспечения преуспевания больниц в долгосрочной перспективе их руководители должны иметь глубокое представление об эксплуатационных расходах и быть хорошо информированными в отношении лучших в своем классе решений по снижению затрат.

Discover a way to get more from your reciprocating engine with the Clean Cycle generator.

GE’s gas engines CHP technology helps North America meet its ever-increasing demand for electricity from coast to coast by using the continent’s abundant natural gas resources to generate power in a wide range of applications – from dairy farms to office buildings; from small towns to metropolitan cities; from Auburn, New York, to San Diego, California.

Distributed power solutions – which grow the grid in developing countries – are part of a GE’s versatile gas engines portfolio for all types of customers, from industrial clients to developing communities to governments.

Two-thirds of the primary energy used for global power generation is wasted, since the remainder mainly goes to conversion losses, and a small portion to transmission and distribution losses and the plant’s own power generation usage.

The goal of GE’s gas engine division is simple: High efficiency at maximum availability with lowest life-cycle cost and with optimal customer service, onsite and around the clock. How to achieve this goal? By long-term investment in technological innovation, continuous improvement of the existing product portfolio, and expansion of the range of services.

cojen_ausg05_engl_screen.pdf

In the first issue of CoJen, we presented the innovative J624 24-cylinder gas engine as a quantum leap in gas engine technology. In the next issue, we were already able to report on its commissioning in a Dutch pilot project with our customer Royal Pride Holland.

Although Iyyanki grew up in India, his move to Jenbach is the culmination of an equal number of years spent living and working in the US. He talks about how he believes his core values are rooted in his formative years in India, but have been expanded upon during his time in the States. “I took the best of both cultures, and adapted them,” he states.

Welcome to faster more flexible power solutions. With power generation products from 100 kW to 100 MW offering you reliable, affordable, scalable power that grows with your demands. It’s amazing what you can achieve when starting small while thinking big – with Distributed Power from GE.

GE Distributed Power Team

The first generation EPA approvedb mobile and stationary drilling technology

Introduced in 1976 and continuously improved, the Jenbacher type 2 engine offers extremely high efficiency in the 250 to 350 kW power range.

Introduced in 1976 and continuously improved, the Jenbacher type 2 engine offers extremely high efficiency in the 250 to 350 kW power range.

Long service intervals, maintenance-friendly engine design and low fuel consumption ensure maximum efficiency in our type 3 engines. Enhanced components prolong service life even when using non-pipeline gases such as landfill gas. The new type 3D generation offers an outstanding service interval with up to 80,000 operating hours until the major overhaul. This engine type stands out in its 500 to 1,100 kW power range due to its technical maturity and high degree of reliability.

Long service intervals, maintenance-friendly engine design and low fuel consumption ensure maximum efficiency in our type 3 engines. Enhanced components prolong service life even when using non-pipeline gases such as landfill gas. The new type 3D generation offers an outstanding service interval with up to 80,000 operating hours until the major overhaul. This engine type stands out in its 500 to 1,100 kW power range due to its technical maturity and high degree of reliability.

Based on the proven design concepts of types 3 and 6, the modern type 4 engines in the 800 to 1,500 kW power range are characterized by a high power density and outstanding efficiency. The enhanced control and monitoring provides easy preventive maintenance, high reliability and availability.

Based on the proven design concepts of types 3 and 6, the modern type 4 engine in the 800 - 1,500 kW power range is characterized by a high power density and outstanding efficiency. The Enhanced control and monitoring provides easy preventive maintenance, high reliability and availability.

Continuously refined based on our extensive experience, the Jenbacher type 6 engines are reliable, advanced products serving the 1.5 to 4.4 MW power range. Its 1,500 rpm engine speed results in a high power density and low installation costs. The type 6 pre-combustion chamber achieves high efficiency with low emissions. Proven design and enhanced components enable a service life of 60,000 operating hours before the first major overhaul. The new J624 model is available with the new technology of 2-stage turbocharging, which offers high electrical efficiency combined with improved flexibility regarding ambient conditions.

Continuously refined based on our extensive experience, the Jenbacher type 6 engines are reliable, advanced products serving the 1.5 to 4.4 MW power range.

Kontinuierliche Entwicklung seit 30 Jahren

Developpement continu depuis 30 ans

Introdotto nel 1976, il motore Jenbacher tipo 2 offre un rendimento estremamente elevato nel campo di potenza compreso tra 250 - 350 kw.

Desarrollo continuo durante 30 anos

De long intervalles d'entretien, une conception moteur facilitant

I lunghi periodi di servizio, il design che facilita la manutenzione e il basso consumo di combustibile asscurano il massimo rendimento

Los largos intervalos de mantenimiento, la concepcion del motor que facilita el mantenimiento y el bajo consumo de combustible aseguran el maximo

Jenbacher Type 4 un rendement exceptionnel

Basato sui concetti di progettazione comprovati del tipo 3 e 6

Basado en los acreditados conceptos de diseno de los tipos 3 y 6, los motores modernos tipo 4 en la gama de potentia 800a 1.500kW

Constamment optimises grace a notre tres important retour d'experience

Jenbacher tipo 6 - Technologia d'advanguardia

Jenbacher tipo 6 - Tachnologia d'avanguardia

Конструкция двигателей Jenbacher шестого модельного ряда постоянно совершенствуется на основе нашего богатого опыта. Сегодня они представляют собой надёжное и современное оборудование для диапазона мощности от 1,5 МВт до 4,4 МВт. Частота вращения двигателя 1 500 оборотов в минуту обеспечивает высокую удельную мощность и низкие затраты на монтаж

Lange Serviceintervalle, wartungsfreundliche Motorkonzeption und niedriger Brennstoffverbrauch sichern die maximale Wirtschaftlichkeit unserer Motoren der Baureihe 3.

Diese modernen Motoren im Leistungsbereich von 800 bis 1.500 kW basieren auf den bewährten und ausgereiften Designkonzepten der Baureihen 3 sowie 6 und zeichnen sich durch hohe Leistungsdichte und hervorragende Wirkungsgrade aus. Ein optimiertes Regelungs- und Überwachungskonzept ermöglicht optimale präventive Wartung und sichert maximale Zuverlässigkeit und Verfügbarkeit.

