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.
A thermal power plant converts the heat energy of coal into electrical energy. Coal is burnt in a boiler to produce steam which drives a steam turbine connected to a generator. Thermal power plants provide the majority of electricity in India. The key components of a thermal power plant include the coal handling system, pulverizers, draft fans, boiler, turbine, condenser, cooling towers, feedwater heaters and others. Thermal power has advantages of using cheap fuel and low initial costs but has disadvantages of polluting the atmosphere. Large thermal power plants in Gujarat include Mundra, Wanakbori and Ukai.
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.
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.
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.
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.
Ntpc (national thermal power corporation) sipat mechanical vocational trainin...haxxo24
This document is a vocational training report submitted by Ritesh Patnaik after completing a 30-day training at the National Thermal Power Corporation plant in Sipat, Chhattisgarh, India. The report provides an overview of the key components and systems at the NTPC Sipat Super Thermal Power Project, including the steam turbine, generator, condenser, boiler, cooling towers, and pollution control devices. It also describes the basic Rankine cycle that is used to convert heat into electrical power at thermal power plants.
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.
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.
A thermal power plant converts the heat energy of coal into electrical energy. Coal is burnt in a boiler to produce steam which drives a steam turbine connected to a generator. Thermal power plants provide the majority of electricity in India. The key components of a thermal power plant include the coal handling system, pulverizers, draft fans, boiler, turbine, condenser, cooling towers, feedwater heaters and others. Thermal power has advantages of using cheap fuel and low initial costs but has disadvantages of polluting the atmosphere. Large thermal power plants in Gujarat include Mundra, Wanakbori and Ukai.
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.
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.
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.
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.
Ntpc (national thermal power corporation) sipat mechanical vocational trainin...haxxo24
This document is a vocational training report submitted by Ritesh Patnaik after completing a 30-day training at the National Thermal Power Corporation plant in Sipat, Chhattisgarh, India. The report provides an overview of the key components and systems at the NTPC Sipat Super Thermal Power Project, including the steam turbine, generator, condenser, boiler, cooling towers, and pollution control devices. It also describes the basic Rankine cycle that is used to convert heat into electrical power at thermal power plants.
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 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
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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.
A thermal power plant converts the heat energy from burning coal into electrical energy. Coal is burned in a boiler to produce high pressure steam, which spins turbines connected to generators. The main equipment includes the coal handling plant, pulverizer, boiler, turbine, condenser, and cooling towers. The steam produced is used to generate electricity before being condensed back into water and returned to the boiler to complete the cycle.
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.
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.
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.
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 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.
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 75% of India's electricity and have an installed capacity of over 93,000 MW. They work by burning fuel to create steam that spins turbines connected to generators. The main components are the fuel handling unit, boiler, turbine, generator, and cooling system. Fuel is burned in the boiler to create high-pressure steam, which drives the turbine before being condensed into water and recirculated or discharged.
Thermal power plants generate electricity by burning coal to produce steam that spins turbines which drive generators. Coal is pulverized and burned in a boiler to heat water and produce high pressure steam. This steam powers steam turbines which are connected to generators to produce electricity. The steam is then condensed in a condenser and recycled to the boiler to repeat the process. While coal provides a cheap and abundant fuel source, it is non-renewable and burning it releases greenhouse gases contributing to global warming.
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 Panipat Thermal Power Station located in Haryana, India. It discusses the key elements of a thermal power station including coal handling, the steam generation process, turbines, generators, condensers, cooling towers and switchyards. The power station uses coal to produce steam that drives turbines connected to generators to produce 1367.7 MW of electricity for Haryana. In conclusion, it notes that Panipat Thermal is the largest power plant in Haryana.
This document is a seminar report submitted by Mukesh Kumar for partial fulfillment of a Bachelor of Technology degree in Mechanical Engineering. It discusses thermal power plants, including an overview of their operation and efficiency, descriptions of typical components like boilers and steam cycles, and examples of power plants located in India with a focus on those in Rajasthan. The document received certification from internal and external examiners for Mukesh Kumar's seminar work on the topic of thermal power plants.
The document provides details about an industrial training project at the Wanakbori Thermal Power Station (WTPS). It includes:
1) An acknowledgment thanking those who facilitated the training.
2) An index outlining the topics to be covered, including details of the boiler, turbine, condenser, coal handling plant, and more.
