Gas Turbine , CCPP, Operation& Maintenance, spare part supply, Manpower service for Power Plant, GE LM6000 ,GE LM2500, GE FRAME 6,... P&W, MAN, RR, Turbine commisioning and start up,......
Gas Turbine Theory - Principle of Operation and ConstructionSahyog Shishodia
This presentation tells all about basic principle behind Gas Turbine, their working, operation and construction. How they came into existence and where are they used.
This document provides an overview of Gas Turbine Efficiency PLC, a global leader in gas turbine efficiency solutions established in 1989. It summarizes the company's history, leadership team, technology team, key product offerings around water wash systems and mechanical capabilities, as well as their customer base including OEMs, end users, and the Swedish Air Force. The company has established manufacturing, technology centers, and sales/service capabilities worldwide and has solutions installed on over 850 gas turbine units totaling more than 22 million operating hours.
The document discusses gas turbines, including their definition, parts, types, working, and applications. It describes the basic operation of a gas turbine as similar to a steam power plant but using air instead of water. The main parts of a gas turbine are identified as the inlet, compressor, shaft, burner, turbine, and nozzle. Types of gas turbines covered include turbojet, turbofan, turboprop, and afterburning turbojet. Applications discussed are their use in marine vessels, aircraft jet propulsion, small micro gas turbines in devices like the Bladon jet engine, and electricity generation including at remote oil and gas sites from 5-500 megawatts.
This document discusses gas turbines, including their components and how they work. It describes the key components - compressors, combustors, and turbines - and explains the basic Brayton cycle of compression, combustion, and expansion that produces power. It also covers gas turbine applications in aircraft engines and industrial settings, and discusses performance factors like efficiency and output over varying operating conditions.
This document discusses gas turbines, including their basic components and working principle. A gas turbine combusts fuel in the presence of compressed air, converting the thermal energy of the combustion products into mechanical energy. The main components are the compressor, combustion chamber, and turbine. The compressed air is mixed with fuel and burned in the combustion chamber. The hot gases then power the turbine before being exhausted. Gas turbines have applications in vehicles, aircraft, ships, and power generation.
Gas turbine power plants work by compressing air which is then mixed with fuel and ignited in a combustion chamber. This powers a turbine, which drives both a generator to produce electricity and the air compressor. Gas turbines have three main parts - an air compressor, combustion chamber, and turbine. They can use fuels like oil, natural gas, or pulverized coal and are used for power generation especially for peak loads or as backup. Advantages include easier fuel storage and handling as well as lower maintenance costs compared to steam plants.
This document discusses gas turbines, including their basic components and working principle. A gas turbine combusts fuel in the presence of compressed air, converting the thermal energy of the combustion products into mechanical energy. The main components are the compressor, combustion chamber, and turbine. The compressed air is mixed with fuel and burned in the combustion chamber. The hot gases then power the turbine before being exhausted. Gas turbines have applications in vehicles, aircraft, ships, and power generation.
A gas power plant consists of an air compressor, combustion chamber, gas turbine, alternator, and starting motor. Air is compressed and mixed with fuel in the combustion chamber, where combustion increases the temperature and pressure. The high-pressure combusted air expands through the gas turbine, rotating the generator to produce electricity. A starting motor initially rotates the compressor.
Gas Turbine Theory - Principle of Operation and ConstructionSahyog Shishodia
This presentation tells all about basic principle behind Gas Turbine, their working, operation and construction. How they came into existence and where are they used.
This document provides an overview of Gas Turbine Efficiency PLC, a global leader in gas turbine efficiency solutions established in 1989. It summarizes the company's history, leadership team, technology team, key product offerings around water wash systems and mechanical capabilities, as well as their customer base including OEMs, end users, and the Swedish Air Force. The company has established manufacturing, technology centers, and sales/service capabilities worldwide and has solutions installed on over 850 gas turbine units totaling more than 22 million operating hours.
The document discusses gas turbines, including their definition, parts, types, working, and applications. It describes the basic operation of a gas turbine as similar to a steam power plant but using air instead of water. The main parts of a gas turbine are identified as the inlet, compressor, shaft, burner, turbine, and nozzle. Types of gas turbines covered include turbojet, turbofan, turboprop, and afterburning turbojet. Applications discussed are their use in marine vessels, aircraft jet propulsion, small micro gas turbines in devices like the Bladon jet engine, and electricity generation including at remote oil and gas sites from 5-500 megawatts.
This document discusses gas turbines, including their components and how they work. It describes the key components - compressors, combustors, and turbines - and explains the basic Brayton cycle of compression, combustion, and expansion that produces power. It also covers gas turbine applications in aircraft engines and industrial settings, and discusses performance factors like efficiency and output over varying operating conditions.
This document discusses gas turbines, including their basic components and working principle. A gas turbine combusts fuel in the presence of compressed air, converting the thermal energy of the combustion products into mechanical energy. The main components are the compressor, combustion chamber, and turbine. The compressed air is mixed with fuel and burned in the combustion chamber. The hot gases then power the turbine before being exhausted. Gas turbines have applications in vehicles, aircraft, ships, and power generation.
Gas turbine power plants work by compressing air which is then mixed with fuel and ignited in a combustion chamber. This powers a turbine, which drives both a generator to produce electricity and the air compressor. Gas turbines have three main parts - an air compressor, combustion chamber, and turbine. They can use fuels like oil, natural gas, or pulverized coal and are used for power generation especially for peak loads or as backup. Advantages include easier fuel storage and handling as well as lower maintenance costs compared to steam plants.
This document discusses gas turbines, including their basic components and working principle. A gas turbine combusts fuel in the presence of compressed air, converting the thermal energy of the combustion products into mechanical energy. The main components are the compressor, combustion chamber, and turbine. The compressed air is mixed with fuel and burned in the combustion chamber. The hot gases then power the turbine before being exhausted. Gas turbines have applications in vehicles, aircraft, ships, and power generation.