Die Jenbacher Motoren der Baureihe 6 wurden auf Basis unserer umfangreichen Erfahrung kontinuierlich weiterentwickelt und sind zuverlässige, hochentwickelte Produkte für den Leistungsbereich von 1,5 MW bis 4,4 MW.

Двигатели Jenbacher второго модельного ряда, введённые в производство в 1976 году, имеют исключительно высокий КПД в диапазоне мощно-сти от 250 кВт до 350 кВт. Надёжная конструкция и концепция стационарного двигателя обеспечивают долговечность его деталей и моторесурс в 60 000 часов до первого капитального ремонта. Улучшенные компоненты и проверенная система управления и контроля придают этому двигателю исключительную надёжность.

Длительные межсервисные интервалы, удобная для обслуживания конструкция двигателя и низкий расход топлива обеспечивают максимальную экономичность наших двигателей третьего модельного ряда.

Эти современные двигатели, работающие в диапазоне мощности от 800 кВт до 1 500 кВт, основаны на испытанных и усовершенствованных концепциях дизайна третьего и шестого модельных рядов. Они отличаются высокой удельной мощностью и превосходными показателями КПД.

GE‘s Clean Cycle* II heat-to-power generator is a compact, modular system that converts waste heat – from an array of heat sources – into power. The conversion process requires no additional fuel, produces no additional emissions, and delivers base-load power that may be used on-site or sold to the grid.

GE‘s Clean Cycle* II heat-to-power generator is a compact, modular system that converts waste heat – from an array of heat sources – into power.

Systém Clean Cycle* divize Heat Recovery Solutions od společnosti GE využívá odpadní teplo k výrobě elektrického proudu – pro vlastní potřebu nebo k dodávkám do veřejné sítě.

Das Clean Cycle* System der Sparte Heat Revovery Solutions von GE nutzt Abwärmeb zur Stromerzeugung – für den Eigenbedarf oder zur Einspeisung ins öffentliche Netz.

The Clean Cycle* system from GE’s Heat Recovery Solutions division captures wasted heat and turns it into electricity that you can use or sell back to the grid.

Le système Clean Cycle* de la filière Heat Revovery Solutions (Solutions de récupération de chaleur) de GE utilise de la chaleur perdue pour la production d’électricité – pour des besoins personnels ou bien pour la fournir au réseau publique.

L’impianto Clean Cycle* della division Heat Revovery Solutions di GE cattura il calore disperso per la produzione di energia ‐ per l’uso proprio o per l’immissione nella rete pubblica.

Wir stellen den weltweit ersten zweistufig aufgeladenen Gasmotor – den neuen Jenbacher J624 von GE – vor. Technische Exzellenz auf einem neuen Niveau – der J624 bietet Ihnen wesentliche Vorteile, besonders für Mehrmotoren-Konzepte für die unabhängige Stromerzeugung und für Kraft-Wärme-Kopplungsanlagen (KWK).

Announcing the world’s first 2-stage turbocharged gas engine – GE’s new Jenbacher J624. A new level of engineering excellence, the J624 offers you significant advantages, particularly in the area of multiple engine power plants for independent power generation and combined heat and power (CHP) solutions.

Intuitive engine management system for gensets that can be used when and where you need it.

DIA.NE XT4* – die neue Generation der Motorsteuerung und -visualisierung für Jenbacher Gasmotoren von GE

With a full range of life cycle services–from planning and plant realization to operation—GE can keep your plant up and running with the utmost efficiency. Our highly skilled staff will give you the support you need to achieve top performance levels with a solution based on our J920 FleXtra powerhouse plant concept.

GE’s engines product line, which includes gas-fueled reciprocating engines, packaged generator sets, and cogeneration units used in the power generation and oil & gas industries, has a legacy of more than 100 years.

Shopping malls, hotels, data centers and office buildings—the structures that permeate cities in both developed and developing nations—are among the highest consumers of energy around the globe

This paper will discuss the benefits and typical applications of distributed power based on larger gas engines. Operating flexibility as well as cogeneration with high total fuel efficiency is investigated.

SCR-Catalyst Retrofit Package for low NOx emissions requirements.

GE’s J920 FleXtra gas engine is at the of its class for electrical efficiency and is designed for durability, simple installation, and maintainability.

bei der Gasmotorensparte von GE in Jenbach

Defining a new era of flexible power generation, GE’s revolutionary LMS100 provides a single, economical solution for the dispatch needs of nearly every market condition.

GE Power & Water now offers a faster, more reliable solution for bridging the gap between energy outages and dependable power generation.

By-product gas to energy is the process of creating energy in the form of electricity or heat from the utilization of a gas that is typically flared. Energy recycling—which can be undertaken at manufacturing facilities, power plants, and large institutions,such as hospitals and universities—generally increases efficiency, thereby reducing energy costs and greenhouse gases simultaneously.

A Conversion, Modification and Upgrade (CM&U) is a solution which improves reliability, availability, maintainability, performance, emissions, efficiency and/or safety of equipment.

GE offers both water and steam injection systems for reducing NOx and other exhaust gas components that can be installed on existing field units.

GE offers both water and steam injection systems for reducing NOx and other exhaust gas components that can be installed on existing field units. Conversions include on-engine modifications as well as package and control system modifications.

GE offers both water and steam injection systems for reducing NOx and other exhaust gas components that can be installed on existing field units. Conversions include on-engine modifications as well as package and control system modifications.

GE has developed an advanced spray injection system, called SPRINT (SPRay INTercooling), which improves the output and efficiency characteristics of the LM6000-PC* and PD and PA/PB Uprate gas turbines.

Our products and services help power the potential of customers across a wide range of operational profiles and industries by increasing efficiency while reducing environmental impact.

GE Power & Water’s Distributed Power business is a leading supplier of aeroderivative gas turbines and packaged generator sets for industrial and marine applications.

The Brazil Service Center was built to help GE meet the needs of its growing aeroderivative gas turbine customer base in Latin America. GE’s gas turbines help businesses and communities benefit from the ability of natural gas to deliver clean, efficient distributed energy.

The LM2500 Base Gas Turbine Marine Package is designed to provide the quality and durability that the marine industry expects from propulsion equipment, with the added benefits of LNG and liquid fuel operation. Its compact configuration provides valuable size and weight benefits aboard high speed commercial vessels.

