This thermal power plant is about The Thermal Power Plant which is situated in 'Manigram' in "West Bengal". It will do quite a presentation as thermal power plant and workings of it.
Thermal Power Plant - Full Detail About Plant and Parts (Also Contain Animate...Shubham Thakur
A thermal power station is a power plant in which the prime mover is steam driven. Water is heated, turns into steam and spins a steam turbine which drives an electrical generator. After it passes through the turbine, the steam is condensed in a condenser and recycled to where it was heated; this is known as a Rankine cycle. The greatest variation in the design of thermal power stations is due to the different fossil fuel resources generally used to heat the water. Some prefer to use the term energy center because such facilities convert forms of heat energy into electrical energy.[1] Certain thermal power plants also are designed to produce heat energy for industrial purposes of district heating, or desalination of water, in addition to generating electrical power. Globally, fossil fueled thermal power plants produce a large part of man-made CO2 emissions to the atmosphere, and efforts to reduce these are varied and widespread.
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Coal-based thermal power plants generate electricity through a four stage process. In the first stage, coal is burned in a boiler to produce heat energy. In the second stage, this heat is used to convert water to high-pressure steam. The third stage involves using this steam to spin turbines connected to generators. Finally, in the fourth stage the rotational energy of the turbines is converted to electrical energy. Key components of coal power plants include the coal handling system, boiler, steam turbine, condenser, ash handling system, and electrical equipment. Newer ultra-supercritical technologies can improve the efficiency and reduce emissions of coal power generation.
The document describes the key components and processes involved in a typical coal-fired thermal power plant, including the boiler, turbine, condenser, coal handling equipment, and other auxiliary systems. It also provides diagrams to illustrate the general layout and flow of energy conversion from coal to steam to mechanical power to electricity. Additionally, it briefly mentions some major thermal power plants located in the state of Rajasthan, India.
Thermal power plants operate using the Rankine cycle. Water is heated into steam in a boiler using heat from burning fuel. The high-pressure steam drives turbines which are coupled to generators, producing electricity. The low-pressure exhaust steam from the turbines is condensed into water in a condenser, where it is pumped back into the boiler to repeat the cycle. Thermal power plants contribute the majority of electricity generation in India due to their ability to efficiently convert fuel into power on a large scale.
Introduction To Thermal Power Plant (Steam power plant)
GENERAL LAYOUT OF THERMAL POWER PLANT
COAL HANDLING PLANT
Power Plant cycles
1. Feed Water Cycle
2. Steam Cycle
3. Condensate Cycle
4. Cooling Water Cycle
5. Air And Flue Gas Cycle
Important Power plant equipment
Deaerator
Boiler Feed Water Pump
Heaters
Economiser
Boiler
BOILER DRUM ( STEAM DRUM)
SUPER HEATER
TURBINE
CONDENSER
Thermal power plants generate electricity by burning coal to produce steam that drives turbines connected to generators. They are a major source of electricity in many countries. In India, thermal power plants make up 75% of electricity generation. Coal is pulverized and burned in a boiler to heat water into steam. The high-pressure steam spins turbines that power generators to produce electricity. The steam is then condensed in a condenser using cooling water from cooling towers before being returned to the boiler as feedwater to repeat the process. While thermal plants provide reliable base-load power, they also produce significant air pollution and carbon emissions.
Best ppt on thermal power station workingRonak Thakare
The document provides an overview of thermal power generation and the key components involved. It discusses how chemical energy from fuel is converted through various processes into electrical energy. The main components that enable this conversion are the boiler, turbine, and generator. Steam generated in the boiler powers the turbine, which spins the generator's rotor to produce electricity via electromagnetic induction. The turbine has high, intermediate, and low pressure sections to efficiently extract energy from the steam.
This document provides an overview of a thermal power plant. It begins with an introduction stating that India relies heavily on thermal power which generates around 75% of its electricity. The document then describes the major components of a thermal power plant including the coal handling plant, boilers, turbines, condensers, and cooling towers. It provides details on how these components work together to generate electricity through the conversion of chemical energy from coal to thermal energy to produce steam and spin turbines which power generators. The document also includes diagrams of the processes and electrical systems within the plant.
Thermal Power Plant - Full Detail About Plant and Parts (Also Contain Animate...Shubham Thakur
A thermal power station is a power plant in which the prime mover is steam driven. Water is heated, turns into steam and spins a steam turbine which drives an electrical generator. After it passes through the turbine, the steam is condensed in a condenser and recycled to where it was heated; this is known as a Rankine cycle. The greatest variation in the design of thermal power stations is due to the different fossil fuel resources generally used to heat the water. Some prefer to use the term energy center because such facilities convert forms of heat energy into electrical energy.[1] Certain thermal power plants also are designed to produce heat energy for industrial purposes of district heating, or desalination of water, in addition to generating electrical power. Globally, fossil fueled thermal power plants produce a large part of man-made CO2 emissions to the atmosphere, and efforts to reduce these are varied and widespread.
For Video on Themal Power Plant (Animated Working Video) :- https://www.youtube.com/watch?v=ouWOhk1INjo
Subscribe To Our Youtube Channel For More Videos:-
https://www.youtube.com/TheEngineeringScienc
Click Here To Subscribe:-
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Coal-based thermal power plants generate electricity through a four stage process. In the first stage, coal is burned in a boiler to produce heat energy. In the second stage, this heat is used to convert water to high-pressure steam. The third stage involves using this steam to spin turbines connected to generators. Finally, in the fourth stage the rotational energy of the turbines is converted to electrical energy. Key components of coal power plants include the coal handling system, boiler, steam turbine, condenser, ash handling system, and electrical equipment. Newer ultra-supercritical technologies can improve the efficiency and reduce emissions of coal power generation.
The document describes the key components and processes involved in a typical coal-fired thermal power plant, including the boiler, turbine, condenser, coal handling equipment, and other auxiliary systems. It also provides diagrams to illustrate the general layout and flow of energy conversion from coal to steam to mechanical power to electricity. Additionally, it briefly mentions some major thermal power plants located in the state of Rajasthan, India.
Thermal power plants operate using the Rankine cycle. Water is heated into steam in a boiler using heat from burning fuel. The high-pressure steam drives turbines which are coupled to generators, producing electricity. The low-pressure exhaust steam from the turbines is condensed into water in a condenser, where it is pumped back into the boiler to repeat the cycle. Thermal power plants contribute the majority of electricity generation in India due to their ability to efficiently convert fuel into power on a large scale.
