Hello frinds
this is the ppt of kota super power plant station kota u can take help from this ppt and can make report and ppt for presentation in your institute and plant
Narendra Meena
NIT AGARTALA
9352442545
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 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.
This document provides an overview of a thermal power plant. It begins by classifying power plants by their fuel sources and prime movers. It then introduces thermal power plants, explaining that they convert the heat energy of coal into electrical energy using a boiler to produce steam that drives a turbine connected to a generator. The document outlines the typical layout and main equipment of a thermal power plant, including coal handling, the boiler, turbine, condenser, and other auxiliary systems. It discusses advantages and limitations of thermal plants and considerations for site selection. Finally, it provides details on several major thermal power plants located in Rajasthan, India.
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.
Abhinav Kumar Mechanical Engineering Vocational Training NTPC Ltd UnchaharABHINAV KUMAR
This is the vocational training report needed to be submitted with the EDC HR Dept in order to acquire the certificate of completion. And additional copy is submitted with the Mechanical Department of my respective college.
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.
The document provides information about the NTPC Dadri power plant located in Uttar Pradesh, India. It has a coal-fired thermal power plant with a capacity of 1820 MW as well as a gas-fired plant of 817 MW and a 5 MW solar plant, totaling 2642 MW. The power plant uses a steam turbine generator process to convert the heat energy from coal combustion into electrical energy. It also discusses the various units involved in this process like the boiler, turbine, alternator, condenser, and cooling towers. The control and instrumentation department works to monitor and control parameters across the plant to ensure safe and efficient operations.
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.
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 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.
This document provides an overview of a thermal power plant. It begins by classifying power plants by their fuel sources and prime movers. It then introduces thermal power plants, explaining that they convert the heat energy of coal into electrical energy using a boiler to produce steam that drives a turbine connected to a generator. The document outlines the typical layout and main equipment of a thermal power plant, including coal handling, the boiler, turbine, condenser, and other auxiliary systems. It discusses advantages and limitations of thermal plants and considerations for site selection. Finally, it provides details on several major thermal power plants located in Rajasthan, India.
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.
Abhinav Kumar Mechanical Engineering Vocational Training NTPC Ltd UnchaharABHINAV KUMAR
This is the vocational training report needed to be submitted with the EDC HR Dept in order to acquire the certificate of completion. And additional copy is submitted with the Mechanical Department of my respective college.
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.
The document provides information about the NTPC Dadri power plant located in Uttar Pradesh, India. It has a coal-fired thermal power plant with a capacity of 1820 MW as well as a gas-fired plant of 817 MW and a 5 MW solar plant, totaling 2642 MW. The power plant uses a steam turbine generator process to convert the heat energy from coal combustion into electrical energy. It also discusses the various units involved in this process like the boiler, turbine, alternator, condenser, and cooling towers. The control and instrumentation department works to monitor and control parameters across the plant to ensure safe and efficient operations.
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.
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.
ELECTRICAL ENGINEERING THERMAL POWER PLANT Industrial ReportUtkarsh Chaubey
The document is an industrial training report submitted by Utkarsh Chaubey to Rajiv Gandhi Proudyogiki Vishwavidyalaya. It provides an overview of Utkarsh's training at the Shri Singaji Thermal Power Plant (SSTPP). The report includes sections on the power plant overview, the Rankine cycle used, classification of thermal power plants, typical components of a coal fired plant, site selection considerations, and descriptions of various systems within SSTPP such as the generator, switchyard, transformers, and safety measures.
The document 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
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.
Kota Super Thermal Power Station (KSTPS) is a coal-based power plant located in Rajasthan, India. It has a total installed capacity of 1240 MW generated across 7 units. The plant receives coal via train from nearby mines and uses water from the Chambal River. It employs a Rankine cycle with a coal handling plant, ash handling plant, electrostatic precipitators, turbo generators to produce power, and a cooling system using hydrogen. Transformers are used to step up the voltage from the generators to connect to the grid.
3.1 Steam power plant introduction, components, advantages and limitations.
3.2 Fuel handling system in power plant types and component
3.3 Electro-static precipitators.
3.4 Control systems of power plant elements, types, desirable
characteristics.
3.5 Steam temperature control and feed water control
3.6 Maintenance procedure of major components of steam 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
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.
