A description of how my optimization of carbon dioxide and propane mixture ratio as a working fluid helps reduce operating pressure by 33%, levelized cost of electricity (LCOE) by 6.36% and total power output from a diesel powered plant by 8% through waste heat recovery.
OPTIMIZATION OF AN ORGANIC RANKINE CYCLE IN ENERGY RECOVERY FROM EXHAUST GASE...IAEME Publication
This paper describes thermal analysis and optimization of an organic Rankine cycle (ORC) integrated with a power generating stationary diesel engine. A simple ORC, with a regenerator, is considered here as a bottoming cycle for producing additional power by recovering waste energy
from the exhaust gases of the engine. Taking evaporation pressure and condensation temperature as two decision variables, a genetic algorithm is used for simultaneously maximizing three objective functions - exergy efficiency, thermal efficiency, and specific network.
Energy and Exergy Analysis of a Cogeneration Cycle, Driven by Ocean Thermal E...theijes
Ocean Thermal Energy Conversion (OTEC) is a technology by which thermal energy from the ocean is harnessed and converted into electricity. It is one of the renewable energy technologies being researched into, as part of solutions to the challenge of global warming and climate change. A major setback of this technology, however, is that it has a very low cycle efficiency. In this work a cogeneration cycle is proposed which is driven by the temperature difference between the warm surface layer and the cold bottom layer of the ocean. The work is aimed at improving the overall cycle efficiency of OTEC systems by reducing the depth at which cold water is captured from the ocean. To achieve this, the cycle employs a binary mixture of ammonia and water as the working fluid and uses the mechanism of absorption to obtain the liquid phase of the working fluid after expansion through the turbine. The effects of varying cycle parameters such as the depth of cold-water capture, heat source temperature and mixture composition of the working fluid were investigated. With a basic solution mixture concentration of 0.40 kg/kg NH3/H2O, and under operating conditions of 30oC as the warm surface water temperature and a cold water temperature of 10oC, captured at a depth of 600m the proposed cycle produced a net power output of 42 kW, and a refrigeration capacity of 370 kW. The thermal efficiency computed was 1.94% and the exergy efficiency was 13.78%, both higher than the case where the depth of cold water capture was 1000m.
A OVERVIEW OF THE RANKIN CYCLE-BASED HEAT EXCHANGER USED IN INTERNAL COMBUSTI...IAEME Publication
The majority of the heat produced by automobiles, primarily by diesel engines, is squandered in various ways. If this waste heat is collected, it can be applied in a variety of other ways. Recently, increased emphasis has been placed on the global issue of rapid economic growth, a relative energy scarcity, internal combustion engine exhaust waste heat, and environmental degradation. The remaining heat is released into the environment through exhaust gases and engine cooling systems, leading to an increase in entropy and significant environmental pollution, so it is necessary to convert waste heat into useful work. Of the total heat supplied to the engine in the form of fuel, approximately 30 to 40% is converted into useful mechanical work. At 4000 RPM, the exhaust gas temperature is at its highest. So a recovery system is created for a constant RPM of 4000. A shell and tube heat exchanger and a uniflow steam engine connected to the main engine make up the recovery system. By reducing the frictional power at the main engine's power stroke and idle stroke, the linked steam engine increases the efficiency of the main engine. Due to the additional recovery system, the system's initial cost is significant. But over time, the system turns out to be profitable.
OPTIMIZATION OF AN ORGANIC RANKINE CYCLE IN ENERGY RECOVERY FROM EXHAUST GASE...IAEME Publication
This paper describes thermal analysis and optimization of an organic Rankine cycle (ORC) integrated with a power generating stationary diesel engine. A simple ORC, with a regenerator, is considered here as a bottoming cycle for producing additional power by recovering waste energy
from the exhaust gases of the engine. Taking evaporation pressure and condensation temperature as two decision variables, a genetic algorithm is used for simultaneously maximizing three objective functions - exergy efficiency, thermal efficiency, and specific network.
