NSPCL is a 120MW (60MW*2) Coal fired thermal captive power plant which is established in durgapur, West Bengal.It has recently two more branches at different loactions i.e Roulkela & Bhilai.
A thermal power plant converts the heat from coal into electrical energy. Coal is burned in a boiler to produce high pressure steam, which spins turbines connected to generators. This generates electricity. The steam is then condensed in a condenser using cooling water, which is cooled in cooling towers or ponds and recycled. Thermal power plants currently contribute the majority of electricity production in India.
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.
A best ppt on kota super thermal power stationNaveen Kumar
Kota Super Thermal Power Station (KSTPS) is located in Kota, Rajasthan. It has a total generation capacity of 1240 MW across 7 stages of power production. Coal is used as fuel and is supplied by Coal India Limited. The presentation discusses the general layout and various key components of the power plant including the coal handling plant, boiler, ash handling plant, steam turbine, electricity generator, cooling system, transformer, and control panel. KSTPS uses a water tube boiler and produces electricity through a steam turbine connected to a generator.
This document describes the process of generating electricity from coal, beginning with coal mining and transport, processing the coal at the power plant, generating steam in boilers using the coal, producing work in turbines using the steam, and generating electricity using generators connected to the turbines. Key components and processes discussed include open-cast coal mines, transporting coal to the plant using a merry-go-round system, crushing and storing coal at the plant, pulverizing coal to a fine powder, burning the powdered coal in boilers to produce high-pressure steam, expanding the steam in a turbine to produce rotational work, and using generators connected to the turbines to convert the rotational work into electricity delivered to the power grid.
Electricity generation is the process of generating electric power from other sources of primary energy. Electricity is most often generated at a power station by electro-mechanical generators, primarily driven by heat engines fueled by chemical combustion or nuclear fission but also by other means such as the kinetic energy of flowing water and wind.
In Indian subcontinent the abundance of coal lead to the establishment of thermal power stations and governing bodies namely WBPDCL, DVC, NTPC act as pioneers in the generation of electricity.
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
Ppt on ntpc dadri created vikas gujjar(IET lko)Vikas Gurjer
This document provides an overview of the NTPC Dadri power plant in India. It has a total generation capacity of 2642 MW from thermal, gas, and solar sources. The Dadri plant has several unique features, including being the largest gas station and dry ash handling plant in Asia. The document then describes the key components and processes within a thermal power plant, including the coal handling plant, boiler, turbine, generator, and ash handling plant. Block diagrams depict the overall power generation process from coal to electricity.
A thermal power plant converts the heat from coal into electrical energy. Coal is burned in a boiler to produce high pressure steam, which spins turbines connected to generators. This generates electricity. The steam is then condensed in a condenser using cooling water, which is cooled in cooling towers or ponds and recycled. Thermal power plants currently contribute the majority of electricity production in India.
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.
A best ppt on kota super thermal power stationNaveen Kumar
Kota Super Thermal Power Station (KSTPS) is located in Kota, Rajasthan. It has a total generation capacity of 1240 MW across 7 stages of power production. Coal is used as fuel and is supplied by Coal India Limited. The presentation discusses the general layout and various key components of the power plant including the coal handling plant, boiler, ash handling plant, steam turbine, electricity generator, cooling system, transformer, and control panel. KSTPS uses a water tube boiler and produces electricity through a steam turbine connected to a generator.
This document describes the process of generating electricity from coal, beginning with coal mining and transport, processing the coal at the power plant, generating steam in boilers using the coal, producing work in turbines using the steam, and generating electricity using generators connected to the turbines. Key components and processes discussed include open-cast coal mines, transporting coal to the plant using a merry-go-round system, crushing and storing coal at the plant, pulverizing coal to a fine powder, burning the powdered coal in boilers to produce high-pressure steam, expanding the steam in a turbine to produce rotational work, and using generators connected to the turbines to convert the rotational work into electricity delivered to the power grid.