Our Service Center support is unmatched in the industry. Our worldwide network of Service Centers provides our customers with quick turnarounds and convenience. Our Centers of Excellence have the capability to overhaul and repair GE units with quick turnarounds.

GE provides industry-leading repair capabilities though our extensive network of authorized repair sources and our repair development expertise and technologies. Our goal is to provide repair solutions to drive down customer maintenance costs.

GE offers a Remote Monitoring and Diagnostic (RM&D) Service for aeroderivative gas turbine plants to help operators improve availability, reliability, operating performance and maintenance effectiveness. Annual and multi-year contracts are available with customized levels of service tailored to your specific needs.

GE Power & Water offers a Remote Monitoring and Diagnostic (RM&D) Service for aeroderivative gas turbine plants to help operators improve availability, reliability, operating performance, and maintenance effectiveness. Annual and multi-year contracts are available with customized levels of service tailored to your specific needs.

Derived from the CF6 family of aircraft engines used on wide-body jetliners, the LM2500 Base and the LM2000 are hot-end drive, two-shaft gas generators with a free power turbine. Thermal efficiencies are from 34% to 36%.

GE Power & Water’s Distributed Power business is a leading supplier of aeroderivative gas turbines and packaged generator sets for industrial and marine applications.

GE Power & Water’s Global Field Services is a world-class service and support network that can anticipate and respond to customer needs for the entire life of your LM engines and packages.

GE's innovative LM1800e* aeroderivative gas turbine package is designed to meet industrial power needs from 16 MW to 18 MW.

GE’s PowerXpand portfolio of products deliver rapid power generation solutions, wherever and whenever you need them. PowerXpand consists of the TM2500+* trailer-mounted aeroderivative gas turbine, along with containerized gas and diesel engines.

GE's PowerXpand portfolio of products deliver rapid power generation solutions, wherever and whenever you need them. PowerXpand consists of the TM2500+* trailer-mounted aeroderivative gas turbine generator set, along with containerized gas and diesel engine generator sets.

GE's PowerXpand portfolio of products deliver rapid power generation solutions, wherever and whenever you need them. PowerXpand consists of the TM2500+* trailer-mounted aeroderivative gas turbine generator set, along with containerized gas and diesel engine generator sets.

Bist Du interessiert, motiviert und begeisterungsfähig und suchst nicht nur einen Beruf, sondern eine spannende Aufgabe? Dann bieten wir Dir die Chance, ein Teil von GE in Jenbach zu werden!

Um sich bei GE-Jenbacher zu bewerben ist es notwendig sich auf unserem Karriereportal GE careers anzumelden und die Bewerberdaten online abzuschicken.

By improving your hospital’s efficiency and the health of your bottom line using combined heat and power solutions, you’ll also create a healthier environment for your community.

Distributed power solutions for the Food & Beverage industry save money, are more efficient and environmentally friendlier.

GE Power & Water’s Distributed Power business is a leading provider of power equipment, engines and services focused on power generation at or near the point of use.

GE Power & Water’s Distributed Power business is a leading provider of power equipment, engines and services focused on power generation at or near the point of use. Distributed Power’s product portfolio includes highly efficient industrial reciprocating engines and aeroderivative gas turbines that generate 100 kW to 100 MW of power for numerous industries globally. Headquartered in Cincinnati, Ohio, the Distributed Power business employs about 5,000 people around the world.

CoJen has gone into the second round! Once again, our magazine for the worldwide Jenbacher gas engine community covers many areas of interest to you.

The province of Alberta, Canada developed annual emission intensity limits for the power generation sector in order to preserve air quality by reducing emissions of sulfur dioxide (SOx), nitrogen dioxide (NOx), and primary particulate matter.

GE’s LM6000 is the proven industry leader aeroderivative gas turbine, with over 770 units running in multiple applications for power generation, industrial cogeneration, and the oil & gas industry. The LM6000 is the first aeroderivative gas turbine that has expanded fuel flexibility beyond traditional fossil fuels, and now has the proven capability of running on one of the cleanest forms of bio fuels, Brazilian sugarcane ethanol.

GE Power & Water continues to innovate available gas turbine offerings to improve power capability and enhance customer operations. The criteria to win are the same for both—more power, more often.

THE world's most efficient simple-cycle gas turbine

The mobileFLEX portfolio is the latest advancement from GE to deliver lower-cost, lower-emission power to drill rigs, artificial lift enhanced oil recovery and oilfield equipment. An all-gas alternative to diesel units, mobileFLEX is an EPA mobile-certified solution that provides a cost advantage to energy producers and operational advantage to drilling contractors by utilizing field gases.

Waukesha engines are hard at work powering the world’s energy infrastructure – driving compressors in gas-gathering, processing and transmission operations and providing electrical power for oil and gas fi elds in remote corners of the globe.

GE’s Distributed Power technology creates flexible, efficient, low-emissions power PT Grand Indonesia manages Grand Indonesia Shopping Town (GIST), a magnificent, multi-use complex of retail shops, offices, and hotel and apartment lodgings in Jakarta, Indonesia.

GE Energy’s Jenbacher gas engines are providing the growers a reliable and cost-effective on-site supply of power for their assimilation lighting, plus heat and CO2 fertilization to create the correct environmental balance for cultivation vine-ripened tomatoes under the “Prominent” brand name.

Telersvereniging Prominent is een vereniging van commerciële glastuinbouwbedrijven, die jaarlijks 82,5 miljoen kilo trostomaten produceren. Telersvereniging Prominent heeft 28 warmte/kracht-installaties van Jenbacher geïnstalleerd om te voorzien in elektriciteit voor belichting, warmte en CO2 op de diverse tuinbouwbedrijven in Nederland.

Austria (Main production facility) GE Jenbacher GmbH & Co OG Achenseestraße 1 - 3 6200 Jenbach

GE Power & Water’s Waukesha Series Four rich-burn engines have traditionally been the engines of choice for some of the harshest and most demanding gas compression, power generation, and mechanical drive applications across the world.

GE Power & Water - Distributed Power - Waukesha gas engines 2015 Product Training Calendar

With the emPact emission control system for Waukesha VHP gas engines, GE effectively combines all the emissions-related components of an engine into one comprehensive control system that can keep your emissions in compliance. The system is factory-designed to optimize the interaction between components, resulting in excellent system performance.

Modern electrical power systems are facing unprecedented challenges from the introduction of increasing quantities of wind and solar energy.