The document provides information about a thermal power simulator training that took place at Essar Power Gujarat Ltd in Jamnagar, India. It acknowledges the organizers and mentors of the training. It then provides details about the Salaya power plant including its location, phases, capacity and key components. It describes the specifics of the 2x600 MW simulator used for training including its advantages. The document outlines the daily plan for the training and provides an overview of the key systems and circuits within the thermal power plant such as the boiler, turbine, generators, transformers and main circuits.
This document provides an overview of the Panipat Thermal Power Plant in Haryana, India. It details that the plant has a total generating capacity of 1,367.8 MW across 8 units. It describes the key raw materials used, including water from the Yamuna Canal, various types of fuel oils, and coal delivered by rail. It then outlines the major components and processes within the plant, including coal handling, boiler, turbine generation, and switchyard equipment. The goal of the plant is to generate power for the state of Haryana in an efficient commercial manner.
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.
NTPC Dadri is a coal-based thermal power plant located in Uttar Pradesh, India. It has a total installed capacity of 2,642 MW from coal, gas, and solar sources. The coal-based plant consists of two stages with a total of 6 units, consuming 13,000 metric tons of coal per day from local mines. The plant uses a Rankine cycle to generate power, with coal being pulverized and used to produce high pressure steam in boilers that drives steam turbines connected to electric generators. Ash is disposed of using an efficient electrostatic precipitator and stored on-site. The plant also focuses on education, health, and fly ash utilization in the local community.
The document provides an overview of the coal handling plant (CHP) at Anpara Thermal Power Station in Uttar Pradesh, India. It discusses the basic processes in a CHP, including receiving coal via rail or conveyor, crushing the coal, transporting it to bunkers via conveyor belts and trippers, and storing excess coal via stacking and reclaiming. The CHP handles coal from receipt to transporting it to boilers and bunkers. It also processes raw coal to the required size for boiler operations. The CHP faces various challenges like design issues due to lower quality coal, problems during monsoon season, and mechanical failures of equipment.
The document provides an overview of the coal handling plant at Anpara Thermal Power Station. It discusses the process of receiving coal via various transportation methods and processing it through primary and secondary crushers to the required size before storing it in bunkers. It also mentions the electrical equipment used in the coal handling plant like breakers, motors, and describes the general working process of crushing, conveying, and storing coal until it is sent to the coal mills for combustion in the boiler furnace. A layout diagram of the typical coal handling plant is also included.
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.
Vocational training at mejia thermal power plantNipak Banerjee
This document provides an overview of the vocational training program at the Mejia Thermal Power Plant. It describes the key components and systems of a thermal power plant, including the coal handling plant, pulverizing plant, draft fans, boiler, ash handling plant, turbine, condenser, cooling tower, and switchyard. It also discusses the electrical, mechanical, and safety operations at the plant. The document is intended to educate trainees on the general layout and functions of the major equipment used in power generation at the Mejia Thermal Power Plant.
This document provides an overview of a practical training seminar presented to the CompuCom Institute of Information Technology & Management Jaipur on NTPC Kahalgaon power station. It discusses the history and setup of NTPC as India's largest power company. The summary describes the three step process of generating electricity through: 1) converting coal to steam, 2) using steam to power turbines for mechanical energy, and 3) generating electricity through power stations and distributing it via transmission lines. Key electrical equipment at the power station like alternators and transformers are also outlined.
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.
MSEB was set up in 1960 to generate, transmit and distribute power to all consumers in
Maharashtra excluding Mumbai. MSEB was the largest SEB in the country. The generation
capacity of MSEB has grown from 760 MW in 1960-61 to 9771 MW in 2001-02. The customer
base has grown from 1,07,833 in 1960-61 to 1,40,09,089 in 2001-02.
C.S.T.P.S in contribution much in field of production of electricity. It is not only number
one thermal power station in Asia but also has occupied specific position on the international
map.
The first set was commission on August 1983 & was dedicated to nation by then PM
(late) Mrs. Indira Gandhi & second set commission on July 1984. The third & fourth units of
CSTPS under stage 2 were commissioned on the 3rd May 1985 & 8th March 1986 respectively.