Introduction To Thermal Power Plant (Steam power plant)
GENERAL LAYOUT OF THERMAL POWER PLANT
COAL HANDLING PLANT
Power Plant cycles
1. Feed Water Cycle
2. Steam Cycle
3. Condensate Cycle
4. Cooling Water Cycle
5. Air And Flue Gas Cycle
Important Power plant equipment
Deaerator
Boiler Feed Water Pump
Heaters
Economiser
Boiler
BOILER DRUM ( STEAM DRUM)
SUPER HEATER
TURBINE
CONDENSER
Thermal power plants generate electricity by burning coal to produce steam that drives turbines connected to generators. They are a major source of electricity in many countries. In India, thermal power plants make up 75% of electricity generation. Coal is pulverized and burned in a boiler to heat water into steam. The high-pressure steam spins turbines that power generators to produce electricity. The steam is then condensed in a condenser using cooling water from cooling towers before being returned to the boiler as feedwater to repeat the process. While thermal plants provide reliable base-load power, they also produce significant air pollution and carbon emissions.
Best ppt on thermal power station workingRonak Thakare
The document provides an overview of thermal power generation and the key components involved. It discusses how chemical energy from fuel is converted through various processes into electrical energy. The main components that enable this conversion are the boiler, turbine, and generator. Steam generated in the boiler powers the turbine, which spins the generator's rotor to produce electricity via electromagnetic induction. The turbine has high, intermediate, and low pressure sections to efficiently extract energy from the steam.
This document provides an overview of a thermal power plant. It begins with an introduction stating that India relies heavily on thermal power which generates around 75% of its electricity. The document then describes the major components of a thermal power plant including the coal handling plant, boilers, turbines, condensers, and cooling towers. It provides details on how these components work together to generate electricity through the conversion of chemical energy from coal to thermal energy to produce steam and spin turbines which power generators. The document also includes diagrams of the processes and electrical systems within the plant.
Thermal Power plant visit Report by Amit Hingeamit307
The document is an industrial visit report on Paras Thermal Power Plant in Akola, India. It provides an overview of the key components and processes of a coal-fired thermal power plant, including coal preparation, boilers, turbines, generators, condensers and cooling towers. Paras Thermal Power Plant is one of the oldest power plants owned by Maharashtra State Power Generation Company, with the first units installed in 1961. It has since been upgraded with newer 250MW units. The report serves to explain the functioning and technical aspects of thermal power generation to students who visited the plant.
Cogeneration involves the sequential conversion of fuel into multiple usable energy forms. It can produce both electrical and thermal energy, unlike conventional systems. There are two types of cogeneration systems - inplant power generation and reject heat utilization. Inplant power generation produces steam at a higher temperature than needed for manufacturing to also generate electricity using a turbine generator. Reject heat utilization uses excess steam from a power plant for manufacturing. Topping cycles produce electricity first while bottoming cycles produce heat first. Cogeneration provides benefits like fuel economy, lower capital costs, and protection from power outages. Common technologies are steam turbine, gas turbine, combined cycle, and diesel engine systems.
This document describes the key components and working of a thermal power plant. It explains that thermal power plants generate electricity by burning fuel to create high pressure steam, which spins a steam turbine connected to a generator. The main components are the boiler, which produces steam from water; a superheater that increases the steam's temperature; and a steam turbine, which is spun by the steam and connected to a generator to produce electricity. After passing through the turbine, the steam enters a condenser where it is cooled and condensed back into water to repeat the process.
The document expresses gratitude to various people who helped with a vocational training project at a thermal power plant. It thanks the officials who oversaw the project, the power plant staff who provided assistance, and the author's parents for their support in completing the project successfully.
This document provides an overview of the key components and processes in a thermal power plant. It describes how coal is pulverized and burned to generate high-temperature steam in a boiler. The steam then drives turbines which power electrical generators, after which the steam is condensed back into water and recycled through the system in a closed-loop Rankine cycle. The document outlines the basic working principle and lists the main parts of a thermal power plant, including coal conveyors, pulverizers, boilers, turbines and condensers.
This document describes the key components and processes involved in a thermal power plant. Water is heated to produce steam, which spins turbines connected to generators to produce electricity. The main components are the boiler, turbines, condenser, cooling tower and auxiliary systems. Coal is pulverized and burned in the boiler to heat water and produce high pressure steam. The steam powers high, intermediate and low pressure turbines in succession to generate electricity before being condensed back into water in the condenser. The water is cooled in the cooling tower and recycled to the boiler to repeat the process.
This presentations contains the basic layout of a thermal power palnt along with the components.Coal and it's types.Future of thermal power plant in India.
This document discusses coal-based thermal power plants. It describes the basic cycles used in thermal power generation like the Rankine cycle. It then discusses the major components of a typical coal fired thermal power station like the coal handling plant, ash handling system, boiler, turbine and condenser. The coal handling plant prepares and feeds coal to the boiler. In the boiler, coal is burnt and water is converted to high pressure steam. This steam powers the turbine, which drives the generator to produce electricity. The exhaust steam from the turbine is condensed back to water in the condenser to complete the cycle.
This document provides an overview of a thermal power station. It begins with defining a thermal power station as a generating station that converts the heat energy from coal combustion into electrical energy. It then outlines the main components of a thermal power station in a block diagram and lists the main equipment, including the coal handling plant, pulverizing plant, boiler, turbine, alternator, condenser, and cooling towers. Each of the major equipment is then explained in more detail. Finally, the document discusses the advantages of thermal power stations in being able to use cheap fuel and their disadvantages in polluting the atmosphere.
The document provides an overview of thermal power generation. It discusses the need for thermal power, the basic working principles, and classifications by fuel and prime mover. The key steps in the thermal power generation process include heating water to create steam, using the steam to power a turbine connected to a generator to produce electricity, and then condensing the steam to be reused. Thermal power plants have advantages of using widely available fuels but have lower efficiency and higher emissions than other generation methods. Improving plant efficiency and reducing emissions are important areas of ongoing research and development.
A thermal power station converts heat energy into electrical power by boiling water to produce steam that spins turbines connected to electrical generators. Water is heated in a boiler, turning it into high-pressure steam that drives the turbine, which turns a generator to produce electricity. After passing through the turbine, the steam is condensed back into water and recycled to be heated again in a closed loop system. Thermal power stations use various heat sources like coal, natural gas, nuclear reactions or solar thermal to produce the steam.