Electricity generation is the process of generating electric power from other sources of primary energy. Electricity is most often generated at a power station by electro-mechanical generators, primarily driven by heat engines fueled by chemical combustion or nuclear fission but also by other means such as the kinetic energy of flowing water and wind.
In Indian subcontinent the abundance of coal lead to the establishment of thermal power stations and governing bodies namely WBPDCL, DVC, NTPC act as pioneers in the generation of electricity.
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
Ppt on ntpc dadri created vikas gujjar(IET lko)Vikas Gurjer
This document provides an overview of the NTPC Dadri power plant in India. It has a total generation capacity of 2642 MW from thermal, gas, and solar sources. The Dadri plant has several unique features, including being the largest gas station and dry ash handling plant in Asia. The document then describes the key components and processes within a thermal power plant, including the coal handling plant, boiler, turbine, generator, and ash handling plant. Block diagrams depict the overall power generation process from coal to electricity.
This document provides an overview of NTPC Dadri power plant located in India. It summarizes that NTPC Dadri has a total installed capacity of 2655 MW consisting of 1820 MW from coal, 830 MW from gas, and 5 MW from solar. It also describes the basic working of the steam power generation process used at the coal-fired units. Key components discussed include the boiler, turbine, condenser, and cooling towers. Details are provided about the coal and gas supplies as well as the ash handling and solar power facilities at NTPC Dadri.
NTPC Dadri is a coal and gas-based thermal power plant located in Uttar Pradesh, India. It has a total installed capacity of 2,637 MW consisting of 1,820 MW from its coal-based units and 817 MW from its gas-based units. The plant sources coal from Piparwara mines in Jharkhand and water from the Upper Ganga Canal. It operates using a conventional thermal power generation process where coal is pulverized and fired in a boiler to produce high pressure steam that drives turbines connected to generators to produce electricity. Ash produced from combustion is utilized in construction and manufacturing industries.
The Kota Super Thermal Power Plant in Rajasthan has a total generation capacity of 1240 MW distributed across 7 stages commissioned between 1983-2009. It is located on the Chambal river and has abundant cooling water and good transportation access. The plant has a coal handling plant to receive and crush coal, boilers to generate steam, superheaters to further heat steam, turbines to convert steam energy to mechanical energy, generators to produce electricity, and auxiliary systems to treat water, handle ash, and control operations.
The document provides information about the gas power plant located at NTPC Dadri in Uttar Pradesh, India. It details that the plant has both coal-based and gas-based thermal generation units with a total installed capacity of 2,642 MW. The coal units have a capacity of 1,820 MW while the gas units have a capacity of 829.78 MW. The plant also has a 5 MW solar power facility. It describes the various components and working principles of the gas turbine system used at the plant.
The document discusses India's energy sources and power generation. It notes that India is a large consumer of energy, with conventional sources being thermal, hydro, and nuclear, and non-conventional sources including wind, solar, geothermal, and tidal. Thermal power makes up 75% of India's power generation, with hydro at 21% and nuclear at 4%. The document outlines the general layout and main circuits of a steam power plant, including the fuel and ash, air and gas, feed water and steam, and cooling water circuits. It also discusses factors to consider when selecting a site for a power plant such as coal availability, ash disposal, land and water needs, and transportation.
This document provides information about Harsh Kumar's summer training project at the National Thermal Power Corporation (NTPC) Dadri power plant in India. It includes:
- An overview of NTPC as the largest power company in India, operating coal and gas-fired thermal power plants.
- Details of the NTPC Dadri plant, which has both coal and gas-fired units totaling 2,642 MW capacity.
- Descriptions of the key components and processes within a thermal power plant, including the coal handling plant, mills, boilers, turbines and generators.
- An explanation of the basic thermal power plant cycle that converts fuel energy to electrical energy.