A gas power plant consists of an air compressor, combustion chamber, gas turbine, alternator, and starting motor. Air is compressed and mixed with fuel in the combustion chamber, where combustion increases the temperature and pressure. The high-pressure combusted air expands through the gas turbine, rotating the generator to produce electricity. A starting motor initially rotates the compressor.
Alstom provides gas power plant solutions that are reliable, versatile, and environmentally friendly. They have over 70 years of experience in designing, constructing, and commissioning gas power plants around the world. Their gas power plant experts are committed to meeting customer needs for retrofitting existing plants or designing new plants from the ground up.
1) Gas turbine power plants work by compressing air, mixing it with fuel and igniting it to spin a turbine. The turbine powers a generator and compressor.
2) Open cycle plants draw in air, exhaust it out. Closed cycle plants circulate a working fluid. Improving open cycle efficiency involves regeneration, reheating, or intercooling.
3) Combining gas turbines with steam plants improves efficiency by using exhaust heat to generate steam. Combining with diesels involves turbocharging, a gas generator, or a compound engine configuration.
The gas turbine is an internal combustion engine that uses air as the working fluid. The engine extracts chemical energy from fuel and converts it to mechanical energy using the gaseous energy of the working fluid (air) to drive the engine and propeller, which, in turn, propel the airplane.
Gas turbine plants use compressed air and combustion to drive a turbine and generate power. They have high efficiency, quick start-up times, and can use different fuels. The key components are an air compressor, combustor, and turbine connected by a common shaft. Air is compressed then mixed with fuel and ignited in the combustor. The hot gases drive the turbine which powers the compressor and generator. Axial compressors are commonly used due to their ability to deliver large air volumes at moderate pressures.
A combined cycle power plant generates electricity in two stages. First, a gas turbine burns fuel to drive a generator and produce electricity, with the exhaust heat recovered. This waste heat is then used to create steam to drive a steam turbine and generate additional electricity. Combined cycle power plants can achieve efficiencies as high as 55% and produce up to 50% more electricity than traditional simple-cycle plants from the same fuel. They have advantages of higher efficiency, lower emissions, and ability to run on different fuels, but also have higher costs and are less responsive than other power plant types.
Gas power plants generate electricity through combustion in a gas turbine. They work on the Brayton cycle - compressed air is combusted with fuel and the expanding hot gases spin a turbine connected to a generator. Key components include a compressor, combustion chamber, gas turbine and generator. Gas power plants have high power-to-weight ratios, require less water than steam plants, and take up less space, though their efficiency drops at partial load. Natural gas is the primary fuel used in gas power plants globally.
This document provides an overview of gas turbine engines. It discusses the history of gas turbine engines, including early developments in England, Germany, and the United States. It then describes the basic process of how gas turbine engines work, including the compressor, combustion chamber, and turbine. Finally, it discusses the different types of gas turbine engines, such as centrifugal flow, axial flow, and centrifugal-axial flow engines.
GAS TURBINES IN SIMPLE CYCLE & COMBINED CYCLE APPLICATIONSAbdelrhman Uossef
1. Gas turbines can operate in simple cycle mode, where the turbine directly drives a generator or compressor, or in combined cycle mode.
2. In simple cycle power generation, the gas turbine shaft is directly coupled to the generator to produce electricity.
3. Gas turbines used in simple cycle applications include models from Siemens, Alstom, Rolls Royce and General Electric ranging from 10-300 MW electrical output.
The document discusses the Ramgarh gas thermal power station in Rajasthan, India. It is the first gas thermal power plant in the state. The power station sources gas fuel from suppliers like GAIL, ONGC, and OIL. It has over 200 engineers and technical workers. The document then explains the basic working principles of a gas turbine, including how compressed air and fuel are combusted to spin the turbine and generate power. It also discusses the stages of operation, combined cycle process, advantages like lower maintenance costs, and disadvantages like lower thermal efficiency.
The gas turbine is an internal combustion engine that uses air as the working fluid. The engine extracts chemical energy from fuel and converts it to mechanical energy using the gaseous energy of the working fluid (air) to drive the engine and propeller, which, in turn, propel the aeroplane.
The document discusses various types of jet propulsion engines. It begins by explaining the design and construction of early gas turbine engines prior to WWII. It then covers the major types of jet propulsion in use today including rockets, ramjets, pulsejets, and gas turbine engines. For gas turbine engines, it describes the basic components and functioning of turbojet, turboprop, turboshaft, and turbofan engines. It also discusses engine components such as air inlet ducts, compressors, and combustion sections.
Gas turbine engines derive their power from burning fuel in a combustion chamber and using the fast flowing combustion gases to drive a turbine in much the same way as the high pressure steam drives a steam turbine.
The gas turbine is the engine at the heart of the power plant that produces electric current. A gas turbine is a combustion engine that can convert natural gas or other liquid fuels to mechanical energy. This energy then drives a generator that produces electrical energy.
In a gas turbine, gas is ignited under pressure and combustible high-pressure, high-temperature gases are produced. The combustible gases power a turbine, which in turn powers a generator. In a boiler power plant, electricity is generated by heating water to produce steam which, via a turbine, powers a generator.
The document discusses gas turbine technology. It begins by defining a gas turbine as a machine that delivers mechanical power using a gaseous working fluid. It then discusses the main components of a gas turbine - the compressor, combustion chamber, and turbine. The document covers various gas turbine cycles including open and closed cycles. It also discusses ways to improve gas turbine efficiency such as intercooling, reheating, and regeneration. The document provides an overview of gas turbine applications and operating principles.
