This document contains questions related to energy sources, renewable energy, energy consumption, energy efficiency, energy conservation, greenhouse gases, acid rain, energy security, and energy auditing. It includes questions on types of energy sources, primary energy sources, renewable energy sources, coal production in India, reserve to production ratio, final energy consumption, greenhouse gas effect, key greenhouse gases, effects of acid rain, differentiation between energy conservation and efficiency, basis for energy security, sources of air pollutants, forms of energy with examples, energy intensity, positive forces to reduce energy consumption, strategies for better energy security, long-term energy strategies, benefits of energy efficiency programs, energy pricing in India, economic reforms in coal, oil, natural gas
The document proposes installing an energy saving heating system using 4 units of EP-CDH-015 heaters and 4 units of 10,000L hot water tanks to supply the daily hot water needs of 230 hotel rooms. This system would save 55.64% on monthly energy costs compared to the existing diesel boiler system, with a return on investment period of 37 months. The proposed system can generate 2005.81 kW of heat daily needed to supply 57,500L of hot water at a lower operating cost than the current system.
The document analyzes the use of a Stirling engine in a cogeneration system based on biomass gasification. It compares a reference CHP system using a piston engine to an advanced system including a Stirling engine. The systems are modeled and their electrical output, heat output, efficiency, and economic viability in terms of net present value ratio are calculated for different operating temperatures of the Stirling engine and two types of heat consumers. The results show that the Stirling engine can improve system performance and profitability, especially for lower gas cooling degrees and industrial heat consumers.
The document recommends replacing 12 old chillers with new, more efficient 20-ton chillers to save on energy costs. Installing the new chillers would save an estimated $44,070 per year from reduced electricity and natural gas usage. The payback period would be 4.18 years based on a total implementation cost of $241,000 minus available rebates of $56,920.
The document discusses power generation economics and cost calculations. It covers:
1) Electricity generation requires a power station to transform fuel into electrical energy at a cost, including plant/equipment, fuel, operating costs, and transmission/distribution costs shared by consumers.
2) Cost of electricity has fixed costs like capital investment and variable costs like fuel that change with generation levels.
3) Methods are described to calculate generation costs factoring in parameters like plant capacity and load factors, fuel costs, efficiency rates, maintenance costs, and more.
This study experimentally investigated the performance of a flat plate solar air heater at different air mass flow rates. Tests were conducted to measure energy and exergy efficiency. It was found that increasing the mass flow rate from 0.036 kg/s to 0.042 kg/s resulted in a 20% increase in energy efficiency and a 36% increase in exergy efficiency. The maximum daily energy efficiency of 56% occurred at a mass flow rate of 0.042 kg/s, while the maximum daily exergy efficiency of 1.46% also occurred at this highest mass flow rate. Increasing the mass flow rate improved the performance of the solar air heater.
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
The papers for publication in The International Journal of Engineering& Science are selected through rigorous peer reviews to ensure originality, timeliness, relevance, and readability.
balance de materia horno de arco electricowaddwqdsa
This document describes models for calculating electrical energy consumption in electric arc furnaces (EAFs). It presents a statistical formula developed using data from over 50 furnaces that estimates electrical energy demand based on process variables. It also describes an online energy balance model used at a DC EAF in Germany that includes gas analysis and energy loss measurements. A dynamic mass and energy balance model was created by combining the statistical and online models. The models provide tools to improve EAF operation and control.
The document provides information about heat treatment processes. It defines heat treatment as a process of heating and cooling metals and alloys in the solid state to change their properties. Heat treatment is done to change properties like strength, hardness, toughness etc. of steels. The key heat treatment processes described are annealing, normalizing, hardening and tempering. Annealing involves heating steel above or below its critical temperature, holding, and slow cooling to soften it and relieve stresses. The goals, processes, and effects of various annealing types like full annealing and spheroidizing annealing are explained.
The document proposes installing an energy saving heating system using 4 units of EP-CDH-015 heaters and 4 units of 10,000L hot water tanks to supply the daily hot water needs of 230 hotel rooms. This system would save 55.64% on monthly energy costs compared to the existing diesel boiler system, with a return on investment period of 37 months. The proposed system can generate 2005.81 kW of heat daily needed to supply 57,500L of hot water at a lower operating cost than the current system.
The document analyzes the use of a Stirling engine in a cogeneration system based on biomass gasification. It compares a reference CHP system using a piston engine to an advanced system including a Stirling engine. The systems are modeled and their electrical output, heat output, efficiency, and economic viability in terms of net present value ratio are calculated for different operating temperatures of the Stirling engine and two types of heat consumers. The results show that the Stirling engine can improve system performance and profitability, especially for lower gas cooling degrees and industrial heat consumers.
The document recommends replacing 12 old chillers with new, more efficient 20-ton chillers to save on energy costs. Installing the new chillers would save an estimated $44,070 per year from reduced electricity and natural gas usage. The payback period would be 4.18 years based on a total implementation cost of $241,000 minus available rebates of $56,920.
The document discusses power generation economics and cost calculations. It covers:
1) Electricity generation requires a power station to transform fuel into electrical energy at a cost, including plant/equipment, fuel, operating costs, and transmission/distribution costs shared by consumers.
2) Cost of electricity has fixed costs like capital investment and variable costs like fuel that change with generation levels.
3) Methods are described to calculate generation costs factoring in parameters like plant capacity and load factors, fuel costs, efficiency rates, maintenance costs, and more.
This study experimentally investigated the performance of a flat plate solar air heater at different air mass flow rates. Tests were conducted to measure energy and exergy efficiency. It was found that increasing the mass flow rate from 0.036 kg/s to 0.042 kg/s resulted in a 20% increase in energy efficiency and a 36% increase in exergy efficiency. The maximum daily energy efficiency of 56% occurred at a mass flow rate of 0.042 kg/s, while the maximum daily exergy efficiency of 1.46% also occurred at this highest mass flow rate. Increasing the mass flow rate improved the performance of the solar air heater.
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
The papers for publication in The International Journal of Engineering& Science are selected through rigorous peer reviews to ensure originality, timeliness, relevance, and readability.
balance de materia horno de arco electricowaddwqdsa
This document describes models for calculating electrical energy consumption in electric arc furnaces (EAFs). It presents a statistical formula developed using data from over 50 furnaces that estimates electrical energy demand based on process variables. It also describes an online energy balance model used at a DC EAF in Germany that includes gas analysis and energy loss measurements. A dynamic mass and energy balance model was created by combining the statistical and online models. The models provide tools to improve EAF operation and control.