Energy and Exergy Analysis of a Cogeneration Cycle, Driven by Ocean Thermal E...theijes
Ocean Thermal Energy Conversion (OTEC) is a technology by which thermal energy from the ocean is harnessed and converted into electricity. It is one of the renewable energy technologies being researched into, as part of solutions to the challenge of global warming and climate change. A major setback of this technology, however, is that it has a very low cycle efficiency. In this work a cogeneration cycle is proposed which is driven by the temperature difference between the warm surface layer and the cold bottom layer of the ocean. The work is aimed at improving the overall cycle efficiency of OTEC systems by reducing the depth at which cold water is captured from the ocean. To achieve this, the cycle employs a binary mixture of ammonia and water as the working fluid and uses the mechanism of absorption to obtain the liquid phase of the working fluid after expansion through the turbine. The effects of varying cycle parameters such as the depth of cold-water capture, heat source temperature and mixture composition of the working fluid were investigated. With a basic solution mixture concentration of 0.40 kg/kg NH3/H2O, and under operating conditions of 30oC as the warm surface water temperature and a cold water temperature of 10oC, captured at a depth of 600m the proposed cycle produced a net power output of 42 kW, and a refrigeration capacity of 370 kW. The thermal efficiency computed was 1.94% and the exergy efficiency was 13.78%, both higher than the case where the depth of cold water capture was 1000m.
A OVERVIEW OF THE RANKIN CYCLE-BASED HEAT EXCHANGER USED IN INTERNAL COMBUSTI...IAEME Publication
The majority of the heat produced by automobiles, primarily by diesel engines, is squandered in various ways. If this waste heat is collected, it can be applied in a variety of other ways. Recently, increased emphasis has been placed on the global issue of rapid economic growth, a relative energy scarcity, internal combustion engine exhaust waste heat, and environmental degradation. The remaining heat is released into the environment through exhaust gases and engine cooling systems, leading to an increase in entropy and significant environmental pollution, so it is necessary to convert waste heat into useful work. Of the total heat supplied to the engine in the form of fuel, approximately 30 to 40% is converted into useful mechanical work. At 4000 RPM, the exhaust gas temperature is at its highest. So a recovery system is created for a constant RPM of 4000. A shell and tube heat exchanger and a uniflow steam engine connected to the main engine make up the recovery system. By reducing the frictional power at the main engine's power stroke and idle stroke, the linked steam engine increases the efficiency of the main engine. Due to the additional recovery system, the system's initial cost is significant. But over time, the system turns out to be profitable.
SIMULATION, EXERGY EFFICIENCY AND ENVIRONMENTAL IMPACT OF ELECTRICITY OF A 62...Zin Eddine Dadach
The first part of this study is to simulate a Natural Gas Combined Cycle (NGCC) for a production of about 620 MW of electricity using the commercial software Aspen Hysys V9.0 and the Soave-Redlich-Kwong (SRK) equation of state. The aim of the second part is to use exergy-based analyses in order to calculate its exergy efficiency and evaluate its environmental impact under standard conditions.
Now a day’s power generation is most important for
every country. This power is generated by some thermal
cycles. But single cycle cannot be attain complete power
requirements and its efficiency also very low so that to fulfill
this requirements to combine two or more cycles in a single
power plant then we can increase the efficiency of the power
plant. Its increased efficiency is more than that of if the plant
operated on single cycle. In which we are using two different
cycles and these two cycles are operated by means of different
working mediums. These type of power plants we can called
them like combined cycle power plants. In combined cycle
power plants above cycle is known as topping cycle and below
cycle is known as bottoming cycle. The above cycle generally
brayton cycle which uses air as a working medium. When the
power generation was completed the exhaust gas will passes
in to the waste heat recovery boiler. Another cycle also
involved in bottoming cycle. This cycle works on the basis on
rankine cycle. In which steam is used as working medium.
The main component in bottoming cycle is waste heat
recovery boiler. It will receive exhaust heat from the gas
turbine and converts water in to steam. The steam used for
generating power by expansion on steam turbine. Combined
cycle power plants are mostly used in commercial power
plants.
In this paper we are analyzing one practical
combined cycle power plant. In practical conditions due to
some losses it can not be generates complete power. So that
we are invistigated why it is not give that much of power and
the effect of various operating parameters such as maximum
temperature and pressure of rankine cycle, gas turbine inlet
temperature and pressure ratio of Brayton cycle on the net
output work and thermal efficiency of the combine cycle
power plant.
The outcome of this work can be utilized in order to
facilitate the design of a combined cycle with higher efficiency
and output work. Mathematical calculations and simple
graphs in ms excel, and auto cad has been carried out to
study the effects and influences of the above mentioned
parameters on the efficiency and work output.