Energy Efficiency in Diesel Generator Operationeecfncci
Diesel generators are highly consuming equipment in Nepalese industry. This presentation explains how to operate Diesel Gensets efficiently. It was prepared for energy auditor training in Nepal in the context of GIZ/NEEP programme. For further information go to EEC webpage: http://www.eec-fncci.org
A gas turbine drives a reciprocating compressor to compress natural gas from a pipeline at 55 bar into underground storage caverns at 150 bar. A two-stage gearbox connects the gas turbine to the compressor, stepping down the turbine speed of 333 rpm for the compressor. Gas turbines convert the heat of fuel into mechanical energy via compression, combustion, and expansion components to power generators or machinery. They are more efficient than other internal combustion engines due to operating in a continuous thermodynamic cycle.
1. A gas turbine uses a gaseous working fluid that is compressed in a compressor, heated in a combustion chamber, and expanded through a turbine to produce mechanical power.
2. Early gas turbines had low efficiency but could start quickly, so they were used to provide peak power loads. Improved materials and cooling techniques have increased efficiency over time.
3. The ideal gas turbine cycle is known as the Joule-Brayton cycle and consists of isentropic compression, constant pressure heating, isentropic expansion, and isobaric closure back to the initial state.
Gas turbine power plants work by compressing air which is then mixed with fuel and ignited in a combustion chamber. This causes hot gases to expand through turbine wheels, rotating the shaft to power the compressor and generator. Around 65% of the turbine's power runs the compressor. Key components include the compressor, combustion chamber, and turbine. Gas turbines have advantages of using various cheaper fuels and requiring less water. However, they have lower efficiency than steam plants due to power used to run the compressor.
David Little has over 30 years of experience in quality control and quality assurance roles in the pharmaceutical manufacturing industry. He has held various positions ensuring compliance with cGMP regulations and standard operating procedures. Most recently, he worked as a certified formulation technician for SABIC Innovative Plastics where he formulated resin powder batches. Prior to that, he spent over 30 years at Bristol-Myers Squibb in quality documentation, packaging inspection, and auditing roles. He is skilled in computer systems including SAP, LIMs, Trackwise, and Maximo.
About this Training Course
To provide attendees with a detailed understanding of the calculations required to evaluate the performance of a
Combined Cycle Gas Turbine (CCGT) Power Plant. Provide an understanding of the requirements as regards implementing a successful performance evaluation strategy for a Combined Cycle Gas Turbine Power Plant
Key Learning Outcome
Performance Test Calculations
Power Output/Heat Rate Calculations
Correction Factors
Performance Monitoring
Performance Diagnostics
Performance Improvements
Combined Cycle GT Plant Overview
Performance Terms and Definitions
Brayton Cycle
Rankine Cycle
Combined Cycle
Performance Test Objectives
Uncertainty Analysis
Who Should Attend
This course would be ideal for any engineer requiring an understanding of the thermodynamic calculations required to assess the performance of a CCGT Power Plant. Attendees would be encouraged to bring their own plant data for discussion during the course.
Alstom provides gas power plant solutions that are reliable, versatile, and environmentally friendly. They have over 70 years of experience in designing, constructing, and commissioning gas power plants around the world. Their gas power plant experts are committed to meeting customer needs for retrofitting existing plants or designing new plants from the ground up.
1) Gas turbine power plants work by compressing air, mixing it with fuel and igniting it to spin a turbine. The turbine powers a generator and compressor.
2) Open cycle plants draw in air, exhaust it out. Closed cycle plants circulate a working fluid. Improving open cycle efficiency involves regeneration, reheating, or intercooling.
3) Combining gas turbines with steam plants improves efficiency by using exhaust heat to generate steam. Combining with diesels involves turbocharging, a gas generator, or a compound engine configuration.
The gas turbine is an internal combustion engine that uses air as the working fluid. The engine extracts chemical energy from fuel and converts it to mechanical energy using the gaseous energy of the working fluid (air) to drive the engine and propeller, which, in turn, propel the airplane.
Gas turbine plants use compressed air and combustion to drive a turbine and generate power. They have high efficiency, quick start-up times, and can use different fuels. The key components are an air compressor, combustor, and turbine connected by a common shaft. Air is compressed then mixed with fuel and ignited in the combustor. The hot gases drive the turbine which powers the compressor and generator. Axial compressors are commonly used due to their ability to deliver large air volumes at moderate pressures.
A combined cycle power plant generates electricity in two stages. First, a gas turbine burns fuel to drive a generator and produce electricity, with the exhaust heat recovered. This waste heat is then used to create steam to drive a steam turbine and generate additional electricity. Combined cycle power plants can achieve efficiencies as high as 55% and produce up to 50% more electricity than traditional simple-cycle plants from the same fuel. They have advantages of higher efficiency, lower emissions, and ability to run on different fuels, but also have higher costs and are less responsive than other power plant types.
Gas power plants generate electricity through combustion in a gas turbine. They work on the Brayton cycle - compressed air is combusted with fuel and the expanding hot gases spin a turbine connected to a generator. Key components include a compressor, combustion chamber, gas turbine and generator. Gas power plants have high power-to-weight ratios, require less water than steam plants, and take up less space, though their efficiency drops at partial load. Natural gas is the primary fuel used in gas power plants globally.
This document provides an overview of gas turbine engines. It discusses the history of gas turbine engines, including early developments in England, Germany, and the United States. It then describes the basic process of how gas turbine engines work, including the compressor, combustion chamber, and turbine. Finally, it discusses the different types of gas turbine engines, such as centrifugal flow, axial flow, and centrifugal-axial flow engines.
GAS TURBINES IN SIMPLE CYCLE & COMBINED CYCLE APPLICATIONSAbdelrhman Uossef
1. Gas turbines can operate in simple cycle mode, where the turbine directly drives a generator or compressor, or in combined cycle mode.