The document provides information about heat treatment processes. It defines heat treatment as a process of heating and cooling metals and alloys in the solid state to change their properties. Heat treatment is done to change properties like strength, hardness, toughness etc. of steels. The key heat treatment processes described are annealing, normalizing, hardening and tempering. Annealing involves heating steel above or below its critical temperature, holding, and slow cooling to soften it and relieve stresses. The goals, processes, and effects of various annealing types like full annealing and spheroidizing annealing are explained.
This document contains a test for an engineering thermodynamics exam with multiple choice and long answer questions. It covers topics like the first and second laws of thermodynamics, Carnot cycle efficiency, psychrometrics, gas properties, steam tables and Rankine cycle. The test has three parts with questions on thermodynamic processes, cycles, properties and applications to heating, cooling and power systems. Students are asked to analyze thermodynamic systems, calculate efficiencies, energy and mass transfers, exhaust velocities and more.
IRJET-Detailed Energy Audit in a Captive Cogeneration PlantIRJET Journal
D.Rajani Kant , B.Sudheer Prem Kumar, N.Ravi Kumar, R.Virendra,J.Suresh Babu " Detailed Energy Audit in a Captive Cogeneration Plant ", International Research Journal of Engineering and Technology (IRJET), Volume2,issue-01 April 2015.e-ISSN:2395-0056, p-ISSN:2395-0072. www.irjet.net
Abstract
The rate of exploitation of the energy resources has been expanding over time and resulted in reduction of fossil fuel reserves. Efficiency of all resources is crucial both in environmental and economic sense. Using energy inefficiently creates waste in all the world’s economies. It has environmental impacts with regional, local and global implications.The key object is to adopt energy management in every field in order to reduce the wastage of energy sources and cost effectiveness without affecting productivity and growth.
This document provides an overview and report on a vocational training project conducted by Tarun Kumar at the Kanti Thermal Power Station. It includes sections on acknowledging those who supported the training, an abstract describing the thermal power generation process, a table of contents, and sections covering topics like the power plant overview, generation process, boiler components, turbines, and control systems. The document aims to provide insight gained from Tarun Kumar's month-long industrial training placement at the thermal power facility.
This document is a project report submitted by Sushant Kumar summarizing his one month vocational training at the Kanti Bijlee Utpadan Nigam Limited power plant. The report provides an overview of the plant's operations including the processes of generating electricity from coal, the main boiler and turbine components, and control systems used. It also describes the milling system for pulverizing coal and the light up process for initially igniting the coal furnace.
This document outlines exam questions for an engineering thermodynamics course. It includes 12 questions covering various topics in thermodynamics. The questions require students to calculate things like work, heat transfer, efficiency, and more for processes like expansion, compression, cycles, etc. They must also explain concepts related to the first and second laws of thermodynamics. Students are instructed to show working using appropriate diagrams and assume suitable data if necessary.
This document provides information about an examination for a power plant engineering course, including questions that assess knowledge of various power plant components, systems, and principles. It begins with general multiple choice and short answer questions about different power plant types. Longer questions then require explaining the working principles and components of specific power plant technologies like circulating fluidized bed combustors, supercritical boilers, diesel power plants, gas turbines, nuclear reactors, wind turbines, and solar power plants. The document concludes with numerical problems involving calculating costs and efficiencies for different power generation scenarios.
This document proposes replacing the conventional diesel generator and battery-based power system used by EthioTelecom with a hybrid system incorporating a fuel cell, microturbine, and DC/DC converter. It analyzes the technical specifications and performance of the system components, models the new system, and compares the costs, emissions, and reliability to the conventional system. The analysis finds that the hybrid system has lower operating costs, reduced emissions, higher reliability, and a payback period of around 6 years, making it a more sustainable option for telecom power in Ethiopia.
Fuel Cell System and Their Technologies A Reviewijtsrd
Renewable energy generation is quickly rising in the power sector industry and extensively used for two groups grid connected and standalone system. This paper gives the insights about fuel cell process and application of many power electronics systems. The fuel cell voltage drops bit by bit with increase in current because of losses related with fuel cell. It is difficult to control large rated fuel cell based power system without regulating tool. The issue associated with fuel based structural planning and the arrangements are extensively examined for all sorts of applications. In order to increase the reliability of fuel cell based power system, the combination of energy storage system and advanced research methods are focused in this paper. The control algorithms of power architecture for the couple of well-known applications are discussed. Rameez Hassan Pala "Fuel Cell System and Their Technologies: A Review" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-2 , February 2019, URL: https://www.ijtsrd.com/papers/ijtsrd20316.pdf
Paper URL: https://www.ijtsrd.com/engineering/electrical-engineering/20316/fuel-cell-system-and-their-technologies-a-review/rameez-hassan-pala
This document contains 16 questions and answers related to power systems. Some example questions include calculating diversity factors, load duration curves, power factor correction, and comparing tariff structures. The answers provide numerical calculations and formulas used to solve problems related to electrical power distribution, generation, and billing.
1) The document discusses energy management systems in the Turkish cement industry, specifically the requirements for companies to obtain ISO 50001 certification by 2015.
2) It provides background on energy use in Turkey, noting that energy intensity is high and energy demand is growing rapidly compared to population. Better energy management like ISO 50001 can increase efficiency.
3) The document then details an example energy management system implemented at a cement plant in Turkey, including establishing energy performance indicators and baselines to monitor usage and drive improvements.
This document summarizes an energy audit conducted on the electrical systems of a small-scale snack food processing plant in India. The audit found that motors used in operations like de-oiling, conveying, and flavoring were not optimally loaded. Illumination levels throughout the plant were also determined to be inefficient. Total annual electricity consumption for the plant was calculated to be 2,347 MWh. The audit suggested replacing oversized motors, improving motor load efficiency, and upgrading lighting systems to reduce annual electricity usage by over 650 MWh and lower operating costs. Conducting regular energy audits was recommended for identifying additional areas to cut energy waste and costs in food industry operations.
(1) The document provides a sample conventional paper with multiple questions covering topics in thermodynamics, heat transfer, fluid mechanics, refrigeration, and other mechanical engineering topics.