The units 5 & 6 were commissioned on the 22nd March 1991 & 11th March 1992 respectively one
more units of 500MW was added to the CSTPS on making its generation to 2340 MW &
making “C.S.T.P.S.” as the giant in Power Generation of CSTPS.
This document provides a summary of a student's 6-week summer training report at the Panipat Thermal Power Station (PTPS) in India. It discusses the key components and processes at the power plant, including the boiler, turbine, generator, condenser, cooling tower, electrostatic precipitator, ash handling plant, and switchyard. The document also provides an overview of the three main inputs to the power station - water, fuel, and coal - and explains how coal is converted to steam, steam is converted to mechanical power via the turbine, and electricity is generated and transmitted from the power plant.
Null Bangalore | Pentesters Approach to AWS IAMDivyanshu
#Abstract:
- Learn more about the real-world methods for auditing AWS IAM (Identity and Access Management) as a pentester. So let us proceed with a brief discussion of IAM as well as some typical misconfigurations and their potential exploits in order to reinforce the understanding of IAM security best practices.
- Gain actionable insights into AWS IAM policies and roles, using hands on approach.
#Prerequisites:
- Basic understanding of AWS services and architecture
- Familiarity with cloud security concepts
- Experience using the AWS Management Console or AWS CLI.
- For hands on lab create account on [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
# Scenario Covered:
- Basics of IAM in AWS
- Implementing IAM Policies with Least Privilege to Manage S3 Bucket
- Objective: Create an S3 bucket with least privilege IAM policy and validate access.
- Steps:
- Create S3 bucket.
- Attach least privilege policy to IAM user.
- Validate access.
- Exploiting IAM PassRole Misconfiguration
-Allows a user to pass a specific IAM role to an AWS service (ec2), typically used for service access delegation. Then exploit PassRole Misconfiguration granting unauthorized access to sensitive resources.
- Objective: Demonstrate how a PassRole misconfiguration can grant unauthorized access.
- Steps:
- Allow user to pass IAM role to EC2.
- Exploit misconfiguration for unauthorized access.
- Access sensitive resources.
- Exploiting IAM AssumeRole Misconfiguration with Overly Permissive Role
- An overly permissive IAM role configuration can lead to privilege escalation by creating a role with administrative privileges and allow a user to assume this role.
- Objective: Show how overly permissive IAM roles can lead to privilege escalation.
- Steps:
- Create role with administrative privileges.
- Allow user to assume the role.
- Perform administrative actions.
- Differentiation between PassRole vs AssumeRole
Try at [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
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.
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.
ELECTRICAL ENGINEERING THERMAL POWER PLANT Industrial ReportUtkarsh Chaubey
The document is an industrial training report submitted by Utkarsh Chaubey to Rajiv Gandhi Proudyogiki Vishwavidyalaya. It provides an overview of Utkarsh's training at the Shri Singaji Thermal Power Plant (SSTPP). The report includes sections on the power plant overview, the Rankine cycle used, classification of thermal power plants, typical components of a coal fired plant, site selection considerations, and descriptions of various systems within SSTPP such as the generator, switchyard, transformers, and safety measures.
The document 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
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.
Kota Super Thermal Power Station (KSTPS) is a coal-based power plant located in Rajasthan, India. It has a total installed capacity of 1240 MW generated across 7 units. The plant receives coal via train from nearby mines and uses water from the Chambal River. It employs a Rankine cycle with a coal handling plant, ash handling plant, electrostatic precipitators, turbo generators to produce power, and a cooling system using hydrogen. Transformers are used to step up the voltage from the generators to connect to the grid.
3.1 Steam power plant introduction, components, advantages and limitations.
3.2 Fuel handling system in power plant types and component
3.3 Electro-static precipitators.
3.4 Control systems of power plant elements, types, desirable
characteristics.
3.5 Steam temperature control and feed water control
3.6 Maintenance procedure of major components of steam 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
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.
The document provides information about a thermal power simulator training that took place at Essar Power Gujarat Ltd in Jamnagar, India. It acknowledges the organizers and mentors of the training. It then provides details about the Salaya power plant including its location, phases, capacity and key components. It describes the specifics of the 2x600 MW simulator used for training including its advantages. The document outlines the daily plan for the training and provides an overview of the key systems and circuits within the thermal power plant such as the boiler, turbine, generators, transformers and main circuits.