Aileen Barton is the product manager for 6F.03 heavy duty gas turbine for GE Power & Water’s Power Generation Products business. In this role, Aileen is responsible for the positioning and viability of this turbine as well as strategy development and positioning for fuel capability with GE’s gas turbine portfolio.

A case study on the application of Arabian Super Light Crude Oil for use in GE 7F-class Dry Low NOx (DLN) combustion systems

2018 Gas Power Systems (GPS / PGP) Products Catalog / Brochure.,With so many things to keep track of in your power generation world, we’ve made it a little easier to find the information you’re looking for. Visit us at powergen.gepower.com and find everything from product descriptions and ratings to interactive tools.

DO #2 is a refined liquid fuel oil used for power generation that is also known as 2-GT distillate oil per ASTM D-2800. This fuel has a well-defined distillation curve with little to no contaminants. Also known as light distillate oil #2 or LDO.

NG is a naturally occurring mixture of hydrocarbons (e.g., methane [CH4], ethane [C2H6], or propane [C3H8]). It is produced in geological formations beneath the Earth's surface that maintains a gaseous state at standard atmospheric temperature and pressure under ordinary conditions.

Expanding performance while resetting the clock on old assets.

175MW Nanxun cogen plant to power industrial zone and grid

GE’s 7HA gas turbine is the industry leader among H-class offerings and is available in two models—the 7HA.01 at 290 MW and the 7HA.02 at 384 MW.

9HA gas turbine fact sheet

The proven performance of GE’s 6B.03 gas turbine makes it an excellent choice for mid-range power generation service.

6F.01 Gas Turbine Fact Sheet

Next Generation, F-Class Flexibility and Efficiency

With more than 2,200 units sold and more than 79 million operating hours, GE’s LM2500 is the top-selling gas turbine globally.

37 million operating hours and more than1,200 units shipped makes GE’s LM600 aeroderivative gas turbine a leader in the +40MW space.

The LMS100 is an intercooled gas turbine system, developed from GE frame and aeroderivative gas turbine technologies, with simple cycle thermal efficiencies of > 44%.

6B.03 HDGT Product Poster GED7389D

GED7448, 6F.01 Heavy Duty Gas Turbine Product Poster

6F.03 Gas Turbine Product Poster GED7390C

The global energy landscape is changing rapidly, and the energy needs of today may not be the energy realities of tomorrow.

World's largest, most efficient gas turbine for 60Hz applications.

The enhanced compressor system provides for increased robustness and damage tolerance

The GE generator product line is divided into three classifications based on the cooling method: air, hydrogen, and water.

RELIABLY AND EFFICIENTLY ELECTRIFYING THE WORLD

This is a product in the FlexEfficiency* Portfolio

GE’s control, protection and monitoring philosophy employs several digital and analog protocols, including FOUNDATION™ Fieldbus (FFB).

PI-BESS is a new product offered by GE Power to clients willing to optimize the operation of their plants and to increase their revenues captured from the ancillary services markets.

With abradable coatings, steam path aerodynamics and welded rotor construction, GE’s advanced technology steam turbines provide enhanced plant operability and combined cycle performance.

70-220 MW Output UP TO 36.2% EFFICIENCY

With abradable coatings, steam path aerodynamics and welded rotor construction, GE’s advanced technology steam turbines provide enhanced plant operability, reliability and combined cycle performance.

85-300 MWOutput UP TO 41.5% EFFICIENCY

In every size and application, GE steam turbines are highly reliable, efficient and easy to maintain. Our advanced technologies—including abradable coatings, steam path aerodynamics, and welded rotor construction—contribute to world-class plant operability and combined cycle performance.

Only units with commercial operation dates in 2000 and later have been included in this list.

200-340 MW Output UP TO 37.0% EFFICIENCY

180-700 MWOutput UP TO 42% EFFICIENCY

180-700 MWOutput UP TO 42% EFFICIENCY

150-500 MWOutput UP TO 42.5% EFFICIENCY

Converting steam into power for more than a century

Excellent Reliability and Performance, in Every Size and Application

Reliable and flexible advanced technology for large combined-cycle solutions

D600 steam turbine

Flexible, modular advanced technology for today’s and tomorrow’s bottoming cycle solutions

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Improve Mill efficiency while reducing maintenance costs

Extend time between mill overhauls while decreasing total cost of ownership

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This upgrade for GE’s LM2500 and LM6000 aeroderivative gas turbines helps you safely reduce or eliminate a common forced four-hour lockout period that can occur after a hot shutdown.

GE’s global service network provides life cycle support for more than 3,500 aeroderivative gas turbines worldwide to help you meet your business challenges and success metrics – anywhere and anytime. Our global service network connects with you locally for rapid response to your service needs.

By utilizing advanced hot section technology from the LM2500+G4 aeroderivative gas turbine, the LM2500 Base engine provides enhanced materials, coatings and enhanced secondary cooling.

Advanced hot section technology from the LM2500+G4 aeroderivative gas turbine provides improved materials, coatings and enhanced secondary cooling.

LM6000 packages utilize a belt-driven fan design that performs adequately but is difficult to maintain. Here are the difficulties with the belt-drive design.

By upgrading a PC turbine to a PG turbine that operates at 3,600 RPM instead of the normal 3,930 RPM of the PG, customers can benefit from some PG improvements.

GE’s Sump Evacuation System (SES) significantly reduces or eliminates bearing sump oil leaks that can occur during extended periods of low power operation or gas turbine trips of your LM6000 aeroderivative gas turbine.

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A leading manufacturer of corrugated cardboard boxes, S.A. Industrias Celulosa Aragonesa (SAICA) faced the prospect of no longer qualifing for Spain's total feed-in tariff, unless it could upgrade the plant to meet Spanish environmental regulations. With a highly skilled team of more than 60 people, GE replaced the entire gas turbine engine with a brand new Frame 6581B production unit including a Mark* VIe control system in just seven weeks.

GE has developed a drop in replacement for REPOWERing the 6B fleet, the 6F.01 Flange-to-Flange (F2F). This will provide 6B reliability and flexibility in a similar footprint with F-class technology, efficiencies, and extended maintenance intervals for power generation and industrial applications.

GE's 7F Advanced Gas Path (AGP) is an upgrade solution that delivers industry-leading performance and operational flexibility driven by increased output, efficiency, and availability. This solution blends hardware innovations with GE's advanced OpFlex software.