(2) Questions cover calculating efficiency of Carnot cycle, lumped capacity analysis, heat transfer of a steel sphere, normal shock relations, jet vane efficiency, specific speed of turbines, flow rates through orifice and venturi plates, pump performance, Joule-Thomson coefficient relations, refrigerant properties, thermostatic expansion valve sizing, flash evaporator entropy generation, heat exchanger sizing, hydrostatic force on a gate, diesel engine performance, psychrometric processes, and air conditioning load and ventilation calculations
Economic evaluation of hybrid wind-pv-diesel of grid power systemBader M. Al Utaibi
This document analyzes the optimal configuration of a hybrid power system for a village in Saudi Arabia consisting of wind, photovoltaic, and diesel generators. The existing system uses six 1,120 kW diesel generators. The document evaluates different hybrid system combinations using HOMER software. It finds that a system with 1,500 kW of solar PV panels, 15 100-kW wind turbines, and four 1,120 kW diesel generators results in the lowest cost of energy of $0.067/kWh while meeting the village's energy demand and reducing emissions by 65.9% compared to diesel only.
This document provides an overview of improving steam boiler operating efficiency. It discusses boiler classification and types, including fire-tube boilers, water-tube boilers, and biomass fuel boilers. It covers combustion principles, boiler efficiency calculations, factors affecting efficiency like excess air and heat losses, and methods to reduce losses like improving excess air control and heat recovery. The document also discusses instrumentation and controls, water treatment, performance monitoring, and environmental pollution aspects of boiler operation.
This document provides an overview of improving steam boiler operating efficiency. It discusses boiler types, fuels, combustion principles, boiler efficiency calculations, instrumentation and controls, heat recovery systems, and environmental pollution aspects related to boiler operation. The document is intended to educate operators, technicians, engineers and industrialists on basics of industrial boilers and efficiency improvement techniques. It covers topics such as boiler classification, combustion efficiency, reducing losses, efficiency calculations, instrumentation, controls, heat recovery options, and environmental impacts of boiler use.
Modeling, Application and Economic Feasibility Analysis of SOFC Combined Heat...juliomussane
Abstract- Abstract: Solid fuel cells combined heat and power is one of the most promising technologies for reducing energy consumption in stationary area (commercial building and residential environmental). This paper is aim to studies the model, applications and economic feasibility of an model of Solid Oxide Fuel Cell micro combined Heat and Power (SOFC mCHP) for single-family apartment in Wuhan area. A model of Solid Oxide Fuel Cell micro combined Heat and Power (SOFC mCHP) system is presented to estimate the energy required to meet the average of electricity and heating demand of a 120 m2 of single-family apartment in Wuhan area. Several simulation are conducted in Matlab-Simulink® environment in order to archive the aim of this paper. The model can be modified for any SOFC micro-CHP system. SOFC micro-CHP for stationary area has a higher potential to becoming cost-competitive in the worldwide. Based on the economic feasibility analyzes presented, the results indicated that it is feasible to introduce the SOFC micro-CHP system in Wuhan area from the economic viewpoint. However, fuel cell are still a non-mature technology aiming to reach the market in the coming years. Due to the constant development of fuel cell technology and recent commercial production, the available information about its performance in real applications is currently limited to date, and the cost information is not well established.
Index Terms- Model, application, economic analyze, SOFC, co-generation Heat and Power, Wuhan area.
This document contains instructions for a Thermal Engineering exam. It has 12 questions divided into two sections. The first section has 6 questions on topics like Orsat apparatus, coal combustion analysis, steam properties, Rankine cycle, boiler types and trials. The second section has questions on second law of thermodynamics, heat pumps, available energy, diesel cycle analysis, internal combustion engines, and their systems. Students are instructed to answer questions by section in separate answer books. Diagrams, tables, and calculators may be used. Data should be assumed if necessary.
The energy audit was conducted at a metal fabrication and casting company in Nigeria to identify areas of energy waste and potential savings. Data was collected on the company's electricity consumption over the past year, equipment power ratings, and lighting load. Analysis found the average monthly electricity consumption was around 8,500 kWh, with usage varying monthly. Machines were found to operate at low average loads of 62% and low power factors of 0.674 lagging. Recommendations will be provided to reduce power consumption through equipment replacements or process changes that save energy with payback periods less than equipment lifespans.
This document contains a test for an engineering thermodynamics exam with multiple choice and long answer questions. It covers topics like the first and second laws of thermodynamics, Carnot cycle efficiency, psychrometrics, gas properties, steam tables and Rankine cycle. The test has three parts with questions on thermodynamic processes, cycles, properties and applications to heating, cooling and power systems. Students are asked to analyze thermodynamic systems, calculate efficiencies, energy and mass transfers, exhaust velocities and more.
IRJET-Detailed Energy Audit in a Captive Cogeneration PlantIRJET Journal
D.Rajani Kant , B.Sudheer Prem Kumar, N.Ravi Kumar, R.Virendra,J.Suresh Babu " Detailed Energy Audit in a Captive Cogeneration Plant ", International Research Journal of Engineering and Technology (IRJET), Volume2,issue-01 April 2015.e-ISSN:2395-0056, p-ISSN:2395-0072. www.irjet.net
Abstract
The rate of exploitation of the energy resources has been expanding over time and resulted in reduction of fossil fuel reserves. Efficiency of all resources is crucial both in environmental and economic sense. Using energy inefficiently creates waste in all the world’s economies. It has environmental impacts with regional, local and global implications.The key object is to adopt energy management in every field in order to reduce the wastage of energy sources and cost effectiveness without affecting productivity and growth.
This document provides an overview and report on a vocational training project conducted by Tarun Kumar at the Kanti Thermal Power Station. It includes sections on acknowledging those who supported the training, an abstract describing the thermal power generation process, a table of contents, and sections covering topics like the power plant overview, generation process, boiler components, turbines, and control systems. The document aims to provide insight gained from Tarun Kumar's month-long industrial training placement at the thermal power facility.
This document is a project report submitted by Sushant Kumar summarizing his one month vocational training at the Kanti Bijlee Utpadan Nigam Limited power plant. The report provides an overview of the plant's operations including the processes of generating electricity from coal, the main boiler and turbine components, and control systems used. It also describes the milling system for pulverizing coal and the light up process for initially igniting the coal furnace.
This document outlines exam questions for an engineering thermodynamics course. It includes 12 questions covering various topics in thermodynamics. The questions require students to calculate things like work, heat transfer, efficiency, and more for processes like expansion, compression, cycles, etc. They must also explain concepts related to the first and second laws of thermodynamics. Students are instructed to show working using appropriate diagrams and assume suitable data if necessary.