The document provides an overview of the Mejia Thermal Power Station (MTPS) located in West Bengal, India. It is owned by the Damodar Valley Corporation and has a total installed capacity of 2340 MW generated from various units. The document describes the key components of the thermal power plant including the coal handling system, pulverizer, boiler, turbine, condenser, and switchyard. It also provides a step-by-step explanation of how coal is converted into electrical energy within the power station.
The document is a presentation on a practical training and industrial visit to the Kota Super Thermal Power Station in India. It summarizes the key details of the power station in 3 points:
1) The power station has a total installed capacity of 1240 MW and uses coal as its fuel source, sourced from nearby mines. It employs a steam turbine generator system to convert the heat from combustion into electrical power.
2) The power station's operations include a coal handling plant to receive and transport coal via rail, a boiler to produce high pressure steam from coal combustion, a steam turbine to convert steam power into rotational energy, and generators to convert this into electrical power.
3) Ash handling is also
Steam turbines and its associated systems(ntpc ramagundam)abdul mohammad
Steam turbine is an excellent prime mover to convert heat energy of steam to mechanical energy. Of all heat engines and prime movers the steam turbine is nearest to the ideal and it is widely used in power plants and in all industries where power is needed for process.
In power generation mostly steam turbine is used because of its greater thermal efficiency and higher power-to-weight ratio. Because the turbine generates rotary motion, it is particularly suited to be used to drive an electrical generator – about 80% of all electricity generation in the world is by use of steam turbines.
Rotor is the heart of the steam turbine and it affects the efficiency of the steam turbine. In this project we have mainly discussed about the working process of a steam turbine. The thermal efficiency of a steam turbine is much higher than that of a steam engine.
Thermal power plants generate electricity through the combustion of fuel to produce steam that drives a steam turbine which spins an electrical generator. The document discusses several key components and considerations for thermal power plants, including their need for large quantities of fuel (typically coal), water, and land for ash storage. It also outlines the basic energy conversion process from fuel to electricity and highlights some common components like boilers, turbines, condensers, and coal and ash handling systems. Locating thermal plants requires consideration of factors like fuel availability, water sources, and ash disposal.
The Thermal Power Station burns fuel & uses the resultant to make the steam, which derives the turbo generator. The Fuel i.e. coal is burnt in pulverized from. The pressure energy of the steam produce is converted into mechanical energy with the help of turbine. The mechanical energy is fed to the generator where the magnet rotate inside a set of stator winding & thus electricity is produced in India 65% of total power is generated by thermal power stations. To understand the working of the Thermal Power Station plant, we can divide the whole process into following parts.
Thermal power plant Khedr, Hisar, HaryanaEesha Gupta
The document provides information about the Rajiv Gandhi Thermal Power Plant (RGTPP) in Khedar, India. It discusses that RGTPP has two units that generate 600 MW each for a total output of 1200 MW per day. It then describes the basic processes that occur in a coal-based thermal power plant, including how coal is converted to steam to drive turbines and generate electricity. The document outlines the major components of RGTPP, including the coal handling system, boiler, turbines, generators, cooling system and instrumentation.
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.
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.
This presentation summarizes information about the Thermal Power Station in Muzafargarh, Pakistan. The key points are:
- The power station has a total installed capacity of 1350 MW generated across 6 units powered by natural gas and furnace oil.
- It uses a Rankine cycle to generate steam from heated water to power turbines and generate electricity.
- The presentation describes the typical components and processes within a thermal power plant, including boilers, turbines, generators, and cooling systems.
- Muzafargarh power station is a major source of electricity in Pakistan's national grid and is operated by the Pakistan Electric Power Company.
This document is a presentation submitted by Arun Kumar to Mr. Puneet Singh on coal handling plant (CHP) at NTPC Dadri power station. It includes an introduction to CHP, availability and transportation of coal in India, analysis of coal samples, and overview of the general CHP layout and auxiliary equipment. The objectives of CHP are to supply processed coal to boiler bunkers and stack excess coal in the yard. The presentation covers the types of coal commonly used in India, various transportation methods, and the operational cycles of bunkering, stacking, and reclaiming coal at the plant.
Dalian LIKE Stacker and Reclaimer Co., Ltd. was incorporated in 2001 in Dalian, China with registered capital of RMB 60 million. It is a subsidiary of Dalian LIKE, a top supplier of hydraulic and electrical systems for bulk material handling equipment in China. The company designs and builds various material handling systems including stackers, reclaimers, wagon tipplers, ship loaders/unloaders, and provides EPC contracting services. It has facilities in China and has completed projects internationally in countries like India, Turkey, Thailand, Korea, Brazil, and more.
Thermal Power plant visit Report by Amit Hingeamit307
The document is an industrial visit report on Paras Thermal Power Plant in Akola, India. It provides an overview of the key components and processes of a coal-fired thermal power plant, including coal preparation, boilers, turbines, generators, condensers and cooling towers. Paras Thermal Power Plant is one of the oldest power plants owned by Maharashtra State Power Generation Company, with the first units installed in 1961. It has since been upgraded with newer 250MW units. The report serves to explain the functioning and technical aspects of thermal power generation to students who visited the plant.
Cogeneration involves the sequential conversion of fuel into multiple usable energy forms. It can produce both electrical and thermal energy, unlike conventional systems. There are two types of cogeneration systems - inplant power generation and reject heat utilization. Inplant power generation produces steam at a higher temperature than needed for manufacturing to also generate electricity using a turbine generator. Reject heat utilization uses excess steam from a power plant for manufacturing. Topping cycles produce electricity first while bottoming cycles produce heat first. Cogeneration provides benefits like fuel economy, lower capital costs, and protection from power outages. Common technologies are steam turbine, gas turbine, combined cycle, and diesel engine systems.
This document describes the key components and working of a thermal power plant. It explains that thermal power plants generate electricity by burning fuel to create high pressure steam, which spins a steam turbine connected to a generator. The main components are the boiler, which produces steam from water; a superheater that increases the steam's temperature; and a steam turbine, which is spun by the steam and connected to a generator to produce electricity. After passing through the turbine, the steam enters a condenser where it is cooled and condensed back into water to repeat the process.
The document expresses gratitude to various people who helped with a vocational training project at a thermal power plant. It thanks the officials who oversaw the project, the power plant staff who provided assistance, and the author's parents for their support in completing the project successfully.
This document provides an overview of the key components and processes in a thermal power plant. It describes how coal is pulverized and burned to generate high-temperature steam in a boiler. The steam then drives turbines which power electrical generators, after which the steam is condensed back into water and recycled through the system in a closed-loop Rankine cycle. The document outlines the basic working principle and lists the main parts of a thermal power plant, including coal conveyors, pulverizers, boilers, turbines and condensers.