This document provides an overview of the Panipat Thermal Power Plant in Haryana, India. It details that the plant has a total generating capacity of 1,367.8 MW across 8 units. It describes the key raw materials used, including water from the Yamuna Canal, various types of fuel oils, and coal delivered by rail. It then outlines the major components and processes within the plant, including coal handling, boiler, turbine generation, and switchyard equipment. The goal of the plant is to generate power for the state of Haryana in an efficient commercial manner.
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.
NTPC Dadri is a coal-based thermal power plant located in Uttar Pradesh, India. It has a total installed capacity of 2,642 MW from coal, gas, and solar sources. The coal-based plant consists of two stages with a total of 6 units, consuming 13,000 metric tons of coal per day from local mines. The plant uses a Rankine cycle to generate power, with coal being pulverized and used to produce high pressure steam in boilers that drives steam turbines connected to electric generators. Ash is disposed of using an efficient electrostatic precipitator and stored on-site. The plant also focuses on education, health, and fly ash utilization in the local community.
The document provides an overview of the coal handling plant (CHP) at Anpara Thermal Power Station in Uttar Pradesh, India. It discusses the basic processes in a CHP, including receiving coal via rail or conveyor, crushing the coal, transporting it to bunkers via conveyor belts and trippers, and storing excess coal via stacking and reclaiming. The CHP handles coal from receipt to transporting it to boilers and bunkers. It also processes raw coal to the required size for boiler operations. The CHP faces various challenges like design issues due to lower quality coal, problems during monsoon season, and mechanical failures of equipment.
The document provides an overview of the coal handling plant at Anpara Thermal Power Station. It discusses the process of receiving coal via various transportation methods and processing it through primary and secondary crushers to the required size before storing it in bunkers. It also mentions the electrical equipment used in the coal handling plant like breakers, motors, and describes the general working process of crushing, conveying, and storing coal until it is sent to the coal mills for combustion in the boiler furnace. A layout diagram of the typical coal handling plant is also included.
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.
Vocational training at mejia thermal power plantNipak Banerjee
This document provides an overview of the vocational training program at the Mejia Thermal Power Plant. It describes the key components and systems of a thermal power plant, including the coal handling plant, pulverizing plant, draft fans, boiler, ash handling plant, turbine, condenser, cooling tower, and switchyard. It also discusses the electrical, mechanical, and safety operations at the plant. The document is intended to educate trainees on the general layout and functions of the major equipment used in power generation at the Mejia Thermal Power Plant.
This document provides an overview of a practical training seminar presented to the CompuCom Institute of Information Technology & Management Jaipur on NTPC Kahalgaon power station. It discusses the history and setup of NTPC as India's largest power company. The summary describes the three step process of generating electricity through: 1) converting coal to steam, 2) using steam to power turbines for mechanical energy, and 3) generating electricity through power stations and distributing it via transmission lines. Key electrical equipment at the power station like alternators and transformers are also outlined.
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.
MSEB was set up in 1960 to generate, transmit and distribute power to all consumers in
Maharashtra excluding Mumbai. MSEB was the largest SEB in the country. The generation
capacity of MSEB has grown from 760 MW in 1960-61 to 9771 MW in 2001-02. The customer
base has grown from 1,07,833 in 1960-61 to 1,40,09,089 in 2001-02.
C.S.T.P.S in contribution much in field of production of electricity. It is not only number
one thermal power station in Asia but also has occupied specific position on the international
map.
The first set was commission on August 1983 & was dedicated to nation by then PM
(late) Mrs. Indira Gandhi & second set commission on July 1984. The third & fourth units of
CSTPS under stage 2 were commissioned on the 3rd May 1985 & 8th March 1986 respectively.
The units 5 & 6 were commissioned on the 22nd March 1991 & 11th March 1992 respectively one
more units of 500MW was added to the CSTPS on making its generation to 2340 MW &
making “C.S.T.P.S.” as the giant in Power Generation of CSTPS.