This document provides information about an examination for a power plant engineering course, including questions that assess knowledge of various power plant components, systems, and principles. It begins with general multiple choice and short answer questions about different power plant types. Longer questions then require explaining the working principles and components of specific power plant technologies like circulating fluidized bed combustors, supercritical boilers, diesel power plants, gas turbines, nuclear reactors, wind turbines, and solar power plants. The document concludes with numerical problems involving calculating costs and efficiencies for different power generation scenarios.
This document proposes replacing the conventional diesel generator and battery-based power system used by EthioTelecom with a hybrid system incorporating a fuel cell, microturbine, and DC/DC converter. It analyzes the technical specifications and performance of the system components, models the new system, and compares the costs, emissions, and reliability to the conventional system. The analysis finds that the hybrid system has lower operating costs, reduced emissions, higher reliability, and a payback period of around 6 years, making it a more sustainable option for telecom power in Ethiopia.
Fuel Cell System and Their Technologies A Reviewijtsrd
Renewable energy generation is quickly rising in the power sector industry and extensively used for two groups grid connected and standalone system. This paper gives the insights about fuel cell process and application of many power electronics systems. The fuel cell voltage drops bit by bit with increase in current because of losses related with fuel cell. It is difficult to control large rated fuel cell based power system without regulating tool. The issue associated with fuel based structural planning and the arrangements are extensively examined for all sorts of applications. In order to increase the reliability of fuel cell based power system, the combination of energy storage system and advanced research methods are focused in this paper. The control algorithms of power architecture for the couple of well-known applications are discussed. Rameez Hassan Pala "Fuel Cell System and Their Technologies: A Review" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-2 , February 2019, URL: https://www.ijtsrd.com/papers/ijtsrd20316.pdf
Paper URL: https://www.ijtsrd.com/engineering/electrical-engineering/20316/fuel-cell-system-and-their-technologies-a-review/rameez-hassan-pala
This document contains 16 questions and answers related to power systems. Some example questions include calculating diversity factors, load duration curves, power factor correction, and comparing tariff structures. The answers provide numerical calculations and formulas used to solve problems related to electrical power distribution, generation, and billing.
1) The document discusses energy management systems in the Turkish cement industry, specifically the requirements for companies to obtain ISO 50001 certification by 2015.
2) It provides background on energy use in Turkey, noting that energy intensity is high and energy demand is growing rapidly compared to population. Better energy management like ISO 50001 can increase efficiency.
3) The document then details an example energy management system implemented at a cement plant in Turkey, including establishing energy performance indicators and baselines to monitor usage and drive improvements.
This document summarizes an energy audit conducted on the electrical systems of a small-scale snack food processing plant in India. The audit found that motors used in operations like de-oiling, conveying, and flavoring were not optimally loaded. Illumination levels throughout the plant were also determined to be inefficient. Total annual electricity consumption for the plant was calculated to be 2,347 MWh. The audit suggested replacing oversized motors, improving motor load efficiency, and upgrading lighting systems to reduce annual electricity usage by over 650 MWh and lower operating costs. Conducting regular energy audits was recommended for identifying additional areas to cut energy waste and costs in food industry operations.
(1) The document provides a sample conventional paper with multiple questions covering topics in thermodynamics, heat transfer, fluid mechanics, refrigeration, and other mechanical engineering topics.
(2) Questions cover calculating efficiency of Carnot cycle, lumped capacity analysis, heat transfer of a steel sphere, normal shock relations, jet vane efficiency, specific speed of turbines, flow rates through orifice and venturi plates, pump performance, Joule-Thomson coefficient relations, refrigerant properties, thermostatic expansion valve sizing, flash evaporator entropy generation, heat exchanger sizing, hydrostatic force on a gate, diesel engine performance, psychrometric processes, and air conditioning load and ventilation calculations
Economic evaluation of hybrid wind-pv-diesel of grid power systemBader M. Al Utaibi
This document analyzes the optimal configuration of a hybrid power system for a village in Saudi Arabia consisting of wind, photovoltaic, and diesel generators. The existing system uses six 1,120 kW diesel generators. The document evaluates different hybrid system combinations using HOMER software. It finds that a system with 1,500 kW of solar PV panels, 15 100-kW wind turbines, and four 1,120 kW diesel generators results in the lowest cost of energy of $0.067/kWh while meeting the village's energy demand and reducing emissions by 65.9% compared to diesel only.
This document provides an overview of improving steam boiler operating efficiency. It discusses boiler classification and types, including fire-tube boilers, water-tube boilers, and biomass fuel boilers. It covers combustion principles, boiler efficiency calculations, factors affecting efficiency like excess air and heat losses, and methods to reduce losses like improving excess air control and heat recovery. The document also discusses instrumentation and controls, water treatment, performance monitoring, and environmental pollution aspects of boiler operation.
This document provides an overview of improving steam boiler operating efficiency. It discusses boiler types, fuels, combustion principles, boiler efficiency calculations, instrumentation and controls, heat recovery systems, and environmental pollution aspects related to boiler operation. The document is intended to educate operators, technicians, engineers and industrialists on basics of industrial boilers and efficiency improvement techniques. It covers topics such as boiler classification, combustion efficiency, reducing losses, efficiency calculations, instrumentation, controls, heat recovery options, and environmental impacts of boiler use.
Modeling, Application and Economic Feasibility Analysis of SOFC Combined Heat...juliomussane
Abstract- Abstract: Solid fuel cells combined heat and power is one of the most promising technologies for reducing energy consumption in stationary area (commercial building and residential environmental). This paper is aim to studies the model, applications and economic feasibility of an model of Solid Oxide Fuel Cell micro combined Heat and Power (SOFC mCHP) for single-family apartment in Wuhan area. A model of Solid Oxide Fuel Cell micro combined Heat and Power (SOFC mCHP) system is presented to estimate the energy required to meet the average of electricity and heating demand of a 120 m2 of single-family apartment in Wuhan area. Several simulation are conducted in Matlab-Simulink® environment in order to archive the aim of this paper. The model can be modified for any SOFC micro-CHP system. SOFC micro-CHP for stationary area has a higher potential to becoming cost-competitive in the worldwide. Based on the economic feasibility analyzes presented, the results indicated that it is feasible to introduce the SOFC micro-CHP system in Wuhan area from the economic viewpoint. However, fuel cell are still a non-mature technology aiming to reach the market in the coming years. Due to the constant development of fuel cell technology and recent commercial production, the available information about its performance in real applications is currently limited to date, and the cost information is not well established.
Index Terms- Model, application, economic analyze, SOFC, co-generation Heat and Power, Wuhan area.