This document describes the key components and processes involved in a thermal power plant. Water is heated to produce steam, which spins turbines connected to generators to produce electricity. The main components are the boiler, turbines, condenser, cooling tower and auxiliary systems. Coal is pulverized and burned in the boiler to heat water and produce high pressure steam. The steam powers high, intermediate and low pressure turbines in succession to generate electricity before being condensed back into water in the condenser. The water is cooled in the cooling tower and recycled to the boiler to repeat the process.
This presentations contains the basic layout of a thermal power palnt along with the components.Coal and it's types.Future of thermal power plant in India.
This document discusses coal-based thermal power plants. It describes the basic cycles used in thermal power generation like the Rankine cycle. It then discusses the major components of a typical coal fired thermal power station like the coal handling plant, ash handling system, boiler, turbine and condenser. The coal handling plant prepares and feeds coal to the boiler. In the boiler, coal is burnt and water is converted to high pressure steam. This steam powers the turbine, which drives the generator to produce electricity. The exhaust steam from the turbine is condensed back to water in the condenser to complete the cycle.
This document provides an overview of a thermal power station. It begins with defining a thermal power station as a generating station that converts the heat energy from coal combustion into electrical energy. It then outlines the main components of a thermal power station in a block diagram and lists the main equipment, including the coal handling plant, pulverizing plant, boiler, turbine, alternator, condenser, and cooling towers. Each of the major equipment is then explained in more detail. Finally, the document discusses the advantages of thermal power stations in being able to use cheap fuel and their disadvantages in polluting the atmosphere.
The document provides an overview of thermal power generation. It discusses the need for thermal power, the basic working principles, and classifications by fuel and prime mover. The key steps in the thermal power generation process include heating water to create steam, using the steam to power a turbine connected to a generator to produce electricity, and then condensing the steam to be reused. Thermal power plants have advantages of using widely available fuels but have lower efficiency and higher emissions than other generation methods. Improving plant efficiency and reducing emissions are important areas of ongoing research and development.
A thermal power station converts heat energy into electrical power by boiling water to produce steam that spins turbines connected to electrical generators. Water is heated in a boiler, turning it into high-pressure steam that drives the turbine, which turns a generator to produce electricity. After passing through the turbine, the steam is condensed back into water and recycled to be heated again in a closed loop system. Thermal power stations use various heat sources like coal, natural gas, nuclear reactions or solar thermal to produce the steam.
The document provides an overview of the Mejia Thermal Power Station (MTPS) located in West Bengal, India. It is owned by the Damodar Valley Corporation and has a total installed capacity of 2340 MW generated from various units. The document describes the key components of the thermal power plant including the coal handling system, pulverizer, boiler, turbine, condenser, and switchyard. It also provides a step-by-step explanation of how coal is converted into electrical energy within the power station.
The document is a presentation on a practical training and industrial visit to the Kota Super Thermal Power Station in India. It summarizes the key details of the power station in 3 points:
1) The power station has a total installed capacity of 1240 MW and uses coal as its fuel source, sourced from nearby mines. It employs a steam turbine generator system to convert the heat from combustion into electrical power.
2) The power station's operations include a coal handling plant to receive and transport coal via rail, a boiler to produce high pressure steam from coal combustion, a steam turbine to convert steam power into rotational energy, and generators to convert this into electrical power.
3) Ash handling is also
Steam turbines and its associated systems(ntpc ramagundam)abdul mohammad
Steam turbine is an excellent prime mover to convert heat energy of steam to mechanical energy. Of all heat engines and prime movers the steam turbine is nearest to the ideal and it is widely used in power plants and in all industries where power is needed for process.
In power generation mostly steam turbine is used because of its greater thermal efficiency and higher power-to-weight ratio. Because the turbine generates rotary motion, it is particularly suited to be used to drive an electrical generator – about 80% of all electricity generation in the world is by use of steam turbines.
Rotor is the heart of the steam turbine and it affects the efficiency of the steam turbine. In this project we have mainly discussed about the working process of a steam turbine. The thermal efficiency of a steam turbine is much higher than that of a steam engine.
Thermal power plants generate electricity through the combustion of fuel to produce steam that drives a steam turbine which spins an electrical generator. The document discusses several key components and considerations for thermal power plants, including their need for large quantities of fuel (typically coal), water, and land for ash storage. It also outlines the basic energy conversion process from fuel to electricity and highlights some common components like boilers, turbines, condensers, and coal and ash handling systems. Locating thermal plants requires consideration of factors like fuel availability, water sources, and ash disposal.
The Thermal Power Station burns fuel & uses the resultant to make the steam, which derives the turbo generator. The Fuel i.e. coal is burnt in pulverized from. The pressure energy of the steam produce is converted into mechanical energy with the help of turbine. The mechanical energy is fed to the generator where the magnet rotate inside a set of stator winding & thus electricity is produced in India 65% of total power is generated by thermal power stations. To understand the working of the Thermal Power Station plant, we can divide the whole process into following parts.
Thermal power plant Khedr, Hisar, HaryanaEesha Gupta
The document provides information about the Rajiv Gandhi Thermal Power Plant (RGTPP) in Khedar, India. It discusses that RGTPP has two units that generate 600 MW each for a total output of 1200 MW per day. It then describes the basic processes that occur in a coal-based thermal power plant, including how coal is converted to steam to drive turbines and generate electricity. The document outlines the major components of RGTPP, including the coal handling system, boiler, turbines, generators, cooling system and instrumentation.
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.
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.
This presentation summarizes information about the Thermal Power Station in Muzafargarh, Pakistan. The key points are:
- The power station has a total installed capacity of 1350 MW generated across 6 units powered by natural gas and furnace oil.
- It uses a Rankine cycle to generate steam from heated water to power turbines and generate electricity.
- The presentation describes the typical components and processes within a thermal power plant, including boilers, turbines, generators, and cooling systems.
- Muzafargarh power station is a major source of electricity in Pakistan's national grid and is operated by the Pakistan Electric Power Company.
This document is a presentation submitted by Arun Kumar to Mr. Puneet Singh on coal handling plant (CHP) at NTPC Dadri power station. It includes an introduction to CHP, availability and transportation of coal in India, analysis of coal samples, and overview of the general CHP layout and auxiliary equipment. The objectives of CHP are to supply processed coal to boiler bunkers and stack excess coal in the yard. The presentation covers the types of coal commonly used in India, various transportation methods, and the operational cycles of bunkering, stacking, and reclaiming coal at the plant.