2. In simple cycle power generation, the gas turbine shaft is directly coupled to the generator to produce electricity.
3. Gas turbines used in simple cycle applications include models from Siemens, Alstom, Rolls Royce and General Electric ranging from 10-300 MW electrical output.
The document discusses the Ramgarh gas thermal power station in Rajasthan, India. It is the first gas thermal power plant in the state. The power station sources gas fuel from suppliers like GAIL, ONGC, and OIL. It has over 200 engineers and technical workers. The document then explains the basic working principles of a gas turbine, including how compressed air and fuel are combusted to spin the turbine and generate power. It also discusses the stages of operation, combined cycle process, advantages like lower maintenance costs, and disadvantages like lower thermal efficiency.
The gas turbine is an internal combustion engine that uses air as the working fluid. The engine extracts chemical energy from fuel and converts it to mechanical energy using the gaseous energy of the working fluid (air) to drive the engine and propeller, which, in turn, propel the aeroplane.
The document discusses various types of jet propulsion engines. It begins by explaining the design and construction of early gas turbine engines prior to WWII. It then covers the major types of jet propulsion in use today including rockets, ramjets, pulsejets, and gas turbine engines. For gas turbine engines, it describes the basic components and functioning of turbojet, turboprop, turboshaft, and turbofan engines. It also discusses engine components such as air inlet ducts, compressors, and combustion sections.
Gas turbine engines derive their power from burning fuel in a combustion chamber and using the fast flowing combustion gases to drive a turbine in much the same way as the high pressure steam drives a steam turbine.
The gas turbine is the engine at the heart of the power plant that produces electric current. A gas turbine is a combustion engine that can convert natural gas or other liquid fuels to mechanical energy. This energy then drives a generator that produces electrical energy.
In a gas turbine, gas is ignited under pressure and combustible high-pressure, high-temperature gases are produced. The combustible gases power a turbine, which in turn powers a generator. In a boiler power plant, electricity is generated by heating water to produce steam which, via a turbine, powers a generator.
The document discusses gas turbine technology. It begins by defining a gas turbine as a machine that delivers mechanical power using a gaseous working fluid. It then discusses the main components of a gas turbine - the compressor, combustion chamber, and turbine. The document covers various gas turbine cycles including open and closed cycles. It also discusses ways to improve gas turbine efficiency such as intercooling, reheating, and regeneration. The document provides an overview of gas turbine applications and operating principles.
Energy Efficiency in Diesel Generator Operationeecfncci
Diesel generators are highly consuming equipment in Nepalese industry. This presentation explains how to operate Diesel Gensets efficiently. It was prepared for energy auditor training in Nepal in the context of GIZ/NEEP programme. For further information go to EEC webpage: http://www.eec-fncci.org
A gas turbine drives a reciprocating compressor to compress natural gas from a pipeline at 55 bar into underground storage caverns at 150 bar. A two-stage gearbox connects the gas turbine to the compressor, stepping down the turbine speed of 333 rpm for the compressor. Gas turbines convert the heat of fuel into mechanical energy via compression, combustion, and expansion components to power generators or machinery. They are more efficient than other internal combustion engines due to operating in a continuous thermodynamic cycle.
1. A gas turbine uses a gaseous working fluid that is compressed in a compressor, heated in a combustion chamber, and expanded through a turbine to produce mechanical power.
2. Early gas turbines had low efficiency but could start quickly, so they were used to provide peak power loads. Improved materials and cooling techniques have increased efficiency over time.
3. The ideal gas turbine cycle is known as the Joule-Brayton cycle and consists of isentropic compression, constant pressure heating, isentropic expansion, and isobaric closure back to the initial state.
Gas turbine power plants work by compressing air which is then mixed with fuel and ignited in a combustion chamber. This causes hot gases to expand through turbine wheels, rotating the shaft to power the compressor and generator. Around 65% of the turbine's power runs the compressor. Key components include the compressor, combustion chamber, and turbine. Gas turbines have advantages of using various cheaper fuels and requiring less water. However, they have lower efficiency than steam plants due to power used to run the compressor.
David Little has over 30 years of experience in quality control and quality assurance roles in the pharmaceutical manufacturing industry. He has held various positions ensuring compliance with cGMP regulations and standard operating procedures. Most recently, he worked as a certified formulation technician for SABIC Innovative Plastics where he formulated resin powder batches. Prior to that, he spent over 30 years at Bristol-Myers Squibb in quality documentation, packaging inspection, and auditing roles. He is skilled in computer systems including SAP, LIMs, Trackwise, and Maximo.
About this Training Course
To provide attendees with a detailed understanding of the calculations required to evaluate the performance of a
Combined Cycle Gas Turbine (CCGT) Power Plant. Provide an understanding of the requirements as regards implementing a successful performance evaluation strategy for a Combined Cycle Gas Turbine Power Plant
Key Learning Outcome
Performance Test Calculations
Power Output/Heat Rate Calculations
Correction Factors
Performance Monitoring
Performance Diagnostics
Performance Improvements
Combined Cycle GT Plant Overview
Performance Terms and Definitions
Brayton Cycle
Rankine Cycle
Combined Cycle
Performance Test Objectives
Uncertainty Analysis
Who Should Attend
This course would be ideal for any engineer requiring an understanding of the thermodynamic calculations required to assess the performance of a CCGT Power Plant. Attendees would be encouraged to bring their own plant data for discussion during the course.
Turbine Controls Limited develops standardized gas turbine control systems that provide low cost and faster installation compared to custom systems. The pre-developed systems interface seamlessly with existing plant equipment, improving reliability, functionality, diagnostics, and maintainability. They are designed by engineers using latest techniques to minimize costs and reduce outage times for installation, resulting in quick payback periods. Standard control systems have been developed for GE Frame 3 and 5 engines and Ruston gas turbines from 1MW to 6MW.