Waste heat recovery from hot gasses in cement industryhannyboi123
This final year project focuses on direct heat recovery in which heat from various units such as the Kiln, Calciner and Clinker Cooler is recovered. For this study, a process model is developed using Aspen HYSYS simulation software, and the model is confirmed against acquired data from the industry followed by calculation of equal fuel saved. The heat recovered from all these units is used to produce superheated steam to run a steam turbine generator which in turn provides electricity to the cement plant. This is an implementation of the Steam Rankine Cycle. This project not only benefits the industry in terms of cost-saving on fuel but also reduces the quantity of toxic hot waste gases. The number of carbon emissions would have increased drastically if coal would have been used instead. The steam turbine was able to generate 14 MW. If this is successfully implemented in all other major industries, a significant amount of non-renewable reserves can be saved for future generations.
Effect of Compression Ratio on Performance of Combined Cycle Gas Turbineijsrd.com
It is known the performance of a gas turbine (GT) has strong dependence of climate conditions. A suitable solution to minimize this negative effect is to raise inlet turbine temperature and reduce temperature of inlet air to GT compressor. Combined cycles gas turbines (CCGT) are a lot used to acquire a high-efficiency power plant. Increases the peak compression ratio has been proposed to improve the combined-cycle gas-turbine performance. The code of the performance model for CCGT power plant was developed utilizing the MATLAB software. The simulating results show that the overall efficiency increases with the increase of the peak compression ratio. The total power output increases with the increase of the peak compression ratio. The peak overall efficiency occurs at the higher compression ratio with low ambient temperature and higher turbine inlet temperature. The overall thermal efficiencies for CCGT are higher compared to gas-turbine plants.
Iris Publishers- Journal of Engineering Sciences | Performance and Design Opt...IrisPublishers
The aim of this work is to optimize the design and performance of solar powered γ Stirling engine based on genetic algorithm (GA). A second-order mathematical model which includes thermal losses coupled with genetic algorithm GA has been developed and used to find the best values for different design variables. The physical geometry of the γ Stirling engine has been used as an objective variable in the genetic algorithm GA to determine the optimal parameters. The design geometry of the heat exchanger was considered to be the objective variable. The heater slots height, heater effective length, cooler slots height, cooler effective length, re-generator foil unrolled length and re-generator effective length are assumed to be the objective variables. Also, three different types of working fluids have been used in the model simulation to investigate the effect of the different working fluid on the engine performance. The comparison between the results obtained from the simulation by using the original parameters and the results from the optimized parameters when the engine was powered by solar energy; the higher temperature was 923 K applied to the working fluid when the air, helium, and hydrogen were used as working fluid. The engine power increases from 140.58 watts to 228.54 watts, and it is enhanced by approximately 50%, when the heating temperature is 923 K and the air is used as working fluid. The result showed that the working temperature is one of the most important parameters; because the output power increases by increasing of the hot side temperature.
Scope of Improving Energy Utilization in Coal Based Co-Generation on Thermal ...IJMER
International Journal of Modern Engineering Research (IJMER) is Peer reviewed, online Journal. It serves as an international archival forum of scholarly research related to engineering and science education.
Investigating The Performance of A Steam Power PlantIJMERJOURNAL
ABSTRACT: The performance analysis of Shobra El-Khima power plant in Cairo, Egypt is presented based on energy and exergy analysis to determine the causes , the sites with high exergy destruction , losses and the possibilities of improving the plant performance. The performance of the plant was evaluated at different loads (Full, 75% and, 50 %). The calculated thermal efficiency based on the heat added to the steam was found to be 41.9 %, 41.7 %, 43.9% , while the exergetic efficiency of the power cycle was found to be 44.8%, 45.5% and 48.8% at max, 75% and, 50 % load respectively. The condenser was found to have the largest energy losses where (54.3%, 55.1% and 56.3% at max, 75% and, 50 % load respectively) of the added energy to the steam is lost to the environment. The maximum exergy destruction was found to be in the turbine where the percentage of the exergy destruction was found to be (42%, 59% and 46.1% at max, 75% and, 50 % load respectively). The pump was found to have the minimum exergy destruction. It was also found that the exergy destruction in feed water heaters and in the condenser together represents the maximum exergy destruction in the plant (about 52%). This means that the irreversibilities in the heat transfer devices in the plant have a significant role on the exergy destruction. So, it is thought that the improvement in the power plant will be limited due to the heat transfer devices.