Dalian LIKE Stacker and Reclaimer Co., Ltd. was incorporated in 2001 in Dalian, China with registered capital of RMB 60 million. It is a subsidiary of Dalian LIKE, a top supplier of hydraulic and electrical systems for bulk material handling equipment in China. The company designs and builds various material handling systems including stackers, reclaimers, wagon tipplers, ship loaders/unloaders, and provides EPC contracting services. It has facilities in China and has completed projects internationally in countries like India, Turkey, Thailand, Korea, Brazil, and more.
This document provides instructions for calculating the proper tension for a conveyor belt based on operating conditions and specifications. It outlines 12 key pieces of information needed, such as carrying surface, drive data, environment, loading rate and pulley diameters. It then describes calculating the effective belt tension as the sum of tensions to move the empty belt, load and lift the load. Additional tension is added to prevent slippage. The proper reinforcement ply is then selected based on flexibility, load support and impact resistance. Motor horsepower requirements and maximum tension the system can generate are also calculated.
The document discusses a coal handling plant (CHP) that handles coal from receipt to transporting it to boilers and storage bunkers for a power plant. The power plant has a capacity of 2 x 250 MW located in Bina, Madhya Pradesh. The CHP receives coal via road, rail, or ropeway and uses equipment like wagon tipplers, conveyor belts, crushers, and trippers to process and transport the coal through operational cycles to the boilers and bunkers. Common problems faced by CHPs include design issues, monsoon season impacts, and dealing with oversized or muddy coal.
This document provides an overview of the Badarpur Thermal Power Station (BTPS) owned and operated by NTPC Limited, the largest power generation company in India. It summarizes that BTPS was established in 1973 and transferred to NTPC in 1978. It now has a total installed capacity of 720 MW from 5 units. The document then describes the basic working principles of a steam power plant using the Rankine cycle. It provides diagrams of the typical processes and components involved, including the boiler, turbines, condenser, reheater, and others. Finally, it gives more details on some of the key components and maintenance departments at BTPS.
This document provides an overview of the coal handling plant (CHP) at the Rajmahal area of Eastern Coalfields Limited in India. It discusses the general layout of the CHP including wagon tipplers, bunkers, conveyor belts, screens, crushers and hoppers. It also describes the operating cycle and crushing mechanisms used including double roll crushers, rotary breaker crushers, and impact crushers to crush coal from 600mm to 20-25mm.
This document provides an overview of the coal handling plant (CHP) at the NTPC Ramagundam power station in India. The NTPC is one of the largest power generation companies in India. The Ramagundam station has an installed capacity of 2,600 MW produced across three stages. Coal is a key fuel source and is transported via conveyors from storage to the plant. The CHP uses various safety systems for the conveyors like pull cord switches, belt sway switches, and chute block switches. It also employs technologies like stacker reclaimers and long travel drives to facilitate coal transportation. The summary provides a high-level view of the key details about NTPC, the Ramagundam plant
The document discusses the construction and working of a coal handling plant (CHP). It first introduces what a CHP is and its objectives. It then discusses coal availability and transportation in India, with most coal transported via rail. The general layout of a CHP is shown including equipment like wagon tipplers, conveyor belts, crushers, bunkers and the operational cycles of bunkering, stacking and reclaiming. Key aspects of equipment like tipplers, conveyor belts and the three stage crushing system are described.
NTPC KORBA CHHATTISGARH coal to electricity by tejasvi anant (tan 90')Tejasvi Anant
NTPC is India's largest power company established in 1975. NTPC operates the 2600 MW Korba Super Thermal Power Plant located in Chhattisgarh, India. The plant sources coal from local mines using a merry-go-round rail system. The coal is crushed and milled before being burned in the boiler to produce steam that drives the turbine generator, producing electricity. Flue gases pass through an electrostatic precipitator before being released through the chimney. The generator outputs electricity at 15.75 kV which is stepped up to 400 kV by transformers before connecting to the transmission grid.
Belt conveyors transport solid objects and bulk materials over long distances using a closed loop rubber or textile belt. They are composed of three main parts: the carcass for strength and support, skims for adhesion between carcass layers, and covers to protect the carcass. Belt conveyors use idler rollers to support the belt and tensioning devices like screw or hydraulic take-ups to maintain proper tension as the belt lengthens from use. Inclined conveyors also require holdbacks to prevent the loaded belt from reversing and accelerating out of control.
This document discusses coal handling plants (CHPs) at thermal power stations. It begins with an introduction to coal and its uses. It then discusses the objectives and general layout of a CHP, including receiving coal via various transportation methods, temporary coal storage, crushing equipment, conveying systems, and auxiliary equipment. Specific equipment like wagon tipplers, conveyor belts, crushers, and feeders are explained. The document concludes with discussing coal analysis, maintenance needs of a CHP, and references.
The document provides an overview of the coal handling plant (CHP) at the Nabinagar Power Generating Company located in Bihar, India. The CHP processes 5 million tonnes of coal per year received via wagons to supply coal bunkers for boiler operations at the power plant. The CHP includes a wagon tippler, crushers, conveyor belts, vibrating screens, and bunkers to receive, crush, transport, and store coal prior to feeding the coal mills and furnaces. The document also discusses the transportation, storage, grading, and utilization of coal in thermal power plants in India.
The document describes the key systems and processes involved in a typical coal-based power plant. It discusses the various stages from receiving coal, to grinding and feeding it into the boiler to produce steam, to generating electricity via turbines connected to generators, and finally returning water to a liquid state to repeat the process. The power plant relies on integrated systems to handle coal, water, combustion, electricity production, ash removal and emissions control to efficiently and reliably generate power.
This document provides status updates on the construction and installation of various conveyors that are part of a large coal handling plant. It includes tables with details of completion percentages for each conveyor segment. Some conveyors are fully completed while others require additional work such as belt laying and jointing, drive alignment, and chute and skirt board installation to reach full completion. Challenges are also noted around coordinating work between different contractors.
This document provides information about a coal handling plant (CHP) at a thermal power station. It discusses the general working of a CHP, including receiving coal via various transportation methods, crushing and sizing the coal, storing it in bunkers, and sending it to coal mills. It also addresses common problems faced at CHPs, such as design issues, rainy season challenges, and equipment failures. Additionally, the document proposes designs for managing dust at different stages of the CHP process, such as adding moisture, using wind breaks, compacting coal piles, and installing a wet dust collector to reduce water consumption and dust levels.