A Presentation on Kota Super Thermal Power StationLekhraJ Meena
The document provides information about the Kota Super Thermal Power Plant in India including its establishment, generation capacity, units and their installation details. It describes the main components of the plant including the coal handling plant, boiler, superheater, steam turbine, generator, water treatment plant, ash handling plant and control room. The coal handling plant section explains the wagon unloading, crushing and conveying systems. The document also provides diagrams to illustrate the layout and processes of the power plant.
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 Kota Super Thermal Power Station is a coal-based steam plant located on the left bank of the Chambal River in Kota, Rajasthan. It has a total generation capacity of 1240MW from 7 units and requires 250 hectares of land. The first unit was commissioned in 1983. Coal is transported by rail from nearby mines and handles about 3074 tonnes per day. The plant has a coal handling system, boilers, turbines, generators, cooling system, water treatment plant, and ash handling facilities. It supplies power to various cities in Rajasthan.
Presentation on Kota super Thermal Power Stationpukhraj palariya
The document provides information about the Kota Super Thermal Power Station (KSTPS) in Kota, Rajasthan. It discusses the key stages and features of the power station, including that it began operations in 1983, has a total generation capacity of 1240 MW from 7 units, and sources coal from local mines to power its boilers. The power station uses a steam turbine generator process to convert the thermal energy of steam into electrical energy.
SUMMER TRAINING AT NTPC DADRI GAS SECTIONAMIT KUMAR
The document provides an overview of NTPC, India's largest power company, and details about gas power plants and combined cycle power plants. It describes the key components and processes, including gas turbines, heat recovery steam generators, steam turbines, and the Brayton and Rankine cycles. Specifically, it explains how compressed air is heated in a gas turbine to drive a generator, before its waste heat is used to generate high pressure steam to drive a steam turbine. Together, the gas and steam turbines can produce up to 600 megawatts of electricity in a combined cycle configuration. The document also outlines NTPC's emissions controls and cooling systems to reduce environmental impacts.
harduaganj thermal power station h.t.p.s.vaibyfrndz
This presentation summarizes the Harduaganj Thermal Power Plant located in Aligarh district, Uttar Pradesh, India. The plant has a total installed capacity of 415MW generated across 5 units, with the last two units each having a capacity of 250MW. The plant operates by burning coal to create steam that drives turbines connected to generators to produce electricity. It also describes the various components used in the thermal power generation process such as the boiler, turbine, condenser, and coal handling equipment.
details about the real thermal plant and its working.here is the knowledge that i gained through my internship in Aditya aluminium governed by Hindalco industries pvt.ltd.
This 3 sentence summary provides an overview of the key components and processes at the Obra power station:
The document discusses the various stages of expansion at the Obra power station in India, describing the basic processes that generate electricity from coal including the coal handling plant, boiler, steam turbine, and transformer. It also outlines the water treatment plant and discusses the production and uses of fly ash and bottom ash as byproducts.
The document provides information about Emam Raza's summer training experience at the National Thermal Power Plant in Dadri, India. It discusses the key aspects of the power plant including its capacity of 2642 MW from thermal, gas, and solar sources. It describes the basic processes involved in electricity generation from coal including the coal handling system, boiler, turbine, condenser, and other important equipment. The document also provides details about NTPC as a company, the transportation and characteristics of coal used at the plant, working of various sections, and uses of coal ash.
This document provides an overview of the Kota Super Thermal Power Station located on the Chambal river in Kota, India. It has a total installed capacity of 1240MW across 7 units of varying sizes commissioned between 1983-2009. The power station uses a coal-fired thermal process, with key components including the coal handling plant, boiler, superheater, steam turbine, economizer, generator, water treatment plant, and ash handling plant. It benefits from abundant cooling water from the river and good transportation access for coal and industry in the local region.
A thermal power station is a power station 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.