GENERATION OF POWER THROUGH HYDROGEN – OXYGEN FUEL CELLSinventy
Research Inventy : International Journal of Engineering and Science is published by the group of young academic and industrial researchers with 12 Issues per year. It is an online as well as print version open access journal that provides rapid publication (monthly) of articles in all areas of the subject such as: civil, mechanical, chemical, electronic and computer engineering as well as production and information technology. The Journal welcomes the submission of manuscripts that meet the general criteria of significance and scientific excellence. Papers will be published by rapid process within 20 days after acceptance and peer review process takes only 7 days. All articles published in Research Inventy will be peer-reviewed.
NO1 Uk best vashikaran specialist in delhi vashikaran baba near me online vas...Amil Baba Dawood bangali
Contact with Dawood Bhai Just call on +92322-6382012 and we'll help you. We'll solve all your problems within 12 to 24 hours and with 101% guarantee and with astrology systematic. If you want to take any personal or professional advice then also you can call us on +92322-6382012 , ONLINE LOVE PROBLEM & Other all types of Daily Life Problem's.Then CALL or WHATSAPP us on +92322-6382012 and Get all these problems solutions here by Amil Baba DAWOOD BANGALI
#vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore#blackmagicformarriage #aamilbaba #kalajadu #kalailam #taweez #wazifaexpert #jadumantar #vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore #blackmagicforlove #blackmagicformarriage #aamilbaba #kalajadu #kalailam #taweez #wazifaexpert #jadumantar #vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore #Amilbabainuk #amilbabainspain #amilbabaindubai #Amilbabainnorway #amilbabainkrachi #amilbabainlahore #amilbabaingujranwalan #amilbabainislamabad
Water scarcity is the lack of fresh water resources to meet the standard water demand. There are two type of water scarcity. One is physical. The other is economic water scarcity.
SIMULATION, EXERGY EFFICIENCY AND ENVIRONMENTAL IMPACT OF ELECTRICITY OF A 62...Zin Eddine Dadach
The first part of this study is to simulate a Natural Gas Combined Cycle (NGCC) for a production of about 620 MW of electricity using the commercial software Aspen Hysys V9.0 and the Soave-Redlich-Kwong (SRK) equation of state. The aim of the second part is to use exergy-based analyses in order to calculate its exergy efficiency and evaluate its environmental impact under standard conditions.
Now a day’s power generation is most important for
every country. This power is generated by some thermal
cycles. But single cycle cannot be attain complete power
requirements and its efficiency also very low so that to fulfill
this requirements to combine two or more cycles in a single
power plant then we can increase the efficiency of the power
plant. Its increased efficiency is more than that of if the plant
operated on single cycle. In which we are using two different
cycles and these two cycles are operated by means of different
working mediums. These type of power plants we can called
them like combined cycle power plants. In combined cycle
power plants above cycle is known as topping cycle and below
cycle is known as bottoming cycle. The above cycle generally
brayton cycle which uses air as a working medium. When the
power generation was completed the exhaust gas will passes
in to the waste heat recovery boiler. Another cycle also
involved in bottoming cycle. This cycle works on the basis on
rankine cycle. In which steam is used as working medium.
The main component in bottoming cycle is waste heat
recovery boiler. It will receive exhaust heat from the gas
turbine and converts water in to steam. The steam used for
generating power by expansion on steam turbine. Combined
cycle power plants are mostly used in commercial power
plants.
In this paper we are analyzing one practical
combined cycle power plant. In practical conditions due to
some losses it can not be generates complete power. So that
we are invistigated why it is not give that much of power and
the effect of various operating parameters such as maximum
temperature and pressure of rankine cycle, gas turbine inlet
temperature and pressure ratio of Brayton cycle on the net
output work and thermal efficiency of the combine cycle
power plant.
The outcome of this work can be utilized in order to
facilitate the design of a combined cycle with higher efficiency
and output work. Mathematical calculations and simple
graphs in ms excel, and auto cad has been carried out to
study the effects and influences of the above mentioned
parameters on the efficiency and work output.