The document describes the processes involved in a typical coal handling plant. The key processes are: [1] Unloading coal via wagon tipplers or bottom-opening wagons; [2] Feeding the coal using various feeders like belt, apron or vibrating feeders; [3] Screening to size the coal using screens or rollers; [4] Crushing oversized coal using impact, attrition or compression crushers; [5] Stacking and reclaiming coal using stacker-reclaimers; [6] Bunkering coal into storage bins using trippers. Magnetic separators are used to remove tramp iron from the coal flow. The diagram shows the typical flow of coal from
This document provides an overview of coal handling systems used in coal power plants. It discusses key components like stockpiles, stacker/reclaimers, belt feeders, conveyors, and the control systems used. Stockpiles provide surge capacity and are formed using stackers and reclaimed using reclaimers. Belt feeders carry coal from crushers to conveyors. Safety interlocks and procedures are described for operating components like feeders, conveyors, and stacker/reclaimers to handle coal safely and effectively throughout the coal handling process.
This document provides an overview of a coal handling plant (CHP). It discusses the key components and processes within a CHP, including:
- Transportation of coal primarily via railways to the plant.
- Analysis of incoming coal to check quality matches agreements.
- The general layout and flow of coal through the plant via wagon tipplers, conveyor belts, crushers, and bunkers.
- The crushing process uses a three stage system to reduce coal size.
- Operational cycles to bunker, stack, or reclaim coal depending on bunker levels and maintenance needs.
- Key equipment used includes wagon tipplers, conveyor belts, double roll crushers, rotary break
Barauni Thermal Power Station is a 320 megawatt coal-fired power station in Begusarai district, Bihar, India. It was established in 1962 through Russian collaboration. The power station currently has two operational units producing 220 MW total, while two new 500 MW units are under construction. Coal is supplied from nearby mines and the generated electricity is supplied to North Bihar. The power station aims to increase total capacity to 500 MW in the next five years through renovations.
The Kota Super Thermal Power Station is a 1240MW coal power plant located in Kota, Rajasthan. It uses a steam turbine generator system fueled by coal. Coal is transported via a conveyor system to the boiler, where it is burned to produce steam that drives the turbine generator. The steam is then condensed in condensers using cooling water from the Chambal River. Fly ash from combustion is captured and can be used for products like cement or road construction. The power station began operating in 1983 and has since expanded in stages to its current capacity.
The document summarizes the Bokaro Thermal Power Station located in Jharkhand, India. It has three units that generate a total of 630 MW of power. The power station uses coal as its fuel source, which is handled through a coal handling plant and crushed before being fired in the boiler. The boiler then heats water to create high-pressure steam, which spins turbines connected to generators to produce electricity. The steam is reused in the process by passing through a superheater, economizer and condenser before being treated and reused. Ash is removed using an electrostatic precipitator and handled separately. A control room monitors and regulates the entire power generation process.
Kota Super Thermal Power Station (KSTPS) is located in Kota, India and has a total installed capacity of 1240 MW generated across 7 units. It uses bituminous coal to power steam turbines that drive electricity generators. The main components include the coal handling plant, boiler, steam turbine, generator, and ash handling plant. Coal is delivered by rail, crushed, and conveyed to the boiler which converts it to steam to spin the turbine and generate electricity.
This document summarizes a seminar presented on practical training at the Kota Super Thermal Power Station. It describes the key parts of the power station including the coal handling plant, boiler, turbine, generator, water treatment plant, and switchyard. It provides details on processes like coal crushing and water treatment. The power station has a total generation capacity of 1240 MW across 6 units and uses coal from local mines to power its operations.
ELECTRICAL ENGINEERING THERMAL POWER PLANT Industrial ReportUtkarsh Chaubey
The document is an industrial training report submitted by Utkarsh Chaubey to Rajiv Gandhi Proudyogiki Vishwavidyalaya. It provides an overview of Utkarsh's training at the Shri Singaji Thermal Power Plant (SSTPP). The report includes sections on the power plant overview, the Rankine cycle used, classification of thermal power plants, typical components of a coal fired plant, site selection considerations, and descriptions of various systems within SSTPP such as the generator, switchyard, transformers, and safety measures.
The document provides information about a 24 week training program at NTPC Limited, India's largest power company. It discusses visits to various divisions at NTPC's power plants in Badarpur and Faridabad to learn about electricity generation. The training was an educational experience that allowed observing the power generation process firsthand. The document then outlines the key components of coal handling plants, power generation processes, and electrical equipment involved in electricity production and distribution.
The document provides information about Harshit Madaan's summer training at Suratgarh Super Thermal Power Station. It includes:
1) An overview of the power station, noting that it has an installed capacity of 1500MW across 6 units, making it the largest power station in Rajasthan.
2) Descriptions of the key components and processes within the power station, including the coal handling plant, boiler, turbine, generator, cooling tower and switchyard.
3) Brief explanations of how the plant generates power through boiling water with coal to create pressurized steam that drives the turbine and generator.
The document provides information about NTPC Dadri, a power plant located in India operated by NTPC. It has a total installed capacity of 2655 MW from coal, gas, and solar sources. The coal-based plant has a capacity of 1820 MW, the gas-based plant 830 MW, and the solar-based plant 5 MW. The document then describes the basic process of how coal is converted to electricity at a thermal power plant. It explains the key equipment used including the coal handling plant, boiler, turbine, condenser, and cooling towers. It provides specific details about NTPC Dadri's coal source and requirements. In summary, the document outlines the different energy sources and installed capacity at NTPC Dad
Kota Super Thermal Power Station is a coal-based power plant located in Kota, India. It has a total generation capacity of 1240MW from its units commissioned between 1983 and 2009. The power plant uses a coal handling plant to transport coal via conveyor belts to the boilers, which heat water to produce steam that drives turbines connected to generators. Key components include the boiler, superheater, economizer, air preheater, condenser, and ash handling system. Water is treated on site before being fed to the boilers. The control room monitors operations and measurements across the plant.
The document provides information about the layout and components of the Raj West Power Plant in Barmer, Rajasthan, India. The plant will be a 1080MW lignite-based thermal power plant using circulating fluidized bed combustion technology. Coal will be sourced from nearby mines through a joint venture company. The general layout and components of a thermal power plant are described, including coal handling, the boiler, turbine, generator, condenser, and ash handling. Key specifications of equipment like circuit breakers and isolators in the switchyard are also mentioned.