This document contains instructions for a Thermal Engineering exam. It has 12 questions divided into two sections. The first section has 6 questions on topics like Orsat apparatus, coal combustion analysis, steam properties, Rankine cycle, boiler types and trials. The second section has questions on second law of thermodynamics, heat pumps, available energy, diesel cycle analysis, internal combustion engines, and their systems. Students are instructed to answer questions by section in separate answer books. Diagrams, tables, and calculators may be used. Data should be assumed if necessary.
The energy audit was conducted at a metal fabrication and casting company in Nigeria to identify areas of energy waste and potential savings. Data was collected on the company's electricity consumption over the past year, equipment power ratings, and lighting load. Analysis found the average monthly electricity consumption was around 8,500 kWh, with usage varying monthly. Machines were found to operate at low average loads of 62% and low power factors of 0.674 lagging. Recommendations will be provided to reduce power consumption through equipment replacements or process changes that save energy with payback periods less than equipment lifespans.
1. UNIT-I
PART-A
1. Classify the types of the energy available on the earth?
2. Briefly mention about primary sources of energy?
3. What is renewable energy and list at least three renewable energy sources?
4. Name the five states in India, where coal production is concentrated.
5. Define Reserve to ‘Production Ratio’?
6. How do you define ‘Final Energy Consumption’?
7. What is greenhouse gas effect?
8. What are the key greenhouses gases driving global warming?
9. List down at least three effects of acid rain?
10. Differentiate between Energy Conservation and Energy Efficiency?
11. What is the basis for aim of Energy Security for any country?
12. List down the major sources of pollutants in Air?
13. List five forms of energy with examples.
14. What is energy intensity and what does it indicate?
15. List 5 positive forces of a force field analysis in support of the goal: “Reduce energy
consumption per unit production”.
PART-B
1. List the strategies for better energy security of the nation?
2. Mention some of the long-term energy strategies available for the better energy
secured nation?
3. How do an Industry, nation and globe would benefit from energy efficiency
programs?
4. How energy pricing is done in India?
5. Briefly describe the economic reforms in Coal, oil and natural gas and electricity
sectors.
6. Explain the difference between energy conservation and energy efficiency, and state
one example where energy costs are reduced but energy consumption goes up.
7. Discuss the difference between energy conservation and energy efficiency.
8. The following table shows the import bill of fossil fuels in million metric tons
(MMT) and its cost in Crores Rupees over the last eight years.
(i) Calculate the average annual percentage increase of fossil fuel imports.
(ii) Calculate the average annual percentage increase of the import bill
(iii) Calculate the average costs for the last eight years, in Rs. Per metric ton of
imported fossil fuels.
2. Import bill of fossil fuels
Year Quantity (MMT) Value (Rs.Crore)
1996-97 33.90 18,337
1997-98 34.49 15,872
1998-99 39.81 19,907
1999-00 57.80 40,028
2000-01 74.10 65,932
2001-02 84.90 80,116
2002-03 90.00 85,042
2003-04 95.00 93,159
9. What do you understand by energy security? Mention a few strategies to ensure
energy security.
10. Answer the following
a. Differentiate between renewable and nonrenewable energy with example.
b. How acid rain is formed? And what is its impact.
c. List two designated consumers as mentioned in EC Act 2001
d. Explain briefly about Clean Development Mechanism?
11. An agency is implementing energy efficiency measures in municipal water pumping
under ESCO route. The investment is Rs. 5 Crores. Present annual electricity bill is
Rs. 4 Crores. The expected savings are 20%. (Cost of electricity = Rs. 4/ kWh,
Annual maintenance cost -10% of investment) The expected CDM revenues would
be Rs. 50 Lakhs/ year. Calculate IRR for this project over a 10 year period, after
including the CDM benefit.
12. Write short notes on the following with reference to Energy Conservation Act 2001
a. Standards and labeling of equipment and appliance
b. Designated consumer
13. In a carbonation of a soft drink, the total quantity of Carbon dioxide required is the
equivalent of 4 volumes of gas to one volume of water at 0 oC and atmospheric
pressure. Calculate (I) the mass fraction and (II) the mole fraction of Carbon dioxide
in the drink. Ignore all components other than carbon dioxide and water. Take gas
constant = 0.08206
14. In a pumping system the motor efficiency is 90% and pump efficiency is 80%. The
pump discharge is throttled causing 20% loss; moreover 28% are lost through friction
in pipe fittings. The motor draws 34 kW. Calculate the net water power available at
the end of the piping system.
15. Assume that the annual per capita electricity consumption of India is 606 kWh and the
population is 1.078 Billion people.
(i) If the installed power capacity is 118,419 MW, calculate the average plant
load factor of the power mix at 606 kWh per capita consumption.
(ii) Calculate annual per capita consumption 30 years later if electricity
consumption in India goes up by 6% each year, and population growth is
1.2% annually.
3. (iii) How many years will it take to reach the per capita consumption of the USA
at 13,500 kWh under a business as usual scenario as in (ii)?
UNIT-II
Part A
1. Write a note on various forms of energy with examples.
2. What are the various grades of energy with an example
3. What are the characteristics of Direct current and Alternating current?
4. What is ‘Reactive power’ and ‘Active power’?
5. Differentiate between ‘contract demand’ and ‘maximum demand’?
6. Define the term ‘Load Factor’ with an example?
7. Explain the importance of TOD (time of the day) tariff?
8. A 250 W sodium vapour lamp is installed on a street. The supply voltage for a street
light is 230 V and it operates for around 12 hours in a day. Considering the current of
2 amps and power factor 0.85 calculate the energy consumption per day
9. A three phase induction 75 kW motor operates at 55 kW. The measured voltage is
415 V, current is 80 amps. Calculate the power factor of the motor?
10. Define ‘Law of conservation of matter’.
11. Differentiate the terms ‘specific heat’ and ‘heat capacity’?
12. What are the principles of energy management?
13. What do you mean by energy audit?
14. Give any four bench marking parameters followed in equipment/utility related in
Industries.
15. What parameters are measured with the following instruments?
a ) Pitot tube b) Stroboscope
c) Fyrit d) Lux Meter
PART-B
1. What is heat transfer? Briefly explain three primary modes of heat transfer.
2. What are the differences of AC current and DC current?
3. Describe the merits of using steam in industries.
4. Briefly explain with examples on fuel and energy substitution
5. Distinguish between ‘preliminary energy audit’ and ‘detailed energy audit’?
6. Give a typical energy audit reporting format.
7. List steps involved in ‘detailed energy audit’.
8. (i ) What is meant by fuel substitution?