3) An abstract stating the aim was to study the mechanical instruments involved in power generation and improve practical knowledge.
KTPS-V Station in Andhra Pradesh was commissioned in 1996 as the first major thermal power station in the state. It uses a steam turbine generator system where coal is burned to produce steam that spins the turbine to generate electricity. The station has four main circuits: steam and water, air and gas, coal and ash, and cooling water. Steam is produced in a boiler and drives high, intermediate, and low pressure turbines connected to an electrical generator before condensing in a condenser.
NTPC Dadri power plant has an installed capacity of 2642 MW including 1820 MW from thermal units and 817 MW from gas units. It sources coal from Piparwara mine in Jharkhand and water from Upper Ganga Canal. The basic processes include coal handling, combustion in boilers to produce steam, steam passing through turbines to generate electricity, and condensation of steam in condensers. Key components are coal handling plant, boilers, turbines, condensers, cooling towers, ESPs for emissions control, and chimney. Fly ash is a byproduct that is used in construction materials.
SUMMER INTERNSHIP(INDUSTRAIL REPORT) ON THERMAL POWER PLANT Amit Gupta
The document describes the key components and processes involved in a typical coal-fired thermal power plant, including coal handling, pulverizing, combustion in the boiler, steam generation, power generation in the turbine, and condensing spent steam. It also provides details on equipment like draft fans, superheaters, reheaters, the ash handling system, feedwater heaters, and installed capacity of thermal power plants in Rajasthan.
introduction to thermal powerplant,type of thermal powerplant,captive powerplant,rankin cycle,co-generation powerplant,subcritical powerplant,supercritical powerplant,theory of operation,working principle,parts of powerplant,boiler,turbine,etc
A thermal power station uses coal to generate steam, which spins turbines that create electrical power. Coal is pulverized and burned to heat water and create steam. The steam spins turbines connected to generators, producing electricity. The steam is then condensed back into water and recycled through the system. Thermal power stations use various pumps, fans, condensers and other equipment to efficiently convert the energy in coal into electrical power for transmission and distribution.
The document discusses the Sikka thermal power plant located in Jamnagar district, India. It describes that the plant was installed in 1984 with one 120MW unit, and a second unit was later added for a total capacity of 240MW. The plant uses coal from nearby states as its main fuel. It also has access to seawater for cooling purposes. The document explains the basic processes that occur in thermal power plants, including converting the chemical energy in coal to heat, using heat to create steam to turn turbines and generate electricity. It provides details on the key components of thermal power plants like boilers, turbines, condensers, and electrostatic precipitators.
Internship Report on thermal power station in vizag steel plantAbhishek Kumar
This document provides information about a study of power generation and distribution at a thermal power plant in Visakhapatnam Steel Plant. It discusses the key components of the thermal power plant including five water tube boilers that produce steam at 101 atmospheres of pressure and 540 degrees Celsius. The steam powers five steam turbines coupled to generators with a total installed capacity of 286.5 MW. The document outlines the processes of coal combustion in the boilers, steam generation, power generation using steam turbines, and distribution of power within the steel plant. It also discusses operational aspects like load management and limits of the turbo generators.
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:-
http://www.youtube.com/user/TheEngineeringScienc?sub_confirmation=1
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.
A thermal power plant converts the heat energy from burning coal into electrical energy. Coal is burned in a boiler to produce high pressure steam, which spins turbines connected to generators. The main equipment includes the coal handling plant, pulverizer, boiler, turbine, condenser, and cooling towers. The steam produced is used to generate electricity before being condensed back into water and returned to the boiler to complete the cycle.
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.
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.
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.
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 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.
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 75% of India's electricity and have an installed capacity of over 93,000 MW. They work by burning fuel to create steam that spins turbines connected to generators. The main components are the fuel handling unit, boiler, turbine, generator, and cooling system. Fuel is burned in the boiler to create high-pressure steam, which drives the turbine before being condensed into water and recirculated or discharged.
Thermal power plants generate electricity by burning coal to produce steam that spins turbines which drive generators. Coal is pulverized and burned in a boiler to heat water and produce high pressure steam. This steam powers steam turbines which are connected to generators to produce electricity. The steam is then condensed in a condenser and recycled to the boiler to repeat the process. While coal provides a cheap and abundant fuel source, it is non-renewable and burning it releases greenhouse gases contributing to global warming.