Summer Training Presentation Kota Super Thermal Power StationFellowBuddy.com
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This document provides information about a thermal power plant. It discusses the working principle where coal is burned to heat water into steam, which spins a turbine connected to a generator to produce electricity. It describes the main equipment used such as the coal handling plant, pulverizer, boiler, turbine, condenser, cooling towers, feedwater heater, economizer and air preheater. It also discusses the waste generated and control methods used, and lists advantages like low cost fuel and disadvantages like pollution.
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
This document provides an overview of NTPC Dadri power plant located in India. It summarizes that NTPC Dadri has a total installed capacity of 2655 MW consisting of 1820 MW from coal, 830 MW from gas, and 5 MW from solar. It also describes the basic working of the steam power generation process used at the coal-fired units. Key components discussed include the boiler, turbine, condenser, and cooling towers. Details are provided about the coal and gas supplies as well as the ash handling and solar power facilities at NTPC Dadri.
NTPC Dadri is a coal and gas-based thermal power plant located in Uttar Pradesh, India. It has a total installed capacity of 2,637 MW consisting of 1,820 MW from its coal-based units and 817 MW from its gas-based units. The plant sources coal from Piparwara mines in Jharkhand and water from the Upper Ganga Canal. It operates using a conventional thermal power generation process where coal is pulverized and fired in a boiler to produce high pressure steam that drives turbines connected to generators to produce electricity. Ash produced from combustion is utilized in construction and manufacturing industries.
The Kota Super Thermal Power Plant in Rajasthan has a total generation capacity of 1240 MW distributed across 7 stages commissioned between 1983-2009. It is located on the Chambal river and has abundant cooling water and good transportation access. The plant has a coal handling plant to receive and crush coal, boilers to generate steam, superheaters to further heat steam, turbines to convert steam energy to mechanical energy, generators to produce electricity, and auxiliary systems to treat water, handle ash, and control operations.
The document provides information about the gas power plant located at NTPC Dadri in Uttar Pradesh, India. It details that the plant has both coal-based and gas-based thermal generation units with a total installed capacity of 2,642 MW. The coal units have a capacity of 1,820 MW while the gas units have a capacity of 829.78 MW. The plant also has a 5 MW solar power facility. It describes the various components and working principles of the gas turbine system used at the plant.
The document discusses India's energy sources and power generation. It notes that India is a large consumer of energy, with conventional sources being thermal, hydro, and nuclear, and non-conventional sources including wind, solar, geothermal, and tidal. Thermal power makes up 75% of India's power generation, with hydro at 21% and nuclear at 4%. The document outlines the general layout and main circuits of a steam power plant, including the fuel and ash, air and gas, feed water and steam, and cooling water circuits. It also discusses factors to consider when selecting a site for a power plant such as coal availability, ash disposal, land and water needs, and transportation.
This document provides information about Harsh Kumar's summer training project at the National Thermal Power Corporation (NTPC) Dadri power plant in India. It includes:
- An overview of NTPC as the largest power company in India, operating coal and gas-fired thermal power plants.
- Details of the NTPC Dadri plant, which has both coal and gas-fired units totaling 2,642 MW capacity.
- Descriptions of the key components and processes within a thermal power plant, including the coal handling plant, mills, boilers, turbines and generators.
- An explanation of the basic thermal power plant cycle that converts fuel energy to electrical energy.
A Presentation on Kota Super Thermal Power StationLekhraJ Meena
The document provides information about the Kota Super Thermal Power Plant in India including its establishment, generation capacity, units and their installation details. It describes the main components of the plant including the coal handling plant, boiler, superheater, steam turbine, generator, water treatment plant, ash handling plant and control room. The coal handling plant section explains the wagon unloading, crushing and conveying systems. The document also provides diagrams to illustrate the layout and processes of the power plant.
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 Kota Super Thermal Power Station is a coal-based steam plant located on the left bank of the Chambal River in Kota, Rajasthan. It has a total generation capacity of 1240MW from 7 units and requires 250 hectares of land. The first unit was commissioned in 1983. Coal is transported by rail from nearby mines and handles about 3074 tonnes per day. The plant has a coal handling system, boilers, turbines, generators, cooling system, water treatment plant, and ash handling facilities. It supplies power to various cities in Rajasthan.