The document provides information about a thermal power simulator training that took place at Essar Power Gujarat Ltd in Jamnagar, India. It acknowledges the organizers and mentors of the training. It then provides details about the Salaya power plant including its location, phases, capacity and key components. It describes the specifics of the 2x600 MW simulator used for training including its advantages. The document outlines the daily plan for the training and provides an overview of the key systems and circuits within the thermal power plant such as the boiler, turbine, generators, transformers and main circuits.
1. The document provides an acknowledgement and thanks to various individuals and departments at NTPC Tanda for allowing the training and providing support and knowledge.
2. It then outlines the content which will be covered, including a brief description of the Tanda thermal project, production of electricity, description of the thermal plant, basic cycle of a power plant, control and instrumentation unit, and important equipment of the plant.
3. It begins describing the Tanda thermal project, providing its geographical location, features such as its installed capacity and suppliers, and performance metrics like its designed boiler efficiency.
The document summarizes the training seminar on the Kota Super Thermal Power Station. It describes the power station's establishment in 1973 with initial capacity of 220 MW expanding to 1240 MW currently. It details the main components of the plant including the coal handling plant, boiler, superheater, steam turbine, generator, cooling system, and ash handling plant. The layout and functioning of each component is briefly explained.
This document provides an overview of the Suratgarh Super Thermal Power Plant located in Kota, India. It discusses the plant's layout and key components including 5 power generation units with a total capacity of 1500MW, a coal handling plant, water treatment facilities, boilers, turbines, generators, transformers, switchyards, ash handling, electrostatic precipitators, cooling towers and the control room. The presentation concludes with the student expressing their gratitude for the opportunity to tour the large-scale facility and gain practical engineering insights.
The document provides an overview of the Mejia Thermal Power Station located in West Bengal, India. It discusses the key components and processes involved in generating power at the plant, including:
- Coal handling and storage before being pulverized and fed into boilers to produce steam.
- Water tube boilers that convert the steam's thermal energy into rotational energy via turbines connected to generators.
- Condensers that condense the steam back into water and cooling towers that cool the water for reuse.
- Auxiliary equipment like transformers, switchyards, and protection systems.
- The plant has a total installed capacity of 2320 MW produced across multiple units.
Ppt on power generation(thermal), transmission & distributionSuvamSahu2
The document provides information about electrical power generation at a thermal power plant (KTPS). It discusses the working principle, layout, main equipment, waste generated and their control, advantages and disadvantages. The main equipment discussed includes the coal handling plant, pulverizing plant, boiler, turbine, condenser, cooling towers/ponds, feed water heater, economizer, and air preheater. It also provides additional data about KTPS such as its generating capacity and types of circuit breakers used.
This PPT is for presentation on summer training by electrical engineers at Parichha thermal power plant. I have compiled it from ppt by Abhishek Awasthi and Himanshu Katiyar on Panki thermal power plant.
The document summarizes the layout and components of the Kota Super Thermal Power Station, a power plant located in Kota, India. It consists of 7 units with a total generation capacity of 1240 MW. The main parts of the plant include the coal handling plant, boiler, superheater, steam turbine, generator, generating transformer, and cooling system. The coal handling plant processes and conveys coal to the furnace. Steam is generated in the boiler and superheated before powering the steam turbine, which drives the generator to produce electricity.
This document provides an overview of Ajeet Singh Kuri's internship at the Suratgarh Super Thermal Power Station from May 16 to July 16, 2017. It discusses the power station's location, installed capacity, and favorable conditions. It then outlines the contents of Kuri's presentation, which includes introductions to the power station and the process of steam generation, as well as overviews of the coal handling plant, boiler, turbine, turbo generator, condenser, ash handling plant, cooling towers/ponds, and protection/switching systems.
The document summarizes information about the Panki Thermal Power Station located in Kanpur, India. It discusses:
1) The power station has two operational units of 105 MW each that were established in 1976-1977.
2) It describes the various processes involved in coal-fired power generation including the coal handling plant, water treatment plant, boiler, turbine, generator, and switchyard.
3) The key components and functions of a thermal power plant are outlined, from coal firing to electricity generation using steam turbines driven by the steam produced in boilers.
CHINA’S GEO-ECONOMIC OUTREACH IN CENTRAL ASIAN COUNTRIES AND FUTURE PROSPECTjpsjournal1
The rivalry between prominent international actors for dominance over Central Asia's hydrocarbon
reserves and the ancient silk trade route, along with China's diplomatic endeavours in the area, has been
referred to as the "New Great Game." This research centres on the power struggle, considering
geopolitical, geostrategic, and geoeconomic variables. Topics including trade, political hegemony, oil
politics, and conventional and nontraditional security are all explored and explained by the researcher.
Using Mackinder's Heartland, Spykman Rimland, and Hegemonic Stability theories, examines China's role
in Central Asia. This study adheres to the empirical epistemological method and has taken care of
objectivity. This study analyze primary and secondary research documents critically to elaborate role of
china’s geo economic outreach in central Asian countries and its future prospect. China is thriving in trade,
pipeline politics, and winning states, according to this study, thanks to important instruments like the
Shanghai Cooperation Organisation and the Belt and Road Economic Initiative. According to this study,
China is seeing significant success in commerce, pipeline politics, and gaining influence on other
governments. This success may be attributed to the effective utilisation of key tools such as the Shanghai
Cooperation Organisation and the Belt and Road Economic Initiative.
International Conference on NLP, Artificial Intelligence, Machine Learning an...gerogepatton
International Conference on NLP, Artificial Intelligence, Machine Learning and Applications (NLAIM 2024) offers a premier global platform for exchanging insights and findings in the theory, methodology, and applications of NLP, Artificial Intelligence, Machine Learning, and their applications. The conference seeks substantial contributions across all key domains of NLP, Artificial Intelligence, Machine Learning, and their practical applications, aiming to foster both theoretical advancements and real-world implementations. With a focus on facilitating collaboration between researchers and practitioners from academia and industry, the conference serves as a nexus for sharing the latest developments in the field.
Introduction- e - waste – definition - sources of e-waste– hazardous substances in e-waste - effects of e-waste on environment and human health- need for e-waste management– e-waste handling rules - waste minimization techniques for managing e-waste – recycling of e-waste - disposal treatment methods of e- waste – mechanism of extraction of precious metal from leaching solution-global Scenario of E-waste – E-waste in India- case studies.