Chubu Electric shut down its plant operation at Hamoaka Nuclear Power Station following the March 2011 natural disaster. The GE project team worked closely with Chubu's Electric's Thermal Power Department to develop a flange-to-flange replacement solution that met multiple plant objectives.

GE's 9E Advanced Gas Path (AGP) is an upgrade solution that delivers industry-leading performance and operational flexibility driven by increased output, efficiency, and availability.

Delivering a game-changing leap in 9E gas turbine performance through a new 4-stage turbine module design.

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GE’s 9F-3 Advanced Gas Path (AGP) is an upgrade solution that delivers industry-leading performance and operational flexibility driven by increased output, efficiency, and availability.

GE has developed compressor enhancements for the 9FA flared and 9FB compressors. Developed based upon available fleet experience, these enhancements are aimed both at responding to all known fleet events and at improving the operating stress margins of certain components.

GE's OpFlex solutions have been implemented on more than 400 gas turbines globally and have over two million hours of successful operation.

GE's Advanced Gas Path (AGP) is a great example of Power FlexEfficiency at work, setting new standards in performance. By combining design innovations, materials advancements, and proven model-based control software, the Advanced Gas Path enables GE gas turbine customres to benefit from dramatic output and efficiency improvements, while extending maintenance intervals and maintaining low emissions. It's the kind of solutions-driven thinking that's helping GE customers meet the world's energy demands.

GE helps you expand the value of both your assets and plant operation with the Dry Low NOx (DLN) 1+ combustion upgrade solution for GE's B/E-class gas turbines.

The enhanced compressor system provides for increased robustness and damage tolerance.

In today's budget constrained environment, GE recognizes your need to deliver on industry demands for realiable, flexible power by realizing the most value from your existing plant assets. A gas turbine flange-to-flange upgrade can be a more cost-effective solution to increase your site's reliability, extend maintenance intervals, reduce emissions, lower fuel costs, and increase output to meet your specific operational needs.

GE’s Monitoring & Diagnostics Center in Atlanta remotely monitors critical operations data at sites around the world.

Every day, GE collects more than 30,000 operating hours of data from more than 1,600 globally deployed power generation assets, supplementing a 40 terabyte database representing more than 100 million fleet operating hours.

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Rising fuel costs. Fluctuating market conditions. Emerging renewables. Fast-changing environmental regulations. With so many things out of your control these days, it just makes good economic sense to get a firmer grip on those things you can control. That’s where GE Power & Water’s OpFlex Advanced Control Solutions come in. This suite of advanced technologies gives you unprecedented control over your power plant—from start-up to balancing to turndown. It’s an intelligent way to better manage grid stability, fuel ariability, emissions, compliance and all those other challenges that impact your ability to reduce costs and maximize revenue. With OpFlex Solutions, it’s all about giving you more control to respond in real time to real challenges.

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GE currently conducts over 400 thermal performance tests each year, on gas turbine, steam turbine, and combined cycle power plants from all manufacturers. When GE conducts your performance tests, you gain the high level engineering expertise of a trusted name in the power generation industry.

GE gives you a choice. We offer new genuine GE parts to meet your heavy-duty gas trubine needs, but with our one-stop OEM offering, we also give you the option to save moeny and time with GE's most cost-effective refurbished parts.

GE has developed a drop in replacement for REPOWERing the 6B fleet, the 6F.01 Flange-to-Flange (F2F). This will provide 6B reliability and flexibility in a similar footprint with F-class technology, efficiencies, and extended maintenance intervals for power generation and industrial applications.

GE enhancements allow for brushes safe removal and installation with the generator online, easing its replacement and providing greater reliability during operation.

A comprehensive approach to generator condition assessment enabling predictive maintenance.

GE is continually advancing the technology of in-situ inspections on turbine generator equipment. In-situ inspections offer component assessment capabilities comparable or superior to traditional rotor-out inspections.

Generator tooth cracking is a condition that can result in the failure of your rotor or generator. GE has identified the potential for cracked rotor teeth in large steam turbine generators that have been in service for more than 10 years, experienced a negative sequence event, or hav an operational history includig extensive start-stops.

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GE now offers engineered solutions that convert existing synchronous generators, powered by steam or gas turbines, into synchronous condensers with reduced distruption to the existing plant.

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The Cylinder Retrofit product delivers significant improvement to both efficiency and heat rate while increasing output and extending the life of the steam turbine.

GE has a suite of solutions to address the HP/IP issues affecting the D11 steam turbine fleet.

GE's Dense Pack steam path resdesign technology can improve the efficiency of mature steam turbines, enhancing the plant's profitability and competitiveness, while extending the life of the turbine.

GE's Dense Pack steam path redesign technology can improve the efficiency of mature steam turbines, enhancing plant profitability and competitiveness, while extending the life of the turbine.

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The shell warming system delivers a significant reduction in start times and rub induced vibration events while enabling longer sustained HP/IP section efficiencies. Based on GE's D11 fleet experience, minimizing top-to-bottom shell temperature differentials greatly reduces the likelihood of rub induced vibration events.

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A leading manufacturer of corrugated cardboard boxes, S.A. Industrias Celulosa Aragonesa (SAICA) faced the prospect of no longer qualifing for Spain's total feed-in tariff, unless it could upgrade the plant to meet Spanish environmental regulations. With a highly skilled team of more than 60 people, GE replaced the entire gas turbine engine with a brand new Frame 6581B production unit including a Mark* VIe control system in just seven weeks.

Chubu Electric shut down its plant operation at Hamoaka Nuclear Power Station following the March 2011 natural disaster. The GE project team worked closely with Chubu's Electric's Thermal Power Department to develop a flange-to-flange replacement solution that met multiple plant objectives.

GE's Dense Pack steam path resdesign technology can improve the efficiency of mature steam turbines, enhancing the plant's profitability and competitiveness, while extending the life of the turbine.

GE's Dense Pack steam path redesign technology can improve the efficiency of mature steam turbines, enhancing plant profitability and competitiveness, while extending the life of the turbine.

In today's budget constrained environment, GE recognizes your need to deliver on industry demands for realiable, flexible power by realizing the most value from your existing plant assets. A gas turbine flange-to-flange upgrade can be a more cost-effective solution to increase your site's reliability, extend maintenance intervals, reduce emissions, lower fuel costs, and increase output to meet your specific operational needs.