Presentation on Kota super Thermal Power Stationpukhraj palariya
The document provides information about the Kota Super Thermal Power Station (KSTPS) in Kota, Rajasthan. It discusses the key stages and features of the power station, including that it began operations in 1983, has a total generation capacity of 1240 MW from 7 units, and sources coal from local mines to power its boilers. The power station uses a steam turbine generator process to convert the thermal energy of steam into electrical energy.
SUMMER TRAINING AT NTPC DADRI GAS SECTIONAMIT KUMAR
The document provides an overview of NTPC, India's largest power company, and details about gas power plants and combined cycle power plants. It describes the key components and processes, including gas turbines, heat recovery steam generators, steam turbines, and the Brayton and Rankine cycles. Specifically, it explains how compressed air is heated in a gas turbine to drive a generator, before its waste heat is used to generate high pressure steam to drive a steam turbine. Together, the gas and steam turbines can produce up to 600 megawatts of electricity in a combined cycle configuration. The document also outlines NTPC's emissions controls and cooling systems to reduce environmental impacts.
harduaganj thermal power station h.t.p.s.vaibyfrndz
This presentation summarizes the Harduaganj Thermal Power Plant located in Aligarh district, Uttar Pradesh, India. The plant has a total installed capacity of 415MW generated across 5 units, with the last two units each having a capacity of 250MW. The plant operates by burning coal to create steam that drives turbines connected to generators to produce electricity. It also describes the various components used in the thermal power generation process such as the boiler, turbine, condenser, and coal handling equipment.
details about the real thermal plant and its working.here is the knowledge that i gained through my internship in Aditya aluminium governed by Hindalco industries pvt.ltd.
This 3 sentence summary provides an overview of the key components and processes at the Obra power station:
The document discusses the various stages of expansion at the Obra power station in India, describing the basic processes that generate electricity from coal including the coal handling plant, boiler, steam turbine, and transformer. It also outlines the water treatment plant and discusses the production and uses of fly ash and bottom ash as byproducts.
The document provides information about Emam Raza's summer training experience at the National Thermal Power Plant in Dadri, India. It discusses the key aspects of the power plant including its capacity of 2642 MW from thermal, gas, and solar sources. It describes the basic processes involved in electricity generation from coal including the coal handling system, boiler, turbine, condenser, and other important equipment. The document also provides details about NTPC as a company, the transportation and characteristics of coal used at the plant, working of various sections, and uses of coal ash.
This document provides an overview of the Kota Super Thermal Power Station located on the Chambal river in Kota, India. It has a total installed capacity of 1240MW across 7 units of varying sizes commissioned between 1983-2009. The power station uses a coal-fired thermal process, with key components including the coal handling plant, boiler, superheater, steam turbine, economizer, generator, water treatment plant, and ash handling plant. It benefits from abundant cooling water from the river and good transportation access for coal and industry in the local region.
A thermal power station is a power station 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.
Summer Training Presentation Kota Super Thermal Power StationFellowBuddy.com
FellowBuddy.com is an innovative platform that brings students together to share notes, exam papers, study guides, project reports and presentation for upcoming exams.
We connect Students who have an understanding of course material with Students who need help.
Benefits:-
# Students can catch up on notes they missed because of an absence.
# Underachievers can find peer developed notes that break down lecture and study material in a way that they can understand
# Students can earn better grades, save time and study effectively
Our Vision & Mission – Simplifying Students Life
Our Belief – “The great breakthrough in your life comes when you realize it, that you can learn anything you need to learn; to accomplish any goal that you have set for yourself. This means there are no limits on what you can be, have or do.”