Advanced control scheme of doubly fed induction generator for wind turbine us...IJECEIAES
This paper describes a speed control device for generating electrical energy on an electricity network based on the doubly fed induction generator (DFIG) used for wind power conversion systems. At first, a double-fed induction generator model was constructed. A control law is formulated to govern the flow of energy between the stator of a DFIG and the energy network using three types of controllers: proportional integral (PI), sliding mode controller (SMC) and second order sliding mode controller (SOSMC). Their different results in terms of power reference tracking, reaction to unexpected speed fluctuations, sensitivity to perturbations, and resilience against machine parameter alterations are compared. MATLAB/Simulink was used to conduct the simulations for the preceding study. Multiple simulations have shown very satisfying results, and the investigations demonstrate the efficacy and power-enhancing capabilities of the suggested control system.
artificial intelligence and data science contents.pptxGauravCar
What is artificial intelligence? Artificial intelligence is the ability of a computer or computer-controlled robot to perform tasks that are commonly associated with the intellectual processes characteristic of humans, such as the ability to reason.
› ...
Artificial intelligence (AI) | Definitio
Electric vehicle and photovoltaic advanced roles in enhancing the financial p...IJECEIAES
Climate change's impact on the planet forced the United Nations and governments to promote green energies and electric transportation. The deployments of photovoltaic (PV) and electric vehicle (EV) systems gained stronger momentum due to their numerous advantages over fossil fuel types. The advantages go beyond sustainability to reach financial support and stability. The work in this paper introduces the hybrid system between PV and EV to support industrial and commercial plants. This paper covers the theoretical framework of the proposed hybrid system including the required equation to complete the cost analysis when PV and EV are present. In addition, the proposed design diagram which sets the priorities and requirements of the system is presented. The proposed approach allows setup to advance their power stability, especially during power outages. The presented information supports researchers and plant owners to complete the necessary analysis while promoting the deployment of clean energy. The result of a case study that represents a dairy milk farmer supports the theoretical works and highlights its advanced benefits to existing plants. The short return on investment of the proposed approach supports the paper's novelty approach for the sustainable electrical system. In addition, the proposed system allows for an isolated power setup without the need for a transmission line which enhances the safety of the electrical network
Redefining brain tumor segmentation: a cutting-edge convolutional neural netw...IJECEIAES
Medical image analysis has witnessed significant advancements with deep learning techniques. In the domain of brain tumor segmentation, the ability to
precisely delineate tumor boundaries from magnetic resonance imaging (MRI)
scans holds profound implications for diagnosis. This study presents an ensemble convolutional neural network (CNN) with transfer learning, integrating
the state-of-the-art Deeplabv3+ architecture with the ResNet18 backbone. The
model is rigorously trained and evaluated, exhibiting remarkable performance
metrics, including an impressive global accuracy of 99.286%, a high-class accuracy of 82.191%, a mean intersection over union (IoU) of 79.900%, a weighted
IoU of 98.620%, and a Boundary F1 (BF) score of 83.303%. Notably, a detailed comparative analysis with existing methods showcases the superiority of
our proposed model. These findings underscore the model’s competence in precise brain tumor localization, underscoring its potential to revolutionize medical
image analysis and enhance healthcare outcomes. This research paves the way
for future exploration and optimization of advanced CNN models in medical
imaging, emphasizing addressing false positives and resource efficiency.
Discover the latest insights on Data Driven Maintenance with our comprehensive webinar presentation. Learn about traditional maintenance challenges, the right approach to utilizing data, and the benefits of adopting a Data Driven Maintenance strategy. Explore real-world examples, industry best practices, and innovative solutions like FMECA and the D3M model. This presentation, led by expert Jules Oudmans, is essential for asset owners looking to optimize their maintenance processes and leverage digital technologies for improved efficiency and performance. Download now to stay ahead in the evolving maintenance landscape.
2. About SGTPP :
Location : Manigram ,
Murshidabad
No. of Units MW per Unit Total
Capacity
1. Phase-I 2 300 2*300=600
2.Phase-II
(Ongoing)
2 500 2*500=1000
3. Introduction Of A Thermal Power Plant
. A thermal power plant is a power
plant in which heat energy is converted to
electric power. In most of the places in the
world the turbine is steam-driven. Water is
heated, turns into steam and spins a steam
turbine which drives an electrical
generator.
5. DM Plant
Demineralization ( DM ) Water Treatment Plants.
Demineralization is the process of removing mineral
salts from water by using the ion exchange process.
Demineralised water is water completely free (or
almost) of dissolved minerals as a result of one of the
following processes : • Distillation. • Deionization.
6.
7. Coal Handling plant
In the thermal power plants maximum requirements of fuel is coal. The handling of this fuel is a
great job. To handle the fuel i.e. coal, each power station is equipped with a coal handling plant.
Maintenance of Critical Equipments for Coal Handling Plants (CHP) of Thermal Power Stations is
typical job.
8.
9. Ground Hopper
V1 V2 V3
DRC
I/C
PRIMARY CRUSHER HOUSE
SECOND. CRUSHER HOUSE
SM
BUNKER
15. Electrical switchyards are usually part of a
substation where electricity is transformed from
one voltage to another for the transmission,
distribution.
15
16. MAIN COMPONENTS OF
SWITCHYARD
1. TRANSFORMER
2. CURRENT TRANSFORMER
3. POTENTIAL TRANSFORMER
4. CIRCUIT BREAKER
5. ISOLATOR
6. INSULATOR
7. LIGHTNING ARRESTOR
8. BUS BAR
16
17. DISTRIBUTION : Subhasgram and Farakka are fed from 400kV
Switchyard
Saithiya and Azimganj are fed from 200kV switchyard
400kV also fed to Purulia
Gokorno , Faridpur are fed from here
18. ASH HANDLING
SYSTEM
• The ash handling system handles
the ash by bottom ash handling
system, coarse ash handling
system, fly ash handling system,
ash disposal system up to the ash
disposal area and water recovery
system from ash pond and
Bottom ash overflow.
19. PARTS OF ASH HANDLING SYSTEM
• Bottom Ash Handling System
• Coarse Ash (Economizer Ash)
handling system
• Air Pre Heater ash handling system
• Fly ash handling system
• Ash slurry disposal system
20. Pollution Control
Environmental issues in coal based power
generation
• Air pollution
• Water pollution
• Noise pollution
Action plans for utilizations of fly ash by thermal
power plant
To reduce the fly ash in air ESP is used in
chimney
Ashes are supplied to many factories like
Asbestos , Cements
21. CONCLUSION
My training in SGTPP has turned out to be really helpful and special thanks goes
to the
teachers in there and has helped me to gain knowledge in various parts of it.