The document describes the operation of a gas turbine, specifically the General Electric 9E.03 gas turbine. It discusses the key components and processes, including:
1) Air enters through filters and is compressed in the 17-stage axial compressor, increasing in pressure and temperature.
2) The compressed air then enters the combustion chamber where fuel is injected and ignited, further increasing the temperature and pressure.
3) The high pressure gas expands through the three-stage turbine, extracting energy to power the compressor and drive a generator to produce electricity.
4) Finally, the exhaust gas is emitted through a diffuser and chimney.
Mark VI ST Control Product Overview GEH 6127Mircea Tomescu
The Thermo AssistantTM
option provides a graphical display of temperature
measurements from RTDs and thermocouples. It displays temperature trends and alarms for critical
locations on the turbine and generator. It also provides a summary of the temperature status for the entire
unit.
Vibration Monitoring: The turbine control can interface directly to Bently-Nevada proximity probes for
vibration monitoring of critical turbine components. The 1X vibration level and phase are displayed.
Alarms are provided for excessive vibration levels.
Analog Inputs and Outputs: The turbine control provides a variety of analog inputs and outputs for
monitoring pressures, flows, levels, etc. Inputs include 0-5V, 1-5V, 0-10V,
Kazi Ferdousul Karim has over 3 years of experience in power plant operation. He holds a PG Diploma in Thermal Power Plant Engineering and a B.Tech in Electrical Engineering. He is currently working as an Engineer - Operation at Simhapuri Energy Limited in Nellore, Andhra Pradesh, where he is responsible for the operation of boilers and turbines across 3 x 150 MW units. Prior to this, he has undergone simulator training and on-job training at various thermal power plants across 210 MW and 330 MW combined cycle units.
The document discusses different methods of governing steam turbines to maintain a constant rotational speed despite varying loads. Throttle governing reduces steam pressure through a restricted passage before entering the turbine. Nozzle governing opens and closes sets of nozzles to control steam flow. Bypass governing introduces steam into later turbine stages during overloads. Combination governing uses two methods, typically bypass and nozzle. Electro-hydraulic governing uses electronic, hydraulic, and mechanical components to precisely control steam flow and allow synchronization to power grids for load and frequency regulation.
IBC Asia’s Gas Turbines Conference is the premium communication platform that has been helping operators keep costs down and efficiency up for more than half a decade. Join us at the 8th Annual Gas Turbine Conference in Singapore from 27 – 30 May 2014!
What’s New for 2014?
- 16+ end users with operational experiences on various gas turbine models including 9E, 6B, 9FA/FB, 6FA, LM Serious, M701, SGT 600, V94.2/V94.3A/V93.2
- OEM innovation panel to introduce the latest technologies
- Dedicated technology and spare parts show case and one on one networking session
- New case studies by:
> PetroKazakhstan Kazakhstan on control system retrofit
> PT PLN Indonesia on “peaker” management
> PETRONAS Malaysia on component failure analysis....and many more
For more information visit www.gasturbinesasia.com or contact our customer service for assistance Email: register@ibcasia.com.sg | Call: +65 6508 2401
Power LifeMax* - Solutions forB/E Gas Turbine FleetGE_India
- GE has over 40 years of experience with B/E gas turbine technology and has installed over 3,000 units globally totaling over 224 GW of power.
- GE offers Power LifeMax solutions to maximize the performance and value of mature gas turbine fleets, including the Advanced Gas Path and 9E Max upgrades.
- The Advanced Gas Path upgrade improves heat rate by 1.5% for combined cycle and 1.7% for simple cycle while increasing output by 3.8% for combined cycle and 3.6% for simple cycle. It has over 29,000 fired hours of experience across 8 units.
- The 9E Max upgrade further improves performance with a 6% reduction to combined cycle heat rate
The document provides an overview of various welding techniques including:
- Oxy-fuel gas welding and cutting, one of the earliest techniques developed in 1904 for repair work requiring portable equipment.
- Shielded metal arc welding, developed in 1907, which remains widely used for structural steel, machinery, and more due to its versatility and low cost.
- Submerged arc welding, from 1936, useful for high quality pressure vessels and structural components due to its high deposition rate and radiographic sound welds under flux.
- Gas metal arc welding and flux cored arc welding, from the 1950s, enabling continuous, high quality welding including of stainless steel.
- Gas tungsten arc welding, from 1942, producing
This document provides an agenda for an O&M Gas Turbine course. It lists the instructor's contact information and covers various gas turbine topics including basic knowledge, components, systems, operation, history, cycles, bearing types, valve types, seals, electrical systems, instrumentation loops, and a Solar electric schematic. Slides are included on compressors, electrical systems, and explosion proof equipment. The course aims to give attendees an overview of gas turbine systems and components.
This document summarizes the key components and operation of a gas turbine located at the Panipat Refinery. It includes 5 gas turbines made by BHEL/GE that are MS 6000 single shaft design units with a base load capacity of 30.77 MW each. The major components discussed include the compressor, combustors, turbine section, casings, bearings, and cooling/sealing systems. It also provides details on the basic principles of how a gas turbine works by continuously drawing in air, compressing it, adding fuel to increase its energy, directing the high pressure gas to expand through a turbine, and exhausting the low pressure gas.
Jimmy M. Barker has over 30 years of experience in industrial controls engineering, specializing in gas turbine controls systems. He has worked extensively with GE Mark IV, V, Ve, and VI turbine control systems in both domestic and international power plants. His background includes roles in commissioning, start-up, calibration, maintenance, retrofits, and training on turbine controls. He holds multiple engineering and project management certifications.
This document provides information about gas turbines, including:
- The basic components and working mechanism of a gas turbine, including the compressor, combustor, and turbine.
- Details on the Brayton cycle that gas turbines use.