When it comes to replacement parts, you have many choices. But are you making the right one? With GE, you get genuine OEM-designed and manufactured parts that preserve the integrity of your asset. But that's just the beginning - with GE you get more than a new part. You experience a true collaboration that helps improve your plant's performance, reliability, safety, and emissions.

GE's My Power & Water Stroe is an easy-to-use resource where you can check price and availablity from more than 100,000 continuously replenished generator, gas and steam turbine parts, create spare parts lists, place quotes and orders, track order status, and review your quote and order histor - all in one place.

GECC-1 is a coating used for corrosion prevention on steel and stainless steel turbine components.

The average age of a large liquid cooled GE generator is now over 35 years and many owners plan to run them for many more years. Large liquid cooled generators were designed for decades of life with expected periodic inspection, maintenance and repairs.

GER 2461, GER 2461D, GER2461, GER2461D - Mark I & Early Mark II Controls

GER 2668, GER2668 - Interturn Short-Circuit Detector for Turbine-Generator Rotor Windings

GER 3003, GER3003 -- Generrex for LSTG (1975)

GER 3004, GER3004 - Generrex Description & Performance 1975

GER 3087, GER3087 Generrex Performance & Service Experience (1978)

GER 3107, GER3107 Speedtronic Mark II Controls

GER 3243, GER3243 - Generrex Design Concepts (1980)

GER 3419, GER 3419A, GER3419, GER3419A - Gas Turbine Inlet Air Treatment

GER 3428, GER 3428A, GER3428, GER3428A - Fuels Flexibility in Heavy-Duty Gas Turbines

GER 3430, GER 3430G, GER3430, GER3430G - Cogeneration Application Considerations

GER 3434, GER 3434D, GER3434, GER3434D - GE Gas Turbine Design Philosophy

GER 3481, GER 3481C, GER3481, GER3481C - Liquid Fuel Treatment Systems

GER 3512, GER3512 - Generrex-PPS Performance & Experience (1986)

GER 3539, GER 3539A, GER3539, GER3539A - A Review of GE Fossil Steam Turbine Rotors with Shrunk-on Wheels

GER 3551, GER3551 - Development of the GE Quiet Combustor and Other Design Changes to Benefit Quality

GER 3567, GER 3567H, GER3567, GER3567H - GE Gas Turbine Performance Characteristics

GER 3568, GER 3568G, GER3568, GER3568G - Dry Low NOx Combustion Systems for GE Heavy-Duty Gas Turbines

GER 3571, GER 3571H, GER3571, GER3571H - Performance and Reliability Improvements for Heavy-Duty Gas Turbines

GER 3574, GER 3574G, GER3574, GER3574G - GE Combined-Cycle Product Line and Performance

GER 3582, GER 3582E, GER3582, GER3582E - Steam Turbines for STAG Combined-Cycle Power Systems

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GER 3636, GER 3636A, GER3636, GER3636A - Experience with Compresses Air Cleaning of Main Steam Piping

GER 3642, GER 3642E, GER3642, GER3642E - Steam Turbine Cycle Optimization, Evaluation, and Performance Testing Considerations

GER 3644, GER 3644D, GER3644, GER3644D - Performance and Economic Considerations of Repowering Steam Power Plants

GER 3646, GER 3646D, GER3646, GER3646D - Steam Turbines for Large Power Applications

GER 3651, GER 3651D, GER3651, GER3651D - GE Combined-Cycle Experience

GER 3658, GER 3658D, GER3658, GER3658D - SPEEDTRONIC Mark V Gas Turbine Control System

GER 3687, GER 3687C, GER3687, GER3687C - SPEEDTRONIC™ Mark V Steam Turbine Control System

GER 3688, GER 3688B, GER3688, GER3688B - GE Generators - An Overview

GER 3695, GER 3695E, GER3695, GER3695E - GE Aeroderivative Gas Turbines: Design and Operating Features

GER 3696, GER 3696D, GER3696, GER3696D - Upgradable Opportunities for Steam Turbines

GER 3701, GER 3701B, GER3701, GER3701B - Gas Turbines for Mechanical Drive Applications

GER 3705, GER3705 - GE Steam Turbine Design Philosophy and Technology Programs

GER 3706, GER 3706D, GER3706, GER3706D - Steam Turbines for Industrial Applications

GER 3713, GER 3713E, GER3713, GER3713E - Advances in Steam Path Technology

GER 3750, GER 3750C, GER3750, GER3750C - Steam Turbine Sustained Efficiency

GER 3751, GER 3751A, GER3751, GER3751A - Understanding, Diagnosing, and Repairing Leaks in Water-Cooled Generator Stator Windings

GER 3764, GER 3764A, GER3764, GER3764A - Considerations When Burning Ash-Bearing Fuels in Heavy Duty Gas Turbines

GER 3765, GER 3765B, GER3765, GER3765B - MS6001FA: An Advanced-Technology 70-MW Class 50/60 Hz Gas Turbine

GER 3767, GER 3767C, GER3767, GER3767C - Single-Shaft Combined-Cycle Power Generation System

GER 3804, GER3804 - High-Power-Density™ Steam Turbine Design Evolution

GER 3808C, GER 3808, GER3808, GER3808C - Uprate Options for the MS7001 Heavy Duty Gas Turbine 

GER 3809, GER3809 - Generator Rotor Thermal Sensitivity-Theory and Experience

GER 3928, GER 3928C, GER3928, GER3928C - Uprate Options for the MS9001 Heavy Duty Gas Turbine

GER 3930, GER3930 - GE Generator Rotor Retaining Rings: Experience and Fleet Data

GER 3935, GER 3935B, GER3935, GER3935B - Power Systems for the 21st Century: “H” Gas Turbine Combined-Cycles

GER 3936, GER 3936A, GER3936, GER3936A - Advanced Technology Combined Cycles

GER 3942, GER3942 - Gas Fuel Clean-Up System Design Considerations fo GE Heavy-Duty Gas Turbines

GER 3945, GER 3945A, GER3945, GER3945A - Steam Turbines for Ultrasupercritical Power Plants

GER 3950, GER 3950C, GER3950, GER3950C - The F Technology Experience Story

GER 3952, GER 3952A, GER3952, GER3952A - Operation and Maintenance Strategies to Enhance Plant Profitability

GER 3953, GER3953 - Thermal Performance Evaluation and Assessment of Steam Turbine Units

GER 3954, GER 3954C, GER3954, GER3954C - Generator Test & Inspect Generator In-Situ Inspections

GER 3957, GER 3957B, GER3957, GER3957B - Gas Turbine Repair Technology

GER 4171, GER4171 - Performance and Reliability Improvements for MS5002 Gas Turbines

GER 4172, GER4172 - Gas Turbine NOx Emissions Approaching Zero: Is it Worth the Price?