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 Panipat Thermal Power Station located in Haryana, India. It discusses the key elements of a thermal power station including coal handling, the steam generation process, turbines, generators, condensers, cooling towers and switchyards. The power station uses coal to produce steam that drives turbines connected to generators to produce 1367.7 MW of electricity for Haryana. In conclusion, it notes that Panipat Thermal is the largest power plant in Haryana.
This document is a seminar report submitted by Mukesh Kumar for partial fulfillment of a Bachelor of Technology degree in Mechanical Engineering. It discusses thermal power plants, including an overview of their operation and efficiency, descriptions of typical components like boilers and steam cycles, and examples of power plants located in India with a focus on those in Rajasthan. The document received certification from internal and external examiners for Mukesh Kumar's seminar work on the topic of thermal power plants.
The document provides details about an industrial training project at the Wanakbori Thermal Power Station (WTPS). It includes:
1) An acknowledgment thanking those who facilitated the training.
2) An index outlining the topics to be covered, including details of the boiler, turbine, condenser, coal handling plant, and more.
3) An abstract stating the aim was to study the mechanical instruments involved in power generation and improve practical knowledge.
KTPS-V Station in Andhra Pradesh was commissioned in 1996 as the first major thermal power station in the state. It uses a steam turbine generator system where coal is burned to produce steam that spins the turbine to generate electricity. The station has four main circuits: steam and water, air and gas, coal and ash, and cooling water. Steam is produced in a boiler and drives high, intermediate, and low pressure turbines connected to an electrical generator before condensing in a condenser.
NTPC Dadri power plant has an installed capacity of 2642 MW including 1820 MW from thermal units and 817 MW from gas units. It sources coal from Piparwara mine in Jharkhand and water from Upper Ganga Canal. The basic processes include coal handling, combustion in boilers to produce steam, steam passing through turbines to generate electricity, and condensation of steam in condensers. Key components are coal handling plant, boilers, turbines, condensers, cooling towers, ESPs for emissions control, and chimney. Fly ash is a byproduct that is used in construction materials.
SUMMER INTERNSHIP(INDUSTRAIL REPORT) ON THERMAL POWER PLANT Amit Gupta
The document describes the key components and processes involved in a typical coal-fired thermal power plant, including coal handling, pulverizing, combustion in the boiler, steam generation, power generation in the turbine, and condensing spent steam. It also provides details on equipment like draft fans, superheaters, reheaters, the ash handling system, feedwater heaters, and installed capacity of thermal power plants in Rajasthan.
introduction to thermal powerplant,type of thermal powerplant,captive powerplant,rankin cycle,co-generation powerplant,subcritical powerplant,supercritical powerplant,theory of operation,working principle,parts of powerplant,boiler,turbine,etc
A thermal power station uses coal to generate steam, which spins turbines that create electrical power. Coal is pulverized and burned to heat water and create steam. The steam spins turbines connected to generators, producing electricity. The steam is then condensed back into water and recycled through the system. Thermal power stations use various pumps, fans, condensers and other equipment to efficiently convert the energy in coal into electrical power for transmission and distribution.
The document discusses the Sikka thermal power plant located in Jamnagar district, India. It describes that the plant was installed in 1984 with one 120MW unit, and a second unit was later added for a total capacity of 240MW. The plant uses coal from nearby states as its main fuel. It also has access to seawater for cooling purposes. The document explains the basic processes that occur in thermal power plants, including converting the chemical energy in coal to heat, using heat to create steam to turn turbines and generate electricity. It provides details on the key components of thermal power plants like boilers, turbines, condensers, and electrostatic precipitators.
Internship Report on thermal power station in vizag steel plantAbhishek Kumar
This document provides information about a study of power generation and distribution at a thermal power plant in Visakhapatnam Steel Plant. It discusses the key components of the thermal power plant including five water tube boilers that produce steam at 101 atmospheres of pressure and 540 degrees Celsius. The steam powers five steam turbines coupled to generators with a total installed capacity of 286.5 MW. The document outlines the processes of coal combustion in the boilers, steam generation, power generation using steam turbines, and distribution of power within the steel plant. It also discusses operational aspects like load management and limits of the turbo generators.
The document provides technical details about Mejia Thermal Power Station (MTPS) in Bankura, West Bengal, India. MTPS has a total installed capacity of 2340MW generated across 8 units, with 4 units of 210MW each, 2 units of 250MW each, and 2 units of 500MW each. The document describes the various components that make up the thermal power generation process at MTPS, including the coal handling plant, water treatment plant, boilers, turbines, generators, transformers, and cooling towers.