- Descriptions of key components like the axial compressor and reverse-flow combustor.
- Applications of gas turbines in power generation systems like combined cycle and cogeneration plants.
- Performance variables that affect gas turbine efficiency like ambient temperature and exhaust temperature.
This document provides a summary of aircraft engines, including:
1) It describes the early piston engines used by the Wright Brothers and the development of engines like radial and liquid cooled engines.
2) It explains the basic operation of piston engines using the Otto cycle and common piston engine types like horizontally opposed, Vee, and radial configurations.
3) It introduces gas turbine engines and describes the basic Brayton cycle of compression, combustion, and expansion to produce thrust. Common gas turbine types like turbojets, turbofans, and turboprops are also mentioned.
GE Additive, 21st century Paradigm Shifter - Use cases in GEGE코리아
GE는 최근 20년 이상 적층제조 기술의 연구개발에 투자해왔고, GE의 사업부 내부에서 실제 적층제조 기술을 구현 및 적용했습니다. 성과는 놀라웠죠. 이제 GE는 GE의 고객들과 함께 적층제조를 통한 제조업 혁신과 성공의 길을 가려 합니다.
GE애디티브(GE Additive) 사업부는 GE의 고객 기업들에게 적층제조 기계, 재료, 컨설팅 서비스를 제공합니다. 독일 뮌헨과 미국 피츠버그에 새로 생긴 고객체험센터(CEC, Customer Experience Center)에서는 고객에게 적층제조 기술 분야를 더 효과적으로 지원하고 있습니다.
GE Additive is part of GE, the world’s Digital Industrial Company, transforming industry with software-defined machines and solutions that are connected, responsive and predictive. GE Additive includes additive machine providers Concept Laser and Arcam, along with additive materials provider AP&C.
IGTEC is an independent service provider for gas turbines, generators, motors, and other rotating equipment. Since 2008, IGTEC's team of engineers and technicians have worked in the oil and gas sector, and in 2016 they established IGTEC to meet demand for their services. IGTEC provides high-quality, cost-effective maintenance, repair, overhaul and engineering services for various gas turbine models and other industrial equipment. They have an international sales and support network to serve customers worldwide.
GE ADGT (Aeroderivative Gas Turbines) Products
GE코리아 뉴스레터를 구독하세요! http://goo.gl/IE8WS8
GE코리아 YouTube 채널을 구독하세요! http://goo.gl/M2gc8m
상상을 현실로 만듭니다. Imagination at work.
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GE코리아 슬라이드쉐어: http://www.slideshare.net/GEKorea
Segment Presentation RES Oil and Gas IndustryStephen Furze
This document provides an overview of Innovative Service Solutions for the oil and gas industry. It summarizes the company's values of commitment to quality, partnership, operational excellence, and committed people. It highlights the company's focus on safety, with declining accident rates. It also outlines the company's services across the oil and gas value chain, including equipment services for various applications. Finally, it emphasizes the company's solutions for upstream, midstream, refining, and petrochemical industries.
The document summarizes a value engineering study conducted to replace oil-filled ring main units (RMUs) with sulfur hexafluoride (SF6) gas-insulated RMUs in compact substations at an electric panel factory in Dammam, Saudi Arabia. The study evaluated 8 RMU manufacturers based on total life cycle costs and recommended selecting RMUs from Saudi Lucy as they had the lowest projected costs over a 15-year period. An implementation plan is outlined to revise compact substation designs and procurement processes to transition to the SF6 RMUs from Saudi Lucy.
Cross-fleet solutions: Advancing the performance of other OEM gas turbine fleetsGE Power
GE delivers proven technology to advance the performance and reliability of customers’ other OEM gas turbines, including the 501F/SGT6-5000F and SGT-800.
This document discusses MAN Diesel & Turbo's exhaust gas recirculation (EGR) technology for reducing nitrogen oxide (NOx) emissions from ships to meet upcoming Tier III standards. It provides an overview of EGR, including the system layout, key components, control system, and initial service experience on MAN engines equipped with EGR. EGR works by recirculating a portion of exhaust gas into the engine to reduce combustion temperatures and lower NOx production. MAN has conducted successful sea trials of EGR technology and found no adverse impacts to engine components after over 700 hours of operation.
Reducing costs with condition based maintenance, IBC conference Singapore, 2010Shaun West
This paper described how costs of gas turbine ownership can be reduced based on input of condition based maintenance. Innovative thinking is required coupled with risk management.
TPS’s Rolling Stock Maintenance, Repair and Overhaul (MRO) services are aimed at improving equipment reliability, fleet availability, maintainability and safety. Our dedicated ‘After-Sales Support’ team is focused on enhancing through life value of our customer’s power electronic assets including but not limited to – air conditioning, lighting, control & switchgear, data, auxiliary power supply, alternator & battery raft and door control.
This document discusses efforts taken by Tata Motors to optimize manpower at its Integral Bus Factory in Lucknow, India. It begins with background on Tata Motors and the Integral Bus Factory. An analysis found disproportionate manpower distribution compared to volume contribution. Work measurement studies using MOST identified opportunities to reduce non-value added work, such as by reducing excessive operator motion. Implemented improvements cut standard man-hours by 25% and non-value added work by 9%. The document also examines issues around non-standard work from retrofits and modifications. Data collection helped establish time standards to better plan for irregular non-standard tasks.
- Rolls-Royce focused on developing its after-sales service business as a new business opportunity and customer-centric model through services like "Power by the Hour", "Total Care", and engine health management.
- These services allowed customers to pay predictable maintenance fees based on flight hours and transferred engine maintenance responsibilities to Rolls-Royce, reducing customers' capital costs and improving engine residual values.
- Rolls-Royce's growth in after-sales services helped the company achieve a 10% compound annual growth rate from 2000-2007 through long-term maintenance contracts.