GER 4189, GER 4189B, GER4189, GER4189B - Design Considerations for Heated Gas Fuel

GER 4190, GER4190 - Steam Turbine Thermal Evaluation and Assessment

GER 4191, GER 4191A, GER4191, GER4191A - Industrial Steam Turbine Value Packages

GER 4191, GER 4191B, GER4191, GER4191B - Industrial Steam Turbine Value Packages

GER 4192, GER4192 - Combustion Modification: An Economic Alternative for Boiler NOx Control

GER 4193, GER 4193A, GER4193, GER4193A - SPEEDTRONIC Mark VI Turbine Control System

GER 4194, GER4194 - The 7FB: The Next Evolution of the F Gas Turbine

GER 4196, GER4196 - Performance and Reliability Improvements for the MS5001 Gas Turbines

GER 4198, GER4198 - Intelligent Optimization of Coal Burning to Meet Demanding Power Loads, Emission Requirements, and Cost Objectives

GER 4199, GER4199 - Steam Turbine Uprates

GER 4200, GER4200 - Economic and Technical Considerations for Combined-Cycle Perfomance-Enhancement Options

GER 4201, GER4201 - Structured Steam Turbines for the Combined-Cycle Market

GER 4203, GER4203 - GE Generator Technology Update

GER 4205, GER4205 - Installation and Outage Management Processes and Technologies

GER 4206, GER4206 - Combined-Cycle Development Evolution and Future

GER 4207, GER4207 - GE IGCC Technology and Experience with Advanced Gas Turbines

GER 4208, GER4208 - Creating Owner’s Competitive Advantage through Contractual Services

GER 4209, GER4209 - Economic Evaluation of Plant Upgrades Using Plant Optimization Software

GER 4211, GER4211 - Gas Turbine Emissions and Control

GER 4212, GER4212 - GE Generator Rotor Design, Operational Issues, and Refurbishment Options

GER 4213, GER4213 - Support for Elimination of Oxidation Catalyst Requirements for GE PG7241FA DLN Combustion Turbines

GER 4217, GER 4217B, GER4217, GER4217B - Uprate Options for the MS6001 Heavy-Duty Gas Turbine

GER 4219, GER4219 - IGCC Gas Turbines for Refinery Applications

GER 4221, GER 4221A, GER4221, GER4221A - Power Generation Equipment and Other Factors Concerning the Protection of Power Plant Employees Against Noise in European Union Countries.

GER 4222, GER 4222A, GER4222, GER4222A - New High Efficiency Simple Cycle Gas Turbine - GE’s LMS 100

GER 4223, GER4223 - GE Generator Fleet Experience and Available Refurbishment Options 

GER 4230, GER4230 - Smallworld 4 - Tracking the Topology of Complex Network Models

GER 4231, GER4231 - Smallworld Core Spatial Technology 4: Managing Change in the World of Spatial Data - The Long Transaction

GER 4232, GER4232 - Smallworld Core Spatial Technology 4: Presenting Spatial Data in Multiple Contexts - Using the Right Reference System for the Task in Hand.

GER 4239, GER4239 - Power Plant Near-Field Noise Considerations

GER 4243, GER4243 - Smallworld 4 Product Suite Open Architectures and Standards: Focusing on the Business

GER 4248, GER4248 - Acoustic Terms, Definitions, and General Information

GER 4249, GER4249 - Air Emissions Terms, Definitions and General Information

GER 4250, GER4250 - GE's LM2500+G4 Aeroderivative Gas Turbine for Marine and Industrial Applications

GER 4253, GER4253 - Power Plant Layout Planning – Gas Turbine Inlet Air Quality Considerations 

GER 4256, GER4256 - Knowledge 3: A Platform for Process Modeling, Optimization, and Control

GER 4262, GER4262 - Ice Shedding and Ice Throw – Risk and Mitigation

GER 4264, GER4264 - The Case for Wind

GER 4285, GER4285 - Particulate Matter Emissions, Guarantees and Testing Considerations 

GER 4530, GER4530 - Minhang Power Plan, Shanghai Electric Power Co., Ltd. Performance Evaluation Test Report for the Combustion Optimization System of #8 Boiler

GER 4536, GER4536 Slagging Mitigation Executive Summary

GER 4600, GER4600 - Benefits of a Single Plant Control System (2009)

GER 4601, GER4601- Addressing Gas Turbine Fuel Flexibility

GER 4601, GER 4601B, GER4601, GER4601B - Addressing Gas Turbine Fuel Flexibility

GER 4610, GER4610 - Exhaust System Upgrade Options for Heavy Duty Gas Turbines

GER 4724, GER4724 - Torsional Dynamics: Large 2-pole and 4-pole Steam Turbine Powertrains

GER4933

Manual 994-0089 - D400 Substation Data Manager User's Manual,994-0089 D400 Substation Data Manager User's Manual.book,994-0089 D400 Substation Data Manager User's Manual.book,994-0089 D400 Substation Data Manager User's Manual.book,994-0089 D400 Substation Data Manager User's Manual.book,994-0089 D400 Substation Data Manager User's Manual.book

The Silicon Carbide (SiC) Photodiode in the GE Reuter-Stokes Silicon Carbide flame sensor has high sensitivity to the longer UV wave length (up to 310nm) that easily penetrates the fog of fuel and steam.

Latest software update incorporates all current Software Action Requests (SARs) revisions for LM6000 turbine line, collectively called “S6 Software Block Change” or S6.

Latest software update incorporates all current Software Action Requests (SARs) revisions for LM6000 turbine line, collectively called “S6 Software Block Change” or S6.

The AF-60 FP Drive, a Variable Frequency Drive (VFD), installed in the turbine enclosure allows air flow to be controlled or reduced, preventing damage at low temperatures.