(ii)A thermal fluid heater with Furnace Oil is replaced by a Coconut chip fired boiler
having the following details. Find out payback period based on the cost savings.
Avg. efficiency of old system (Fuel Oil fired boiler) = 80 %
Avg. efficiency of the new system (Coconut chip fired boiler) = 70%
GCV of FO = 10200 kcal / kg
GCV of Coconut chips = 4000 kcal / kg
Heat duty = 15 Lakhs kcal / hr
Annual operating hours = 7000 Hours
4. Investment of new system = Rs. 100 Lakhs
Cost of FO = Rs. 20 / liter
Cost of Coconut chips = Rs. 3000 / Ton
Sp. Gr. Of Fuel oil = 0.90
9. A plant is using 4 tons/day of coal to generate steam. The calorific value of the coal
is 4000 kcal/ kg. The cost of coal is Rs. 2,000/ton. The plant substitutes coal with rice
husks, as a boiler fuel, which has a calorific value of 3000 kcal/ kg and cost Rs.
700/ton. Calculate the annual cost savings at 300 days of operation, assuming that the
boiler efficiency decreases from 78% on coal to 72% on rice husks.
10. An energy manager or energy auditor is trying to establish the power factor of a 15
HP induction motor. The instrument to measure electric parameters displays the
three numbers 5 kW and 2 kVAr and PF = 92.8%. Do you fully agree with the
instrument display and its correctness?
11. A 15 kW, 415 V, 27 A, 4 pole, 50 Hz, 3 phase rated squirrel cage induction motor
has a full load efficiency and power factor of 90% and 0.86 respectively. An energy
auditor measures the following operating data of the motor.
Supply Voltage = 406 V
Current drawn = 22A
PF = 0.82
Find out the following at motor operating conditions:
a) Power input in kW
b) % motor loading
12. a) An energy auditor is trying to establish the operating power factor of a 15 HP/11.2
kW induction motor with full load efficiency of 90%.The motor is not connected
with any PF correction capacitors at motor terminals. The instrument to measure
input electric parameters to the motor displays the three numbers 5 kW, 2 kVAr and
0.928 PF. As an Energy Manger/Energy Auditor, do you fully agree with the
instrument display of Power Factor reading and its correctness?
b) Briefly mention about primary sources of energy?
13. Steam flow from a water tube boiler is measured by measuring the feed water tank
levels. In two hours there is a drop of 200 cm in level. The cross sectional area of the
tank is 9 m2. Assuming no blow down, calculate the steam flow rate. The enthalpy of
steam is 662 kCal/kg and feed water temperature is 80oC.
The calorific value of fuel used in the above boiler was measured by a continuous
flow calorimeter. The following data were obtained.
Mass of fuel : 2.25 kg
Inlet water temp : 30oC
Quantity of water : 360 liters
Outlet water temp : 84oC
% heat transferred to water in bomb calorimeter : 85 %
(a) Calculate the calorific value of the sample (kCal/kg).
(b) If the efficiency of the boiler is 85% find out the fuel firing rate (kg/hr).
14. (a) When the same quantity of heat is added to the same mass of Iron and copper
5. pieces, the temperature of Iron piece rises by 15 OC. Calculate the rise in
temperature of Copper piece, if the specific heat of Iron is 470 J/kgoC and that of
Copper is 390 J / kg oC?
(b) The input to a textile dryer is 60 kg of wet cloth per hour with 55% moisture. If
it is dried to 10% in a dryer, estimate the moisture removed per hour.
15. a) Differentiate between Dry Bulb Temperature & Wet Bulb Temperature.
b) Differentiate between Specific humidity and Relative humidity.
c) Differentiate between Gross Calorific Value (GCV) and Net Calorific Value.
UNIT-3
PART-A
1. Define specific power consumption with an example.
2. Why Sankey diagram is useful in energy balance calculations?
3. List any three guidelines for mass and energy balance.
4. How material and energy balance helps in energy conservation?
5. What way material and energy balance study is useful for a Top management?
6. What is the purpose of material and energy balance?
7. List any three energy loss components in chemical plant.
8. For complete combustion of 1 kg of a typical coal 12 kg of air is required. Calorific
value of coal is 4200 kCal/kg with ash content of 22%. What is the quantity (in kg)
flue gas generated by burning 5 kg coal?
9. What are the various levels of mass and energy balances?
10. Why evaluation of energy and mass balance is important?
11. Describe important features of a Sankey diagram.
12. In a heat exchanger steam is used to heat 40 kg/ hour of furnace oil from 30o C to 90o
C. The specific heat of furnace oil is 0.22 kcal/ kgo C. How much steam per hour is
needed? Latent heat of steam is 540 kcal/ kg.
13. A company consumes 1.3 x 105 kWh of electricity and 11.18 x 107 kCal of furnace
oil per month. Draw the pie chart of percentage share of fuels based on consumption
in kCal. (1 kWh = 860 kcal).
14. How much steam is required in a heat exchanger to heat 50 kg/ hour of a process
fluid from 40O C to 100O C. The specific heat of process fluid is 0.24 kCal/kg OC and
the latent heat of steam is 540 kCal/ kg.
15. In a steam heat exchanger, furnace oil at 40 kg/ hr. enters at 30oC and leaves at 90oC.
Specific heat of furnace oil is 0.22 kcal/ kgoC. If the latent heat of steam is 540 kcal/
kg, find out the amount of steam required to heat the oil.
PART-B
1. Draw a typical Sankey diagram of reheating furnace.
2. Discuss the procedure followed during energy and mass balance calculation.
3. A boiler is fed with soft water containing 120 mg/l dissolved solids. As per IS
standards the maximum dissolved solids in the boiler should not exceed 3500 mg/l
for boilers, operating up to 2 MPa. In order to maintain the specified level, a
6. continuous blow down system is adopted. Find the percentage of feed water which
will be blown down.
4. Production rate from a paper machine is 340 tonnes per day (TPD). Inlet and outlet
dryness to paper machine is 40% and 95% respectively. Evaporated moisture
temperature is 80 °C. To evaporate moisture, the steam is supplied at 3.5 kg/cm
2
(a).
2
(a) is 513 kCal/kg. Assume 24 hours/day operation.