This document provides an overview of Alstom Power Service's strategy. It discusses the power service market opportunity, Alstom's existing fleet and geographic presence, strategic pillars around becoming a full plant service provider, diversifying geographically, differentiating through products, improving processes, and developing people. The strategy focuses on leveraging Alstom's technology leadership and installed base to grow revenues and profitability.
Eaton is a global power management company founded in 1911 that provides electrical, hydraulic, and fuel systems for the aerospace industry. The Aerospace Group is one of Eaton's divisions, generating $1.7 billion in annual sales. It has over 6,700 employees in 27 facilities worldwide. The document discusses Eaton's portfolio and footprint in the aerospace market, highlighting its leadership in components, systems, and aftermarket services across military and commercial aircraft.
Ascent Energy provides recruitment, staffing, and project management services to the global energy sector, including oil and gas, power generation, and alternative energy. They have expertise recruiting specialists and executing large project staffing contracts internationally. Ascent Energy aims to be a leading global partner for recruitment and mobility services to energy companies. Their clients include major oil and gas corporations and utility firms operating worldwide.
The document provides information about Shinjin Engineering Co., including:
- Their history and capabilities in areas such as gas and water treatment, piping, and fabrication.
- Their organization chart and staff experience/qualifications.
- Example projects they have completed for customers like ExxonMobil, Total, and Samsung.
- Their partnership with Kanfa Ingenium Process, which provides process design expertise to complement Shinjin's detailed engineering and project management capabilities.
The document provides information about the capabilities and services of Mitsubishi Hitachi Power Systems Americas' Houston Repair Center (HRC). It summarizes that the HRC has extensive equipment and capabilities for repairing gas and steam turbine components including rotors, interstage seal housings, blades, and diaphragms. It also offers full gas turbine unit refurbishment and has completed repairs for various customers on schedule and on budget.
This document discusses challenges and opportunities in turbomachinery control. It provides an overview of compressor and gas turbine control systems, including their components and how they work. Advanced control systems integrate controllers for better performance than conventional independent PID controllers. Simulation examples show how compressors can surge during process upsets and how controls work to prevent surge by opening anti-surge valves and reducing turbine output. Overall the document focuses on improving machinery reliability and efficiency through advances in control system design.
Sales Presentation: MJB India Gas Turbine ServicesSunil Kumar
MIGTS is an Indian company that provides total service solutions for industrial gas turbines. It has facilities in Ahmedabad equipped for refurbishing gas turbine components through processes like heat treatment, welding, coating and testing. It also has manufacturing capabilities for gas turbine parts through CNC machining and other equipment. MIGTS offers refurbishment, spare parts, engineering services, and sales/leasing of gas turbines to customers in power, oil and gas industries in India.
This document provides an overview of Shanahan Engineering, a construction and maintenance contractor focused on the power generation sector. Some key points:
- The company has over 30 years of experience in over 50 countries and offers construction, maintenance, technical, and consultancy services.
- It has core competencies in power plant construction and maintenance, with experience in gas, steam, and combined cycle turbines as well as other power equipment.
- The company emphasizes health, safety, and environmental standards and policies across its operations.
- It has divisions for construction services, maintenance services, and technical field services that support power plant construction, commissioning, and long-term maintenance needs.
Similar to Pro per energy services/ Gas Turbine Operation and Maintenance (20)
How MJ Global Leads the Packaging Industry.pdfMJ Global
MJ Global's success in staying ahead of the curve in the packaging industry is a testament to its dedication to innovation, sustainability, and customer-centricity. By embracing technological advancements, leading in eco-friendly solutions, collaborating with industry leaders, and adapting to evolving consumer preferences, MJ Global continues to set new standards in the packaging sector.
Understanding User Needs and Satisfying ThemAggregage
https://www.productmanagementtoday.com/frs/26903918/understanding-user-needs-and-satisfying-them
We know we want to create products which our customers find to be valuable. Whether we label it as customer-centric or product-led depends on how long we've been doing product management. There are three challenges we face when doing this. The obvious challenge is figuring out what our users need; the non-obvious challenges are in creating a shared understanding of those needs and in sensing if what we're doing is meeting those needs.
In this webinar, we won't focus on the research methods for discovering user-needs. We will focus on synthesis of the needs we discover, communication and alignment tools, and how we operationalize addressing those needs.
Industry expert Scott Sehlhorst will:
• Introduce a taxonomy for user goals with real world examples
• Present the Onion Diagram, a tool for contextualizing task-level goals
• Illustrate how customer journey maps capture activity-level and task-level goals
• Demonstrate the best approach to selection and prioritization of user-goals to address
• Highlight the crucial benchmarks, observable changes, in ensuring fulfillment of customer needs
buy old yahoo accounts buy yahoo accountsSusan Laney
As a business owner, I understand the importance of having a strong online presence and leveraging various digital platforms to reach and engage with your target audience. One often overlooked yet highly valuable asset in this regard is the humble Yahoo account. While many may perceive Yahoo as a relic of the past, the truth is that these accounts still hold immense potential for businesses of all sizes.
B2B payments are rapidly changing. Find out the 5 key questions you need to be asking yourself to be sure you are mastering B2B payments today. Learn more at www.BlueSnap.com.
Taurus Zodiac Sign: Unveiling the Traits, Dates, and Horoscope Insights of th...my Pandit
Dive into the steadfast world of the Taurus Zodiac Sign. Discover the grounded, stable, and logical nature of Taurus individuals, and explore their key personality traits, important dates, and horoscope insights. Learn how the determination and patience of the Taurus sign make them the rock-steady achievers and anchors of the zodiac.