This document provides a summary of a student's 6-week summer training report at the Panipat Thermal Power Station (PTPS) in India. It discusses the key components and processes at the power plant, including the boiler, turbine, generator, condenser, cooling tower, electrostatic precipitator, ash handling plant, and switchyard. The document also provides an overview of the three main inputs to the power station - water, fuel, and coal - and explains how coal is converted to steam, steam is converted to mechanical power via the turbine, and electricity is generated and transmitted from the power plant.
Null Bangalore | Pentesters Approach to AWS IAMDivyanshu
#Abstract:
- Learn more about the real-world methods for auditing AWS IAM (Identity and Access Management) as a pentester. So let us proceed with a brief discussion of IAM as well as some typical misconfigurations and their potential exploits in order to reinforce the understanding of IAM security best practices.
- Gain actionable insights into AWS IAM policies and roles, using hands on approach.
#Prerequisites:
- Basic understanding of AWS services and architecture
- Familiarity with cloud security concepts
- Experience using the AWS Management Console or AWS CLI.
- For hands on lab create account on [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
# Scenario Covered:
- Basics of IAM in AWS
- Implementing IAM Policies with Least Privilege to Manage S3 Bucket
- Objective: Create an S3 bucket with least privilege IAM policy and validate access.
- Steps:
- Create S3 bucket.
- Attach least privilege policy to IAM user.
- Validate access.
- Exploiting IAM PassRole Misconfiguration
-Allows a user to pass a specific IAM role to an AWS service (ec2), typically used for service access delegation. Then exploit PassRole Misconfiguration granting unauthorized access to sensitive resources.
- Objective: Demonstrate how a PassRole misconfiguration can grant unauthorized access.
- Steps:
- Allow user to pass IAM role to EC2.
- Exploit misconfiguration for unauthorized access.
- Access sensitive resources.
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- Perform administrative actions.
- Differentiation between PassRole vs AssumeRole
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NARENDRA MEENA REPORT AND PPT
1. NATIONAL INSTITUTE OF TECHNOLOGY, AGARTALA
DEPARTMENT OF MECHANICAL ENGINEERING
SUMMER INTERNSHIP
THERMAL POWER PLANT
TO STUDY THE GENERAL CONCEPTS AND WORKING OF KOTA SUPER THERMAL POWER STATION
, AND IT’S COMPONENTS
SUBMITTED TO SUBMITTED BY
Dr.R.K, BHOGENDRO MEITEI NARENDRA KUMAR MEENA
Assistant Professor 19UME098
Mechanical Department
2. ACKNOWLEDGEMENT
I want to thank Mr. Satyendra K. Jain, Executive Engineer, KSTPS for allowing me to undergo the
summer vocational training. My sincerest thanks to him in spite of his busy schedule enlightened me with
his technical concepts and personal life lessons. My humble thanks to him for providing his personal
attention for arranging all the support required for the smooth conduct of our training. All the Junior
Engineers and other team members are highly appreciated for teaching us concepts while doing their
duties in Parallel.
I’m ever thank full to my parents. . In fact, many people have contributed to this report and I would love to
express my gratitude to all of them who helped me through this training.
Narendra Kumar Meena
19UME098
3. CONTENTS
• Objectives
• About
• Design
• General layout
• Production Process
• Main Components Of Coal Fired Thermal Power Station
• Conclusion
• References
4. Objectives
• To learn the basic working of thermal power plants.
• To learn about various components of the same.
• To develop understanding of operations of turbines and boiler.
• To learn about functioning and importance of all the components of power plants.
5. About
• It was established in 1983.
• Kota Super Thermal Power Station is located on the left bank of river Chambal in
Rajasthan’s principal industrial city Kota.
• It is the first coal based Electricity Generating Power Plant in Rajasthan.
• At present the total installed capacity of KSTPS is 1240MW.
• Infrastructural facilities like adequate water availability in Kota Barrage throughout the year.
• Bituminous coal is used as fuel.
• Coal India Limited supplies coal from coal mines of coal producing subsidiaries SECL &
NCL to KSTPS.
6.
7. Stage Unit No. Capacity(mw) Commissioning Date Status
I 1 110 17.1.1983 Running
2 110 13.7.1983 Running
II 3 210 25.9.1988 Running
4 210 1.5.1989 Running
III 5 210 26.3.1994 Running
IV 6 195 30.7.2003 Running
V 7 195 30.5 2009 Running
Design
Kota super thermal power station is designed in following stages .