Waste heat recovery from hot gasses in cement industryhannyboi123
This final year project focuses on direct heat recovery in which heat from various units such as the Kiln, Calciner and Clinker Cooler is recovered. For this study, a process model is developed using Aspen HYSYS simulation software, and the model is confirmed against acquired data from the industry followed by calculation of equal fuel saved. The heat recovered from all these units is used to produce superheated steam to run a steam turbine generator which in turn provides electricity to the cement plant. This is an implementation of the Steam Rankine Cycle. This project not only benefits the industry in terms of cost-saving on fuel but also reduces the quantity of toxic hot waste gases. The number of carbon emissions would have increased drastically if coal would have been used instead. The steam turbine was able to generate 14 MW. If this is successfully implemented in all other major industries, a significant amount of non-renewable reserves can be saved for future generations.
Effect of Compression Ratio on Performance of Combined Cycle Gas Turbineijsrd.com
It is known the performance of a gas turbine (GT) has strong dependence of climate conditions. A suitable solution to minimize this negative effect is to raise inlet turbine temperature and reduce temperature of inlet air to GT compressor. Combined cycles gas turbines (CCGT) are a lot used to acquire a high-efficiency power plant. Increases the peak compression ratio has been proposed to improve the combined-cycle gas-turbine performance. The code of the performance model for CCGT power plant was developed utilizing the MATLAB software. The simulating results show that the overall efficiency increases with the increase of the peak compression ratio. The total power output increases with the increase of the peak compression ratio. The peak overall efficiency occurs at the higher compression ratio with low ambient temperature and higher turbine inlet temperature. The overall thermal efficiencies for CCGT are higher compared to gas-turbine plants.
Iris Publishers- Journal of Engineering Sciences | Performance and Design Opt...IrisPublishers
The aim of this work is to optimize the design and performance of solar powered γ Stirling engine based on genetic algorithm (GA). A second-order mathematical model which includes thermal losses coupled with genetic algorithm GA has been developed and used to find the best values for different design variables. The physical geometry of the γ Stirling engine has been used as an objective variable in the genetic algorithm GA to determine the optimal parameters. The design geometry of the heat exchanger was considered to be the objective variable. The heater slots height, heater effective length, cooler slots height, cooler effective length, re-generator foil unrolled length and re-generator effective length are assumed to be the objective variables. Also, three different types of working fluids have been used in the model simulation to investigate the effect of the different working fluid on the engine performance. The comparison between the results obtained from the simulation by using the original parameters and the results from the optimized parameters when the engine was powered by solar energy; the higher temperature was 923 K applied to the working fluid when the air, helium, and hydrogen were used as working fluid. The engine power increases from 140.58 watts to 228.54 watts, and it is enhanced by approximately 50%, when the heating temperature is 923 K and the air is used as working fluid. The result showed that the working temperature is one of the most important parameters; because the output power increases by increasing of the hot side temperature.
Scope of Improving Energy Utilization in Coal Based Co-Generation on Thermal ...IJMER
International Journal of Modern Engineering Research (IJMER) is Peer reviewed, online Journal. It serves as an international archival forum of scholarly research related to engineering and science education.
Investigating The Performance of A Steam Power PlantIJMERJOURNAL
ABSTRACT: The performance analysis of Shobra El-Khima power plant in Cairo, Egypt is presented based on energy and exergy analysis to determine the causes , the sites with high exergy destruction , losses and the possibilities of improving the plant performance. The performance of the plant was evaluated at different loads (Full, 75% and, 50 %). The calculated thermal efficiency based on the heat added to the steam was found to be 41.9 %, 41.7 %, 43.9% , while the exergetic efficiency of the power cycle was found to be 44.8%, 45.5% and 48.8% at max, 75% and, 50 % load respectively. The condenser was found to have the largest energy losses where (54.3%, 55.1% and 56.3% at max, 75% and, 50 % load respectively) of the added energy to the steam is lost to the environment. The maximum exergy destruction was found to be in the turbine where the percentage of the exergy destruction was found to be (42%, 59% and 46.1% at max, 75% and, 50 % load respectively). The pump was found to have the minimum exergy destruction. It was also found that the exergy destruction in feed water heaters and in the condenser together represents the maximum exergy destruction in the plant (about 52%). This means that the irreversibilities in the heat transfer devices in the plant have a significant role on the exergy destruction. So, it is thought that the improvement in the power plant will be limited due to the heat transfer devices.