Navigating the world of forex trading can be challenging, especially for beginners. To help you make an informed decision, we have comprehensively compared the best forex brokers in India for 2024. This article, reviewed by Top Forex Brokers Review, will cover featured award winners, the best forex brokers, featured offers, the best copy trading platforms, the best forex brokers for beginners, the best MetaTrader brokers, and recently updated reviews. We will focus on FP Markets, Black Bull, EightCap, IC Markets, and Octa.
LA HUG - Video Testimonials with Chynna Morgan - June 2024Lital Barkan
Have you ever heard that user-generated content or video testimonials can take your brand to the next level? We will explore how you can effectively use video testimonials to leverage and boost your sales, content strategy, and increase your CRM data.🤯
We will dig deeper into:
1. How to capture video testimonials that convert from your audience 🎥
2. How to leverage your testimonials to boost your sales 💲
3. How you can capture more CRM data to understand your audience better through video testimonials. 📊
The 10 Most Influential Leaders Guiding Corporate Evolution, 2024.pdfthesiliconleaders
In the recent edition, The 10 Most Influential Leaders Guiding Corporate Evolution, 2024, The Silicon Leaders magazine gladly features Dejan Štancer, President of the Global Chamber of Business Leaders (GCBL), along with other leaders.
Company Valuation webinar series - Tuesday, 4 June 2024FelixPerez547899
This session provided an update as to the latest valuation data in the UK and then delved into a discussion on the upcoming election and the impacts on valuation. We finished, as always with a Q&A
Unveiling the Dynamic Personalities, Key Dates, and Horoscope Insights: Gemin...my Pandit
Explore the fascinating world of the Gemini Zodiac Sign. Discover the unique personality traits, key dates, and horoscope insights of Gemini individuals. Learn how their sociable, communicative nature and boundless curiosity make them the dynamic explorers of the zodiac. Dive into the duality of the Gemini sign and understand their intellectual and adventurous spirit.
Top mailing list providers in the USA.pptxJeremyPeirce1
Discover the top mailing list providers in the USA, offering targeted lists, segmentation, and analytics to optimize your marketing campaigns and drive engagement.
Discover timeless style with the 2022 Vintage Roman Numerals Men's Ring. Crafted from premium stainless steel, this 6mm wide ring embodies elegance and durability. Perfect as a gift, it seamlessly blends classic Roman numeral detailing with modern sophistication, making it an ideal accessory for any occasion.
https://rb.gy/usj1a2
2. Field Service Provider of GE Aero
Brief History of Proper Energy Services
Foundation of Pro-Per2007
Field Services Support2008
Field Services Support2009
Foundation of Pro-Per
Renewable and first HEPP
2009
Partnership with2010
Partnership with2011
Reseller Agreement with2011
Supported MAN Diesel & Turbo Field
Services globally in more than 35 countries
Electromechanical I&C and O&M
OEM approved service provider on
Aeroderivatives
Global service provider for Heavy Duty
machines (FR6B, FR9E) and ST
Air filtration Solutions
3. Business Areas
I&C
Field
Service
Provider
O&M
Field Services Pool
Filtration
Solutions
Pro-Per
Renewable Ltd.
Spare
part
sales/Rep
air
Pro-Per Energy
Services Inc.
Pro-Per Energy
Services Inc.
Management & Administrative Support
Manpower Pool for
Renewable Services
I&C
Field
Service
Activities
O&M
4. MISSION
What did we want to achieve :
Focused on customer critical issues,
Signed partnership agreements with
well-known international companies,
DONALDSON- Filtration,
WOOD GROUP- Frame Units,
TCT – Aero
MAN - THM
Created a competitive environment in :
Services,
Parts sales
Repair
Introduced Turkish man power to
internatiol market,
Finally, we are an ALTERNATIVE.
What did we do:
Listen to the customer,
Create competitive environment,
Create options in,
Services
Parts sales
Repair,
Bring international experience into
Turkey,
Partnership with well-known
companies,
Offer Turkish skill set into international
market,
Be an alternative
6. Installation & Commissioning (Turnkey Aero I&C)
Operation and Maintenance (O&M)
Long Term Service Agreement (LTSA)
Rehabilitation (Complete Package Rehabilitation)
Part Sales:
New and/or Refurbished Spare Part Sales:
GT Parts,
Package Parts,
Rotables
GT and Package Parts
Spare Engine (LM2500 (+), LM6000)
Maintenance Activities:
Hot Section Exchange (HSE)
Parts & Consumables
Tooling
Field Service Support
Major Over Haul (MOH)
OEM Parts
OEM Repair / Replace Procedures,
Aeroderivatives Units LM 2500 and LM 6000
OEM Approved Service Provider
7. TCT is Authorized Service Provider on :
Avon,
RB-211
SERVICES :
Inspections,
Parts sales,
Repair,
Technical guidance,
Zero-time overhaul
Part repair,
Mid-life and Major repairs,
Removal and Installations,
Modular exchange
Engine Test
Performance Analysis
Rolls – Royce Units
OEM Approved Service Provider
8. LM6000, LM2500, Frame (6, 9E)
EPC
I&C
Combustor Inspection (CI)
Hot Gas Path
Major
Bucket replacement
Troubleshooting
Control System support
MV
MVIWG-Refurbished Unit Sales
WG-Heavy Duty Maintenance
WG-Steam Turbine (up to 70MW)
Major Maintenance
Parts Repair
Refurbished parts sales,
Field Service
Aero and Heavy Duty Parts
GT and Package parts
WG-Component Repair
16. Thank Your for your Attention…
PROFESYONEL PERSONEL HIZMETLERI TIC. AS
Esentepe Mah. Kasap Sk. No 4 Özden Konak Apt. Kat ;1 D.1
34394 Sisli – İSTANBUL / TURKEY
Phone : +90 212 347 51 51
www.pro-per.net
info@pro-per.net
https://www.facebook.com/proper.energy
https://www.facebook.com/pages/Pro-Per-Energy-Services/2496541984964