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.
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.
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.
Vocational Training at DURGAPUR THERMAL POWER STATIONHIMANSHU KUMAR
This document provides an overview of the layout and equipment used at a thermal power plant. It describes the key components of the coal handling plant, main generating plant, ash handling plant, and switchyard. The main generating plant generates power by burning coal to produce steam, which spins turbines connected to generators to produce electricity. The coal handling plant receives, crushes, and supplies coal to the boilers, while the ash handling plant removes and disposes of ash after combustion.
This document provides an overview of the processes involved in a thermal power plant. It begins by explaining that thermal power plants convert chemical energy stored in fuels like coal into heat energy and then electrical energy. It describes the basic energy conversions that occur in the boiler, turbine and generator. It then provides specific details about the Kalisindh Thermal Power Plant in Jhalawar, India, including its location, capacity and land acquisition. The document outlines the basic systems and processes within a thermal power plant, including coal handling, steam generation, power generation via turbines and generators, and electrical transmission. It provides diagrams illustrating the Rankine cycle and process flow within the plant.
The document is a seminar presentation on thermal power plants. It discusses the classification, layout, components and working of thermal power plants. The main components discussed are the coal handling plant, pulverizing plant, boiler, turbine, condenser, cooling tower, feedwater heater and economizer. Thermal power plants in Rajasthan like Kota, Suratgarh, Giral, Chhabra and Kalisindh are also summarized along with their installed capacities and commissioning details. Advantages, limitations and site selection parameters for thermal plants are also highlighted.
The document provides information about Kolaghat Thermal Power Station located in West Bengal, India. It has six units totaling 1,260 MW capacity. The power plant uses a steam turbine process to convert the heat from burning coal into electrical energy. It describes the main equipment used including the coal handling plant, boiler, turbine, condenser, and electrical equipment like transformers and generators. The document provides technical specifications for many of the major components.
This document provides a summary of Maneeshkumar Shukla's 4-week summer training at the 3x210 MW Anpara 'A' Thermal Power Station in Anpara, Sonbhadra, Uttar Pradesh, India. It includes an acknowledgement of those who supported the training, a certificate of completion signed by the supervising engineer, and sections describing the power production process involving coal handling, combustion, steam generation, turbine operation, and water management at the facility.
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.
NTPC operates a thermal power plant in Shaktinagar, Uttar Pradesh with an installed capacity of 2000 MW. The plant uses coal from the nearby Jayant mines to fuel its boilers and generate steam, which powers steam turbines that are coupled to generators to produce electricity. Water for the plant is sourced from the Rihand Reservoir. The plant has 7 units of varying sizes that generate electricity for distribution to several states in northern India. An industrial training presentation was given on the functioning of the key components in the thermal power generation process at this plant.
Thermal power plants convert the heat energy from burning coal into electrical energy. Coal is burned in a boiler to produce steam which spins a turbine connected to a generator to produce electricity. The main equipment includes the coal handling plant, pulverizer, boiler, turbine, alternator, condenser and cooling towers. Thermal power is a major source of electricity in many countries but produces carbon emissions and other pollutants. The document provides an overview of how thermal power plants work and their advantages of low-cost fuel but also disadvantages of environmental impacts.
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.
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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.
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The document summarizes a summer training report submitted by a student at the Uttar Pradesh Rajya Vidhyut Utpadan Nigam Limited thermal power plant in Anpara, Sonebhadra, India. The report provides an overview of the power plant, including its layout, products like electricity and ash, and the production process. It also includes a chronological training diary of the student's activities during the summer, such as familiarizing with the plant components and studying the turbines. The production process follows the Rankine cycle, where coal is combusted to produce steam that drives the turbine and generates electricity.
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The document provides theory, diagrams, component lists and step-by-step procedures for students to conduct hands-on experiments in an electrical engineering lab
This document discusses engineering and AutoCAD. It defines an engineer as a person who designs, builds, or maintains machines and public works. It states that drawing is the primary language of engineers, as drawings communicate design ideas from the engineer to workers. It then discusses the engineering design cycle and different types of drawings, including manual drafting. It introduces AutoCAD as automatic computer-aided design software and lists different versions from 2006 to 2010. It notes that AutoCAD can be used to create 2D, 3D, and presentation drawings and discusses basic drawing commands.