GENERATION OF POWER THROUGH HYDROGEN – OXYGEN FUEL CELLSinventy
Research Inventy : International Journal of Engineering and Science is published by the group of young academic and industrial researchers with 12 Issues per year. It is an online as well as print version open access journal that provides rapid publication (monthly) of articles in all areas of the subject such as: civil, mechanical, chemical, electronic and computer engineering as well as production and information technology. The Journal welcomes the submission of manuscripts that meet the general criteria of significance and scientific excellence. Papers will be published by rapid process within 20 days after acceptance and peer review process takes only 7 days. All articles published in Research Inventy will be peer-reviewed.
NO1 Uk best vashikaran specialist in delhi vashikaran baba near me online vas...Amil Baba Dawood bangali
Contact with Dawood Bhai Just call on +92322-6382012 and we'll help you. We'll solve all your problems within 12 to 24 hours and with 101% guarantee and with astrology systematic. If you want to take any personal or professional advice then also you can call us on +92322-6382012 , ONLINE LOVE PROBLEM & Other all types of Daily Life Problem's.Then CALL or WHATSAPP us on +92322-6382012 and Get all these problems solutions here by Amil Baba DAWOOD BANGALI
#vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore#blackmagicformarriage #aamilbaba #kalajadu #kalailam #taweez #wazifaexpert #jadumantar #vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore #blackmagicforlove #blackmagicformarriage #aamilbaba #kalajadu #kalailam #taweez #wazifaexpert #jadumantar #vashikaranspecialist #astrologer #palmistry #amliyaat #taweez #manpasandshadi #horoscope #spiritual #lovelife #lovespell #marriagespell#aamilbabainpakistan #amilbabainkarachi #powerfullblackmagicspell #kalajadumantarspecialist #realamilbaba #AmilbabainPakistan #astrologerincanada #astrologerindubai #lovespellsmaster #kalajaduspecialist #lovespellsthatwork #aamilbabainlahore #Amilbabainuk #amilbabainspain #amilbabaindubai #Amilbabainnorway #amilbabainkrachi #amilbabainlahore #amilbabaingujranwalan #amilbabainislamabad
Water scarcity is the lack of fresh water resources to meet the standard water demand. There are two type of water scarcity. One is physical. The other is economic water scarcity.
Cosmetic shop management system project report.pdfKamal Acharya
Buying new cosmetic products is difficult. It can even be scary for those who have sensitive skin and are prone to skin trouble. The information needed to alleviate this problem is on the back of each product, but it's thought to interpret those ingredient lists unless you have a background in chemistry.
Instead of buying and hoping for the best, we can use data science to help us predict which products may be good fits for us. It includes various function programs to do the above mentioned tasks.
Data file handling has been effectively used in the program.
The automated cosmetic shop management system should deal with the automation of general workflow and administration process of the shop. The main processes of the system focus on customer's request where the system is able to search the most appropriate products and deliver it to the customers. It should help the employees to quickly identify the list of cosmetic product that have reached the minimum quantity and also keep a track of expired date for each cosmetic product. It should help the employees to find the rack number in which the product is placed.It is also Faster and more efficient way.
Explore the innovative world of trenchless pipe repair with our comprehensive guide, "The Benefits and Techniques of Trenchless Pipe Repair." This document delves into the modern methods of repairing underground pipes without the need for extensive excavation, highlighting the numerous advantages and the latest techniques used in the industry.
Learn about the cost savings, reduced environmental impact, and minimal disruption associated with trenchless technology. Discover detailed explanations of popular techniques such as pipe bursting, cured-in-place pipe (CIPP) lining, and directional drilling. Understand how these methods can be applied to various types of infrastructure, from residential plumbing to large-scale municipal systems.
Ideal for homeowners, contractors, engineers, and anyone interested in modern plumbing solutions, this guide provides valuable insights into why trenchless pipe repair is becoming the preferred choice for pipe rehabilitation. Stay informed about the latest advancements and best practices in the field.
Final project report on grocery store management system..pdfKamal Acharya
In today’s fast-changing business environment, it’s extremely important to be able to respond to client needs in the most effective and timely manner. If your customers wish to see your business online and have instant access to your products or services.