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This document provides information about a thermal power plant. It discusses the working principle where coal is burned to heat water into steam, which spins a turbine connected to a generator to produce electricity. It describes the main equipment used such as the coal handling plant, pulverizer, boiler, turbine, condenser, cooling towers, feedwater heater, economizer and air preheater. It also discusses the waste generated and control methods used, and lists advantages like low cost fuel and disadvantages like pollution.
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
This document provides an overview of the Kalisindh Super Thermal Power Plant located in Jhalawar, Rajasthan, India. It has an installed capacity of 1200 MW from two 600 MW coal-fired units. The key components discussed include the coal handling plant, demineralization plant, boiler, superheater, air preheater, economizer, cooling tower, circulating pumps, boiler feed pumps, steam turbine, and generator. The presentation aims to explain the generation and working of the different parts of the thermal power plant.
1. The presentation summarizes the key features of the Kota Super Thermal Power Station (KSTPS) located in Sakatpura, Kota. KSTPS has a total installed capacity of 1240 MW and uses coal as its primary fuel source.
2. The power station operates via five stages, with the first two units producing 110 MW each and subsequent units producing 210 MW and 195 MW. It utilizes various equipment for coal handling, crushing, pulverizing, steam generation, and power production.
3. KSTPS feeds power into the electrical grid through its switchyard, which includes components like isolators, lightning arresters, busbars, and transformers to handle and distribute the generated electricity
The document provides information about the 330 MW Dholpur Combined Cycle Power Project (DCCPP) in India. It consists of 3 units of 110 MW each. The plant uses re-liquefied natural gas as fuel. It uses both a gas turbine and a steam turbine for power generation by utilizing the waste heat from the gas turbine in a heat recovery steam generator to produce steam for the steam turbine. This combined cycle configuration improves efficiency by capturing unused heat energy.
The document reports on the generation of thermal power at NTPC Dadri power plant. It describes the key components of a thermal power plant including the boiler, turbine, condenser and other equipment. The working of the power plant is explained starting from the burning of coal to produce steam and ending with the generation of electricity via the steam turbine connected to an alternator.
NTPC Dadri is a coal and gas-based thermal power plant located in Uttar Pradesh, India. It has a total installed capacity of 2,637 MW from 6 coal units and 6 gas units. The plant sources coal from Jharkhand and water from the Upper Ganga Canal. It operates by pulverizing coal, heating water into steam in a boiler, using the steam to spin turbines connected to a generator to produce electricity, and condensing the steam in a condenser to be reused. The plant helps contribute to over 3/5th of India's total power generation. Ash produced is utilized in construction, cement/brick manufacturing, and agriculture.
This document provides an overview of a thermal power plant, including its key components and processes. It begins with an introduction to thermal power plants in India and how they generate electricity using steam turbines. It then defines a thermal power plant and provides block diagrams of the main components. The main body of the document describes each major equipment in more detail, such as the coal handling plant, boiler, turbine, condenser, and cooling towers. It also lists some thermal power plants located in Rajasthan and discusses the advantages and disadvantages of thermal power generation.
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.
A power plant uses various types of equipment to generate electrical energy from different fuel sources. Thermal power plants convert heat energy from combustion of fuels like coal into electrical energy. They consist of a boiler, turbine and generator. Hydropower plants use the potential energy of water stored in dams to drive turbines and generate electricity. Diesel power plants rely on diesel engines while gas turbine plants use natural gas as fuel. Nuclear power plants utilize nuclear fission to produce heat and generate steam to spin turbines. Selection of the power plant type depends on factors like availability of fuel, water, land and transportation facilities.
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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This document provides an overview of a thermal power plant. It begins with an introduction explaining that a thermal power plant converts the heat energy from coal into electrical energy. It then describes the main components of a thermal power plant including the coal handling plant, boiler, turbine, condenser, and cooling towers. The document also discusses the waste generated from thermal power plants and methods for controlling waste. Finally, it lists some of the key advantages and disadvantages of thermal power plants.