Latent heat of steam at 3.5 kg/cm
i) Estimate the quantity of moisture to be evaporated
ii) Input steam quantity required for evaporation (per hour)
iii) Note: Consider enthalpy of evaporated moisture as 632 kcal/kg
5. In a particular drying operation, it is necessary to hold the moisture content of feed to
a calciner to 15% (W/W) to prevent lumping and sticking. This is accomplishing by
mixing the feed having 30% moisture (w/w) with recycle steam of dried material
having 3% moisture (w/w). The dryer operation is shown in fig below. What fraction
of the dried product must be recycled.
6. Prepare the energy balance of a Diesel Generator based on following details and draw
a Sankey diagram Calorific value of Diesel: 10,000 kCal per liter, Average energy
generated by DG Set: 4.07 kWh per litre. The efficiency of the alternator is 96%.
Losses:
a) 33% stack losses through flue gases
b) 24% coolant losses
c) balance radiation losses
7. a) Draw an energy balance for the DG set with following data. Diesel Generator
trial gives Set 3.5 kWh per Liter of diesel. The cooling water loss and exhaust flue
gas loss as percentage of fuel input are 28% and 32% respectively. Assume calorific
value of diesel as 10200 kCal/kg. The Specific gravity of Diesel is 0.85. Calculate
unaccounted loss as percentage of input energy.
b) Explain the following terms in heat transfer with examples.
i) Conduction ii) Convection
8. A drilling machine drawing continuously 5kW of input power and with an efficiency
of 50% , is used in drilling a bore in an aluminum block of 5kg of mass. How much
will be the rise in temperature of the block at the end of 100 seconds. Assume 20% of
the energy imparted to the block is lost to surroundings and the balance is absorbed
by the block in its uniform heating, and the specific heat of aluminum block = 900
J/kg/degree K
9. A textile dryer is found to consume 4.5 m3/hr of natural gas with a calorific value of
800 kJ/mole. If the throughput of the dryer is 60 kg of wet cloth per hour, drying it
from 55% moisture to 10% moisture, estimate the overall thermal efficiency of the
dryer taking into account the latent heat of evaporation only.( Note: Latent heat of
evaporation=2257 kJ/K, assume the natural gas to be at standard temperature and
pressure at which 1 mole occupies 22.4 liters)
10. 100 numbers of fused 60 Watt incandescent light bulbs (ILB) are replaced by same
numbers of 12 Watt CFL instead of new ILB. Calculate the following for 4000 hours
of operation per year.
a. The annual “kWh saved”
7. b. The annual “kVAh saved” if the power factor of the CFL is 0.6.
c. The annual reduction in electricity costs if Rs. 4 per kWh is the energy charge
and Rs. 250 per kVA per month is the demand charge.
d. The simple payback period if the ILB costs Rs. 10 and the CFL costs Rs. 100
(assume life of ILB and CFL as 1000 hours and 4000 hours respectively).
11. A 500 MW coal plant based on conventional pulverized fuel has a gross efficiency of
38%. The Gross calorific value of the coal used is 4000 kCal/kg with 40% total
carbon. A supercritical unit of 500 MW replaces the plant with a gross efficiency of
40% using the same characteristic coal. Calculate the following
a. Specific coal consumption after replacement
b. Amount of coal and carbon di-oxide saved during a year if the plant works for
8000 hours.
12. Steam flow from a water tube boiler is measured by measuring the feed water tank
levels. In two hours there is a drop of 200 cm in level. The cross sectional area of the
tank is 9 m2. Assuming no blow down, calculate the steam flow rate. The enthalpy of
steam is 662 kCal/kg and feed water temperature is 80oC.The calorific value of fuel
used in the above boiler was measured by a continuous flow calorimeter. The
following data were obtained.
Mass of fuel : 2.25 kg
Inlet water temp : 30oC
Quantity of water : 360 litres
Outlet water temp : 84oC
% heat transferred to water in bomb calorimeter : 85 %
(a) Calculate the calorific value of the sample (kCal/kg).
(b) If the efficiency of the boiler is 85% find out the fuel firing rate (kg/hr).
13. (a) When the same quantity of heat is added to the same mass of Iron and copper
pieces, the temperature of Iron piece rises by 15 OC. Calculate the rise in temperature
of Copper piece, if the specific heat of Iron is 470 J/kgoC and that of Copper is
390 J / kg oC?
(b) The input to a textile dryer is 60 kg of wet cloth per hour with 55% moisture. If it
is dried to 10% in a dryer, estimate the moisture removed per hour.
14. The feed water to a boiler enters the feed water tank at 32 oC where steam from the
same boiler is mixed into it. The mass of the steam mixed is 3% of steam output from
the boiler. The boiler operates with 2% continuous blow down. The enthalpy of the
steam is 593 kCal/kg and specific heat of water is 1 kCal/kgoC. Find out the
temperature of water after the feed water tank. Neglect heat loss if any.
15. a) Determine the amount of moisture on a wet and dry basis for a waste sludge that
has 30 kg of water and 20 kg of solids.
b) Milk is evaporated in a steam jacketed kettle at atmospheric pressure. 1000 kg
milk is charged per batch in the kettle. Milk is heated from 30°C to 100°C and boiled
continuously till 25% of the mass is evaporated. Determine the amount of dry
saturated steam at 1 kg/cm2 g required per batch excluding the heating of kettle.
Specific heat of milk – 0.9 kCal / kgOC
8. Latent heat of evaporation of water - 540 kCal /kg
Latent heat of steam at 1 kg/cm2 g - 525 kCal/ kg
UNIT-4
PART-A
1. Define the term ‘project’.
2. List various steps in project management.
3. List the external source of funds during financing stage in project management.
4. List the elements to be considered during technical design of a project management.
5. While screening the projects, list the criteria used to rank-order project opportunities.
6. What are the different types of contracts involved in project management system.
7. Briefly explain guaranteed saving performance contract.
8. Briefly explain shared saving performance contract.
9. List guidelines used during implementation stage of projects?
10. List the steps involved in CPM project planning?
11. What are the benefits of CPM.
12. Define briefly PERT
13. What are the different steps involved in PERT planning?
14. What are the benefits of PERT management..
15. List the project planning techniques used in project
PART-B
1. Briefly explain steps in project management.
2. What are the several types of contracts used in project management and explain in
brief?
3. How critical path can be identified in CPM?
4. What is CPM and list the steps in CPM project planning?
5. Explain and draw a typical Gantt chart
6. Construct a CPM diagram for the example below
Activity Precedent Time, weeks
A Start 3
B Start 4
C A 1
D A 2
E B 2
F C 3
Finish F,E,D -
7. (i)Construct a CPM diagram for the data given below
(ii)Identify the critical path. Also compute the earliest start, earliest finish, latest start
and latest finish of all activities
9. Activity Precedent Time, weeks
A Start 3
B A 4
C A 1
D C 3
E Start 2
F B 2
Finish D, E, F --
8. A company wants to invest Rs. 40 Lakhs in a project with an annual return of Rs. 8
Lakhs. The life of the project is 10 years.