Online Grocery Store is an e-commerce website, which retails various grocery products. This project allows viewing various products available enables registered users to purchase desired products instantly using Paytm, UPI payment processor (Instant Pay) and also can place order by using Cash on Delivery (Pay Later) option. This project provides an easy access to Administrators and Managers to view orders placed using Pay Later and Instant Pay options.
In order to develop an e-commerce website, a number of Technologies must be studied and understood. These include multi-tiered architecture, server and client-side scripting techniques, implementation technologies, programming language (such as PHP, HTML, CSS, JavaScript) and MySQL relational databases. This is a project with the objective to develop a basic website where a consumer is provided with a shopping cart website and also to know about the technologies used to develop such a website.
This document will discuss each of the underlying technologies to create and implement an e- commerce website.
About
Indigenized remote control interface card suitable for MAFI system CCR equipment. Compatible for IDM8000 CCR. Backplane mounted serial and TCP/Ethernet communication module for CCR remote access. IDM 8000 CCR remote control on serial and TCP protocol.
• Remote control: Parallel or serial interface.
• Compatible with MAFI CCR system.
• Compatible with IDM8000 CCR.
• Compatible with Backplane mount serial communication.
• Compatible with commercial and Defence aviation CCR system.
• Remote control system for accessing CCR and allied system over serial or TCP.
• Indigenized local Support/presence in India.
• Easy in configuration using DIP switches.
Technical Specifications
Indigenized remote control interface card suitable for MAFI system CCR equipment. Compatible for IDM8000 CCR. Backplane mounted serial and TCP/Ethernet communication module for CCR remote access. IDM 8000 CCR remote control on serial and TCP protocol.
Key Features
Indigenized remote control interface card suitable for MAFI system CCR equipment. Compatible for IDM8000 CCR. Backplane mounted serial and TCP/Ethernet communication module for CCR remote access. IDM 8000 CCR remote control on serial and TCP protocol.
• Remote control: Parallel or serial interface
• Compatible with MAFI CCR system
• Copatiable with IDM8000 CCR
• Compatible with Backplane mount serial communication.
• Compatible with commercial and Defence aviation CCR system.
• Remote control system for accessing CCR and allied system over serial or TCP.
• Indigenized local Support/presence in India.
Application
• Remote control: Parallel or serial interface.
• Compatible with MAFI CCR system.
• Compatible with IDM8000 CCR.
• Compatible with Backplane mount serial communication.
• Compatible with commercial and Defence aviation CCR system.
• Remote control system for accessing CCR and allied system over serial or TCP.
• Indigenized local Support/presence in India.
• Easy in configuration using DIP switches.
Overview of the fundamental roles in Hydropower generation and the components involved in wider Electrical Engineering.
This paper presents the design and construction of hydroelectric dams from the hydrologist’s survey of the valley before construction, all aspects and involved disciplines, fluid dynamics, structural engineering, generation and mains frequency regulation to the very transmission of power through the network in the United Kingdom.
Author: Robbie Edward Sayers
Collaborators and co editors: Charlie Sims and Connor Healey.
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Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)MdTanvirMahtab2
This presentation is about the working procedure of Shahjalal Fertilizer Company Limited (SFCL). A Govt. owned Company of Bangladesh Chemical Industries Corporation under Ministry of Industries.
1. ME Thesis presentation 2020-22
Department of Mechanical
Engineering,
JADAVPUR UNIVERSITY
Name – Akash Saha
Supervised by
Professor Sudipta De
Diesel engine waste heat recovery using a CO2
Propane mixture based trans-critical power
cycle: Optimization using Energy, Exergy and
Economic Analyses
2. Overview of the presentation
• Objective of the work
• Selection of the working fluid
• Waste heat recovery system diagram
• Assumptions
• T-s diagram and first law equations
• 2nd law equations
• Grassmann diagram
• Heat Exchanger Area Calculation
• Economic Analysis
• Optimization Algorithm
• Results of the analysis
• Conclusion
• Literature survey
3. Objective of the current study
Intention of the present study is to employ a
trans-critical regenerative power cycle to recover
waste heat of a diesel power plant.
CO2/ propane mixture with different CO2 mass
ratio is used as the working fluid of the power cycle
to ensure safe and environment friendly operation
simultaneously.
An optimization algorithm is also employed to
ensure the best operating performance of the
presented power cycle.