This document provides an overview of a training seminar on a summer internship at the Dholpur Combined Cycle Power Plant. It discusses the organization and various components of the power plant, including the gas turbine, heat recovery steam generator, steam turbine, condenser, turbo generator, excitation system, and 220kV switchyard. Key details are provided on the selection of the plant site, plant specifications and costs, equipment ratings, theories of operation, components and functions of the various systems. The document aims to educate interns on the technical aspects and working of the combined cycle power plant.
Kota super thermal power plant,kstps ppt,RTUManohar Nagar
Rajasthan's first major coal-fired power plant, the KSTPS, was established in 1983 near Kota with a total installed capacity of 1240 MW across 7 units ranging from 110-210 MW each. Located on the left bank of the Chambal River, the KSTPS uses a steam turbine generator process utilizing a Rankine cycle to convert the heat from burning coal into electrical energy.
The document provides information about different types of power plants. It begins by defining a power plant as a machine that produces and delivers electrical energy. It then discusses various factors considered in selecting a suitable power plant location such as fuel availability and environmental conditions. The main types of power plants described are thermal, hydroelectric, diesel, gas turbine and nuclear power plants. For each type, the document outlines the basic working principle, components and advantages/disadvantages. It also provides some specific details about thermal power plants in Tamil Nadu and the working of pumps and turbines used in power plants.
PPT ON THERMAL POWER PLANT (POLLUTION CONTROLLED)HIMANSHU .
!!!!!!!!!!>LINKS FOR THE VIDEOS ARE<!!!!!!!!!!
>>>https://drive.google.com/drive/folders/1cSouvmjSSu7ZSPBq1AA2TYYn87kepoW8?usp=sharing<<<
A generating station which converts heat energy of coal combustion into electrical energy is known as a thermal power station.
IN THIS PPT THERE ARE SOME WAYS OF USING TECHNIQUES TO SOLVE THE PROBLEM OF POLLUTION CAUSED BY THERMAL POWER PLANT
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 summarizes the key components of a typical coal-fired thermal power plant, including:
1. The coal handling plant feeds coal automatically into the boiler furnace. A 200MW plant uses around 2000 tons of coal daily.
2. Ash handling plants deal with the large amounts of ash produced daily, around 5000 tons for a 2000MW plant.
3. Steam from the boiler powers the turbine, which drives the generator to convert heat energy into electrical energy.
Thermal power plants generate electricity by burning coal to heat water and produce steam. The steam spins turbines that drive generators, producing electricity. They provide 65% of India's power. Coal is pulverized and burned in a boiler to heat water and produce high-pressure steam. This steam spins turbines connected to generators, producing electricity. The steam is then condensed in a condenser and recycled to the boiler as water to repeat the process. Thermal power plants have significant environmental impacts due to the air pollution produced by burning coal.
Similar to PPT on Summer Training at NSPCL By Aniket Suman (20)
6th International Conference on Machine Learning & Applications (CMLA 2024)ClaraZara1
6th International Conference on Machine Learning & Applications (CMLA 2024) will provide an excellent international forum for sharing knowledge and results in theory, methodology and applications of on Machine Learning & Applications.
DEEP LEARNING FOR SMART GRID INTRUSION DETECTION: A HYBRID CNN-LSTM-BASED MODELgerogepatton
As digital technology becomes more deeply embedded in power systems, protecting the communication
networks of Smart Grids (SG) has emerged as a critical concern. Distributed Network Protocol 3 (DNP3)
represents a multi-tiered application layer protocol extensively utilized in Supervisory Control and Data
Acquisition (SCADA)-based smart grids to facilitate real-time data gathering and control functionalities.