8. Fig. 3 – General Layout
General Layout
• Fuel & Ash Circuit
• Air & Gas Circuit
• Feed Water & Steam Circuit
• Cooling Water Circuit
9. Production Process
1. First , the pulverized coal is transferred to the furnace through coal handling plant via conveyer belts.
2. Boiler water is converted to steam by the combustion of coal air mixture in furnace.
3. This steam is separated by boiler drum and taken to superheater.
4. After this superheated steam is taken to high pressure turbine where the steam is utilized to rotate the
turbine and the resultant is rotational energy.
5. This steam is now transferred to reheater from this to intermediate pressure turbine and then to low
pressure turbine.
6. The outlet steam from low pressure turbine is condensed in condenser .
7. This condensed water is collected in hot well and is again transferred to the boiler in a closed cycle.
8. The rotational energy produced by high pressure turbine is converted into electrical energy in the generator
11. Main Components of Coal Fired Thermal
Power Station
• Coal Handling Plant
• Boiler
• Ash Handling Plant
• Steam Turbine
• Electricity generator
• Cooling system
• Control panel
12. Coal Handling Plant :--
Coal handling plant can be called the heart of the thermal power plant .
It can divided into 3 sections :--
a. Wagon Unloading System
b. Crushing System
c. Conveying System
In coal handling plant coal transferring follows these steps :--
The wagon tripler unloads the coal from the wagon to hopper. Hopper is made of of iron is in form of net.
Hopper allows to pass coal less than 200mm.
Crusher house crush the coal to 200mm size.
Lastely the conveying belst are used to convey the coal to funace.
14. Fig. 6 – boiler
Boiler :-
• A Boiler( or steam generator ) is a closed vessel in which water under pressure ic
converted into steam .
• The boiler in plant is water tube boiler in which water flows inside the tubes and hot
gases flow outside the tubes.
• Hot water or steam used to transfer heat transfer to a process.
• Furnace :- furnace is primary part of boiler where the chemical energy of coal is
convertd ito thermal energy by combustion
15. Air
(Atmosphere) Air pre heater Boiler
Boiler tubes
Super heater
Chimney
Flue gases
Ash Handling Plant :--
In thermal plant coal is generally used as fuel & hence the ash is produced as the
byproduct. Ash generated in power is about 30 – 40 % of total consumption
16. Rated Output
110 MW
Rotor Speed
300 RPM
Clockwise
Direction
Maximum Steam
Pressure
146 atm
Fig. 7 – Steam Turbine
Steam Turbine :--
Steam Turbine is a machine in which a shaft is rotated steadily by impact or reaction of current
or stream of working substances upon blades of a wheel.
Technical Data Of Turbines
17. For Generator
(110MW)
Current : 7720A
Frequency : 50 Hz
Terminals : 6
Electricity Generator :--
• An electrical generator is a machine which converts mechanical energy into electrical
energy through electro mechanical conversion.
• The generator is driven by directly coupled steam turbine at a speed of 3000 RPM.
18. Fig. 8 – condenser
Cooling system :--
• In KSTPS Hydrogen cooling system ic employed for generator cooling.
• Hydrogen is used because of its superior cooling properties & we can eliminate the
fire risk because it doesn’t support combustion.
• Thermal conductivity of H2 is 7.3 times of air.
19. Control Panel :--
• All the Basic Parameters like Temperature Of Steam & Air , Flow Of Water , Air ,
Pressure , Electricity Generation etc. are controlled in control panel .
• And to detect any irregularities in functioning of any component of plant .
•
• Different control panels :--
•
• CONTROL PANEL 1 – FAN CONTROL DESK
• CONTROL PANEL 2 – FUEL CONTROL DESK
• CONTROL PANEL 3 – STEAM & WATER CONTROL DESK
• CONTROL PANEL 4 – TURBINE CONTROL DESK
• CONTROL PANEL 5 – GENERATOR CONTROL PANEL
20. Conclusion
• I have done through study about the Kota super thermal power station.
• I have gathered the brief knowledge about all the components used in thermal power
plant. And their use in plant and what role they play in producing electricity.
• I have gain an understanding about the working of plant and working principle of the
plant