4. Selection of working fluid
Effect of different CO2 mass fraction in (CO2/ Propane) mixture of
critical temperature and temperature glide at condenser operating
condition
6. Assumptions
• Steady flow operating conditions are applicable
• Isentropic efficiencies of the compressor and the turbine are both assumed to be 85%.
• The ambient condition is specified to be 100kPa and 25oC.
• The chemical exergy has been ignored as the composition is constant throughout the
cycle.
• All the heat exchangers are assumed to be of shell and tube type.
• In both the HRU, the working fluid is assumed to flows through tubes
• Working fluid mass flux is assumed to be 350kg/m2s
• Flue gas velocity over the tube bank is not allowed to go above 10m/s.
• Maximum velocity of engine coolant in the HRU is assumed to be 0.75m/s
• In the regenerator, high pressure working fluid is taken on the tube side, while the low
pressure working fluid is taken on the shell side.
• The thermo-physical properties of flue gas are assumed to be the same as that of air.
• The cooling water is available at 25oC. Thus, the minimum cycle temperature is
assumed to be 35oC.
• Flue gas contains SO2. Thus, the acid dew point temperature of the flue gas is assumed
to be 120oC (so the flue gas is cooled to just 130 oC for additional safety).
• Due to a lower turbine power output (< 1.5 MW turbine power), radial flow turbines are
used.
• The whole heat exchanger system is designed taking a pinch point temperature
difference of 10oC.
7. T-s diagram of the waste heat recovery
system and 1st law equations
T-s diagram of the waste heat driven cycle
10. Heat Exchanger Area calculation
Nusselt Number of shell side fluid
Nusselt Number of supercritical tube side fluid
Krasnoshchekov and Protopopov (1959, 1960,
1961) correlation
Discretization of the heat exchanger
11. Economic Analysis
(Based on the data
and formulae from
the book by Turton)
COM = 5% of CTot
AOH = 8000 hours
i = 5%
LT = 25 years
13. Results of the analysis – 1
Effects of turbine inlet temperature on working fluid mass flow rate
and working fluid inlet temperature to FGHRU
14. Results of the analysis – 2
Effects of varying turbine inlet temperature on
waste heat recovery
15. Results of the analysis – 3
Effects of varying turbine inlet temperature in net
work output and 1st law efficiency
16. Results of the analysis – 4
Effects of varying CO2 mass fraction on maximum cycle
power output at different turbine inlet pressure
17. Results of the analysis – 5
Effects of varying CO2 mass fraction and turbine inlet pressure
on levelized electricity cost
18. Results of the analysis – 6
Comparison of minimum achievable LEC at different TIP of the trans-critical power cycle with
mixture working fluid with the LEC at different TIP of the supercritical CO2 power cycle.
19. Conclusion
1. It is observed that, at a lower turbine inlet pressure of working fluid, cycle power
output significantly increases with reducing CO2 mass fraction in the mixture
working fluid. Corresponding reduction in levelized electricity cost (LEC) is also
found to be significant. For a higher turbine inlet pressure, effects of varying mixture
composition are having less significant effects on cycle power output and LECs.
2. For any specified mixture composition net cycle power output increases with an
increasing turbine inlet pressure. However, this increment is not very appreciable
above a certain turbine inlet pressure (i.e., 14 MPa).
3. For any specified mixture composition, LEC becomes minimum corresponding to a
specific turbine inlet pressure. The minimum LEC of the cycle is found to be at 12
MPa turbine inlet pressure, for 0.3 mass fraction of CO2.
4. The minimum achievable LEC for the presented transcritical cycle operating with
mixture working fluid is close to 6.36% lower compared to that of an optimized
supercritical CO2 power cycle recovering waste heat from a similar source.
Corresponding turbine inlet pressure for the transcritical mixture based cycle is close
to 33% lower compared to that of the supercritical CO2 power cycle.
Finally, diesel power plant and the presented waste heat recovery scheme together can
yield 8% higher power output compared to the yielded power output of the diesel power
plant without waste heat recovery.
20. References
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Editor's Notes
GRASSMANN DIAGRAM NOT VISIBLE ON PROJECTOR
GRASSMANN DIAGRAM NOT VISIBLE ON PROJECTOR
TUBE DIAGRAM NOT VISIBLE, PROTOPOV CORRELATION DESCRIPTION NOT VISIBLE