Robust Intrusion Detection Systems (IDS) are necessary for early threat detection and mitigation because
of the interconnection of these networks, which makes them vulnerable to a variety of cyberattacks. To
solve this issue, this paper develops a hybrid Deep Learning (DL) model specifically designed for intrusion
detection in smart grids. The proposed approach is a combination of the Convolutional Neural Network
(CNN) and the Long-Short-Term Memory algorithms (LSTM). We employed a recent intrusion detection
dataset (DNP3), which focuses on unauthorized commands and Denial of Service (DoS) cyberattacks, to
train and test our model. The results of our experiments show that our CNN-LSTM method is much better
at finding smart grid intrusions than other deep learning algorithms used for classification. In addition,
our proposed approach improves accuracy, precision, recall, and F1 score, achieving a high detection
accuracy rate of 99.50%.
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.
KuberTENes Birthday Bash Guadalajara - K8sGPT first impressionsVictor Morales
K8sGPT is a tool that analyzes and diagnoses Kubernetes clusters. This presentation was used to share the requirements and dependencies to deploy K8sGPT in a local environment.
Embedded machine learning-based road conditions and driving behavior monitoringIJECEIAES
Car accident rates have increased in recent years, resulting in losses in human lives, properties, and other financial costs. An embedded machine learning-based system is developed to address this critical issue. The system can monitor road conditions, detect driving patterns, and identify aggressive driving behaviors. The system is based on neural networks trained on a comprehensive dataset of driving events, driving styles, and road conditions. The system effectively detects potential risks and helps mitigate the frequency and impact of accidents. The primary goal is to ensure the safety of drivers and vehicles. Collecting data involved gathering information on three key road events: normal street and normal drive, speed bumps, circular yellow speed bumps, and three aggressive driving actions: sudden start, sudden stop, and sudden entry. The gathered data is processed and analyzed using a machine learning system designed for limited power and memory devices. The developed system resulted in 91.9% accuracy, 93.6% precision, and 92% recall. The achieved inference time on an Arduino Nano 33 BLE Sense with a 32-bit CPU running at 64 MHz is 34 ms and requires 2.6 kB peak RAM and 139.9 kB program flash memory, making it suitable for resource-constrained embedded systems.
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.
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.
1. A
PRESENTATION ON SUMMER
TRAINING AT NSPCL, DURGAPUR
Presented by:
ANIKET SUMAN
2. INTRODUCTION
• NTPC + SAIL = NSPCL (NTPC - SAIL Power
Company Limited)
• Joint their ventures in March 2001
• Durgapur, Rourkela & Bhilai
• Captive Power Plant
• 120 MW of Generation at Durgapur
3. COAL
Coal
55%
Gas
10%
Hydel
26%
Diesel
1%
RES
5%
Nuclear
3%
Advantages of Coal Fuel:
•Abundantly available in India Semi Bituminous
Coal 27000 kJ/kg
•Low cost
•Easy to handle, transport, store
and use
Coal Properties:
•Calorific Value
•Weatherability
•Sulphur Content
•Ash Content
•Grindability Index
•Particle Size
8. AIR PREHEATER
• It is a device used in steam boilers to transfer
heat from the flue gases to the combustion air
before the air enters the furnace.
• Also known as air heater; air-heating system but
it is kept at a place near by where the air enters in
to the boiler.
• The purpose of the air preheater is to recover the
heat from the flue gas from the boiler to improve
boiler efficiency by burning warm air which
increases combustion efficiency, and reducing
useful heat lost from the flue.
9.
10. SUPER HEATER
• A device which removes last traces of
moisture.
• It helps in reduction in requirement of
steam quantity.
• steam being dry reduces the mechanical
resistance of turbine.
• No corrosion at the turbine blades.
11. COOLING TOWERS
Remove heat from the water discharged from the
condenser so that the water can be discharged to
the river or re circulated and reused.
• Air can be circulated in the cooling towers through
natural draft and mechanical draft.
12. TURBINE AND ALTERNATOR
•A steam turbine is a mechanical device that extracts
thermal energy from pressurized steam, and converts it
into mechanical energy.
•An alternator takes this mechanical energy as input and
gives electrical energy as output.