Patel transformer PVT. LTD is a small-scale company that provides maintenance and repair for distribution transformers located in Palanpur, India. A transformer is a static machine that transforms power from one circuit to another without changing frequency, using Faraday's law of electromagnetic induction. The inspection report will examine the transformer core, insulation machine, coils, design criteria, oven, oil tank, and cleaning/painting. Transformer tests include testing the low-voltage and high-voltage sides.
The diesel engine was invented in the year 1893, by a young German Engineer, called Rudolf Diesel. But it was only nineteen years later, that the first Diesel locomotive came into existence.
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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.
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AI offers the capability to process vast amounts of data, identify patterns, and make predictions with a level of speed and accuracy unattainable by traditional methods. This has profound implications for mechanical engineering, enabling more efficient design processes, predictive maintenance strategies, and optimized manufacturing operations. AI-driven tools can learn from historical data, adapt to new information, and continuously improve their performance, making them invaluable in tackling the multifaceted challenges of modern mechanical engineering.
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3. This power plant was installed in Sikka in
Jamnagar district in 1984.
Initially it has only one unit had installed which
had capacity of only 120MW.
So now total capacity of power plant become 240
MW of electricity generation.
In Sikka these units are designed and monitoring
has been done by GSVCL engineers, TATA
consulting engineers and BHEL engineers
Sikka thermal power plant has been situated at the
coast of Arabian Sea, so there is lot of sea water is
available for cooling purpose
4. In thermal power plant Sikka main fuel used is
bituminous coal which has been exported from
other states like Bihar and Madhya Pradesh.
This coal has been taken from both by truck or by
wagons.
In future another 120MW plants will be installed for
improving plant capacity.
So the future of the Sikka power station has been
quite bright.
5.
6. In thermal power plants, chemical energy of coal is
converted into heat energy from burning coal in
boiler. The heat water makes steam.
The steam turns a turbine, creating mechanical
energy to run generator , Magnets turns inside the
generator, where mechanical energy is converted
into electrical energy.
7. An electrical power station which utilizes thermal energy (
from coal) as a part of its electrical production system is
known as thermal power station.
The schematic diagram of thermal power plant can be divided
into following steps for simplicity.
step-1 coal and ash handling arrangement
step-2 air and flue gages arrangement
step-3 feed water and steam generation arrangement
step-4 electricity transmission arrangements
step-5 cooling arrangement
8.
9. BOILER
SUPER-HEATER
STEAM TURBINE
CONDENSER
ELECTROSTATIC PRESIPITATOR
ALTERNATOR
PARTS OF THERMAL PLANTS
10. A Boiler is closed vessel in which water is converted
into steam by utilizing the heat of coal combustion.
The boiler is designed to meet the nominal
requirement of 120MW generator set.
The unit is designed for the maximum continuous
rating of 383 T/hr of steam flow at pressure of 135
kg/cm2 and steam temperature of 540c.
Steam boiler classified into two type
1. water tube boiler
2. fire tube boiler.
12. The turbine is horizontal compounded,
reheat, impulsive type machine, with
continuous maximum economical rating of
120 MW at the generator terminal at a speed
of 3000 rpm. The design inlet conditions are
127.6 kg/cm2 and 538c for main steam .
STEAM TURBINE
14. 1. smoke particles pick up a negative charge.
2. smoke particles are attracted to collecting
plates.
3. collecting plates are knocked to remove the
smoke particles.
An electrostatic precipitator is an electrical device
which is use for removing dangerous smoke
particles ( fly ash ) from combustion gases prior to
release from a power plant’s stack.
A high voltage applied to the electrodes a strong
electrical field is created b/w the electrodes and
flue gases is ionised.
15. When steam exhaust from the turbine it exhaust in
the condenser, which is exhausted with high
temperature and low pressure.
Condenser is made up of copper tubes which are in
large sizes. Generally two types of condenser are
used one way and two way types of condensers.
In sikka thermal power station two type circulating
tubes are used. When water passes through the
tubes and steam of the tube. Cooling water passes
through the tubes. When this steam contacted with
the water it becomes cooled.
CONDENSER
16. One of the important unit and part of the thermal
power plant is switchyard. In Sikka thermal power
plant there are two generating units of 120 MW.
In this power station two switchyard one of 132 KV
and another one is 66 KV.
SWITCHYARD