Controls upgrade from Mark VI and Fanuc 90-70 to Woodward MicroNet Plus, the latest evolution of the MicroNet control system that has been developed for Aero LM product lines.

Inlet icing can occur on LM series turbines at temperatures less than 40°F (4.4°C) and humidity greater than 65%

The Bently Nevada (BN) 3500 Vibration Monitoring System, the latest vibration system from Bently Nevada, provides continuous, online vibration monitoring suitable for machinery protection applications.

An evaporative cooling system for turbine inlet air is a useful option for installations where high ambient temperatures and low relative humidity are common.

LM6000 PC, PD, PF, PG, and PH units have the unique ability to reach full power (simple cycle) from a cold start within 10 minutes.

Existing Fike Intella scan fire panel is replaced by an Allestec 800 fire protection panel.

An inlet chilling unit will cool the compressor air intake, increasing air density and thus engine output.

A dual fuel manifold with water injection consisting of two liquid fuel manifolds, a gas manifold, and 30 dual fuel nozzles.

Upgrade includes on-engine, off-engine, and the off-package fuel delivery and filtration skids, along with updated controls software and hardware, to yield a unit capable of operating on either Natural Gas or Liquid Fuels (diesel)

Upgrading your liquid fuel-only LM6000 aeroderivative gas turbine so that it also can run on natural gas allows you the flexibility of using different fuels as prices fluctuate.

GE AEP packaged LM6000PA model can be updated to the current LM6000 PC configuration.

Mark* VI controllers are currently nearing the end of their life cycle and will soon become legacy units. Certain parts of both the Mark VI and GE Fanuc 90-70 controllers are already discontinued/obsolete.

The Primary Frequency Control (PFC), an important way to maintain frequency stability, balances the power generation and load consumption in the grid.

GE IP 90-70 Sequencers are currently nearing the end of their life cycle and will soon become legacy units.

The S7 core logic upgrade incorporates all current Software Action Requests (SARs) for LM6000 PC engines

New DLE system lowers combustor flame temperature by using bleed air from 16th stage compressor discharge.

The new thrust balance tube kit design eliminates the valve and 11th stage off-engine tube.

Variable inlet air vanes for LM6000 aeroderivative gas turbines help guide inlet airflow to greatly enhance engine performance.

The Variable Stator Vane (VSV) is part of the High Pressure Compressor (HPC) assembly and thus difficult to access.

NOx is a strictly controlled emission due to its harmful environmental impact.

Upgrade your existing LM gas turbine control system to Woodward’s MicroNet Plus programmable control, a highly advanced OEM-qualified control system developed specifically for controlling your GE LM gas turbine. The MicroNet Plus uses Woodward-qualified core software to operate any GE LM2500 and LM6000 SAC or DLE turbine.

GE_FS_Lockout_Avoidance_EN_A4_V02.pdf

GE_FS_Sump_Evacuation_System_EN_A4_V03.pdf

HMI System can be rack mounted on the Turbine Control Panel (TCP) or a separate desktop unit.

New DLE system lowers combustor flame temperature by using bleed air from 16th stage compressor discharge.

GE AEP packaged LM6000PA model can be updated to the current LM6000 PC configuration.

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GE Power & Water Headquarters (HQ), Schenectady, New York,Imacon Color Scanner

GE Innovation Center, Chengdu, China

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The world's most referenced aerodervative gas turbine just got better.

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Delivering a game-changing leap in 9E gas turbine performance through a new 4-stage turbine module design.

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PSP31060-108, 7FA.05 Gas Turbine, Greenville, SC, USA, DI3700x5600

PSP31060-147, 7FA.05 Gas Turbine, Greenville, SC, USA, DI3700x5600

PSP31060-215, 7FA.05 Gas Turbine, Greenville, SC, USA, DI3700x5600

PSP30251-39 MS7001FB Gas Turbine Greenville, SC, Mfg. Rotor Half Shell DI 6200x6200,PSP30251-39 MS7001FB Gas Turbine Greenville, SC, Mfg. Rotor Half Shell DI

Generator Capacity Uprate Solutions image, Wetted Insulation Detector - WID - Wet Bar Generator Repair Technology - GenRT DI 2000x3000,PSP30344-007 Wetted Insulation Detector - WID - Wet Bar Generator Repair Technology - GenRT DI 2000x3000,Generator Capacity Uprate Solutions image, Wetted Insulation Detector - WID - Wet Bar Generator Repair Technology - GenRT DI 2000x3000,PSP30344-007 Wetted Insulation Detector - WID - Wet Bar Generator Repair Technology - GenRT DI 2000x3000

Generator Winder brazing C-Coils in the field ,PSP30320-06 Generator Winder brazeing C-Coils in the field - building 273 Schenectady, NY USA DI 2000x3000

Generator to Synchronous Condenser Conversion

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GE Employee Pride, Building 273, Schenectady, NY, USA, DI-3800x5700

O&M - Operations & Maintenance Services - Meter Check GE Operated MEAG Facility Power Plant - Franklin, GA USA No external use without permission from facility leader. 35mm TP ,PS30522-04 O&M - Operations & Maintenance Services - Meter Check GE Operated MEAG Facility Power Plant - Franklin, GA USA No external use without permission from facility leader. 35mm TP , O&M - Operations & Maintenance Services - Meter Check GE Operated MEAG Facility Power Plant - Franklin, GA USA No external use without permission from facility leader. 35mm TP ,PS30522-04 O&M - Operations & Maintenance Services - Meter Check GE Operated MEAG Facility Power Plant - Franklin, GA USA No external use without permission from facility leader. 35mm TP , O&M - Operations & Maintenance Services - Meter Check GE Operated MEAG Facility Power Plant - Franklin, GA USA No external use without permission from facility leader. 35mm TP ,PS30522-04 O&M - Operations & Maintenance Services - Meter Check GE Operated MEAG Facility Power Plant - Franklin, GA USA No external use without permission from facility leader. 35mm TP , O&M - Operations & Maintenance Services - Meter Check GE Operated MEAG Facility Power Plant - Franklin, GA USA No external use without permission from facility leader. 35mm TP ,PS30522-04 O&M - Operations & Maintenance Services - Meter Check GE Operated MEAG Facility Power Plant - Franklin, GA USA No external use without permission from facility leader. 35mm TP