1. Find out the IRR of the project.
2. If the interest on capital is 10%, is it worthwhile to invest in the project.
9. An investment of Rs 1.0 Lakh is made for a variable speed drive at the beginning of
the year, which is also the date of first operation. Savings expected over 4 years are
Rs. 30,000, Rs. 30,000, Rs. 40,000 and Rs. 45,000 respectively. Find out the Net
Present Value at the end of the 4th year, if the discount rate is 12%.
10. The details of activities for implementation of an energy efficient project is given
below:
Activity Preceding activity Duration (days)
A - 10
B A 9
C A 4
D C 7
E C 2
F E 3
G B, D 8
H D 4
I F,G,H 1
a) draw a PERT chart
b) find out the duration of the project
c) identify the critical path.
10. 11. Draw PERT Chart for the following for the task, duration and dependency given
below.
Find out:
a) Critical Path
b) expected project duration
Task
Predecessors
Tasks
(Dependencies)
Time (Weeks)
A - 3
B - 5
C - 7
D A 8
E B 5
F C 5
G E 4
H F 5
I D 6
J G - H 4
12. The details of activities for a pump replacement project is given below:
a) draw a PERT chart
b) find out the duration of the project
c) identify the critical path.
Activity Immediate
Predecessors
Time
(days)
A - 1
B A 2
C B 4
D C 6
E C 3
F C 5
G D, E, F 8
H G 7
11. 13. Construct a PERT Diagram for the following project and find out the critical
path
Activity Duration in Days Precedent
A 2 Start
B 3 A
C 5 A
D 4 B
E 6 B
F 5 C
G 7 D
H 3 E
I 1 F, G, H
i) What is the critical path?
ii) What is the total duration required to complete the project?
iii) What is the available slack period in days for activity C & E?
iv) If duration of activity G is reduced by 2 days by crashing, what is the new
critical path and duration?
12. 14. (a) Construct a PERT Chart diagram for the data given below
(b) Identify the critical path and compute the project duration. Also compute the
earliest finish, latest start & latest finish of all activities
Activity Precedent Time, weeks
A 4
B A 3
C A 2
D B 5
E B 3
F C,D 4
G E,F 3
15. The following are the cash flows for a simple insulation up gradation project.
YEAR 0 1 2 3 4
Cash flow -18,000 -5,000 10,000 10,000 10,000
a) Calculate the NPV if the cost of capital or discount rate is 8%
b) Calculate the IRR
UNIT-5
PART-A
1. Define ‘Energy Monitoring and targeting’?
2. Briefly list Benefits that arise from an effective M&T system
3. List down the essential elements of monitoring and targeting System?
4. What are the steps involved in CUSUM analysis?
5. What is the significance of calculating specific energy consumption?
6. What is advantage of presenting plant data in graphical form?
7. Why CUSUM technique is most useful?
8. What do you understand by CUSUM?
9. Name the plant utility systems that require Monitoring and Targeting?
10. What is the primary aim of “energy monitoring’ in the plant?
11. What are the advantages of adding production data to the specific energy
consumption chart?
12. How do we better envisage the plain energy data of a plant entered in spread sheet
form?
13. How the savings can be achieved with the help of Monitoring & targeting?
13. 14. Write a formula relating production and energy consumption.
15. List at least 5 steps involved in CUSUM analysis.
PART-B
1. Use CUSUM technique and calculate energy savings for 6 months period of 2003.
For calculating total energy savings, average production can be taken as
4000MT/Month. Refer data given in table below.
2. Write Ten key steps in “ Monitoring and targeting” that you will undertake as an
energy manager in your plant .
3. What are the various ways to relate the plant’s energy consumption with
production?
4. Briefly explain the essential elements of monitoring and targeting system?
5. Use CUSUM technique to develop a table and to calculate energy savings for 8
months period. For calculating total energy saving, average production can be
taken as 7,500 MT per month. Refer to field data given in the table below.
Month Actual SEC,
kWh/MT
Predicted SEC,
kWh/MT
May 1311 1335
June 1308 1335
July 1368 1335
Aug 1334 1335
Sept 1338 1335
Oct 1351 1335
Nov 1322 1335
Dec 1320 1335
6. Energy saving measures was implemented in a process plant prior to Jan-2008.
Use CUSUM technique and calculate energy savings for 6 months period of
2008.The company produced consistently 3000 T/month in each of the six months.
Refer the graph given in table below.The predicted Specific energy consumption
for 3000 MT production is 260 kWh/MT.It may be noted that retrofits were not
functioning during March & May 2008.
14. Actual Specific Energy Consumption Profile
236
280
235
290
239
240
300
290
280
270
260
250
240
230
220
210
200
Jan Feb Mar Apr May Jun
Month
Specific Energy
Consumption,kWh/MT
7. Use CUSUM technique to develop a table and to calculate energy savings for a 6
months period. For calculating total energy saving, average production can be taken as
4000 MT per month. Refer to field data given in table below.
Month Actual SEC,
kWh/MT
Predicted SEC,
kWh/MT
Jan 252 265
Feb 238 265
Mar 287 300
Apr 287 265
May 359 310
Jun 276 265
8. A foundry has an induction furnace of 5 TPH with a specific energy consumption of
620 kWh / tonne of liquid metal. The yield of the foundry castings is 60%. Further
the castings are heat treated in an oil fired furnace which consumes 75 kgs of oil /
tonne of castings. Find out the energy consumption per tonne of finished product in
terms of oil equivalent. (GCV of oil = 10,000 kCal / kg & 1 kWh = 860 kCal)
15. 9. A 100 tonnes per day (tpd) capacity Chloralakali plant in the year 2005-06
(Reference year) produced 30,000 tonnes per annum (TPA) of caustic soda with an
annual energy consumption of 90 million kWh and during the year 2007-08, the annual
production was 25,000 TPA, with an annual energy consumption of 80 million kWh.
Calculate the Plant Energy Performance.
10. Briefly explain the rationale for monitoring, targeting and reporting.
11. What is the difference between monitoring and targeting?
12. Explain how a CUSUM chart is drawn with an example.
13. What are the steps for cusum analysis?
14. Explain about the energy consumption and production.
15. Explain briefly about data information and analysis.