Novel Application of Combined Heat and Power for Multi-family Residences and Small Remote Communities PDF Download
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Author: Saeed A. Alqaed
Publisher:
ISBN:
Category : Cogeneration of electric power and heat
Languages : en
Pages : 104
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Book Description
Combined heat and power (CHP) systems are increasingly used in conjunction with traditional grid power for industrial and residential applications. This technology most often involves the on-site combustion of primary fuel, such that both electrical and thermal energy can be utilized to increase overall efficiency. It is also possible to create electrical and thermal energy from solar radiation, using hybrid photovoltaics and thermal (PVT) collectors. These are designed to lower the photovoltaic temperature, improving electrical efficiency, while providing useful thermal energy. One of the key steps in deploying CHP technology is optimal sizing and energy dispatch for a particular application. This work considers these problems for a natural gas powered CHP in a multi-family residential building in North America, and PVT for desalination in remote areas in the Kingdom of Saudi Arabia (KSA). It has already been established that CHP for building applications can reduce grid power requirement and lower overall energy costs. However, no comprehensive study has considered optimizing CHPs for multi-family residences. Although this type of building represents a significant fraction of overall energy consumption in the US and world, they have been shown to be significantly less efficient than other types of residences. Also, due to significant thermal demand in the form of hot-water, multi-family residences are particularly well-suited for CHP.Two separate natural gas powered CHP designs for a multi-family residence are presented in this work, both conceived as retrofits to an existing building. These designs use historical demand data from an all-electric 120-unit multi-family residence in Columbus, Ohio, US that was built in 2008 to minimum code standards. The first design uses a CHP that operates intermittently to meet partial loads for electricity and hot water in order to reduce overall energy cost, when considering a demand sensitive grid power cost pricing schedule. A mathematical model is developed for activating the CHP and dispatching its electric power to the building and thermal energy to a central hot water tank. The modeling includes a detailed cost function, which is optimized over the CHP and storage tank sizes under a constraint on the CHP duty cycle.The second CHP design for a multi-family residence considers a cold climate, such that the building would have greater thermal energy needs. In this case, the CHP is used in conjunction with a ground-coupled geothermal heat pump (GCHP) system, forming a hybrid design. GCHP systems use the ground as a heat source or sink to improve the efficiency of space heating and cooling, and GCHP is often used in residential and commercial buildings due to their higher efficiency and lower environmental impact. However, for a heating-dominated climate, the residential building would take more thermal energy from the ground in the winter than it returns in the summer, causing the ground temperature to drop over time. To correct this, the design presented here operates the CHP continuously, and passes its excess thermal energy to the ground, thus enabling the possibility for balancing the heating and cooling of the ground over each year. On the electrical side of the system, a battery storage element is added to better match the variations in load to the continuous CHP electrical output. The third CHP design considered in this work uses PVT for desalination in a hot, dry climate. As global demand for fresh water increases, desalination technology is becoming more important because natural supplies of fresh water are fixed. Desalination activity is largely concentrated in the Middle East, where dry Arab countries rely on desalination to meet their fresh water demand. The energy needed for desalination in the Middle East is mainly provided by burning oil, raising concerns about greenhouse gas (GHG) emissions and, frankly, increasingly depleted supply. In this context, this work presents a PVT design to power reverse-osmosis membrane desalination, most appropriate for small, remote communities in KSA. It has been shown that the energy demands for RO can be reduced by pre-heating the feed brine. Therefore, the design uses the thermal energy from PVT to pre-heat the feedwater and the electrical energy to satisfy the RO pumping demands. Thermal and battery storage, along with conventional backup power, are necessary in order to operate the RO continuously and utilize all of the renewable energy collected by the PVT. The design allows for sizing of the components in order to achieve minimum cost at any desired level of renewable energy penetration. The performance of each design presented in this work is measured primarily in terms of economic cost and carbon reduction. Savings relative to using conventional grid power are computed, allowing for determination of payback time and net present value. Results indicate that each CHP design provides both cost advantage and carbon reduction, spread out over the system lifetime. The scale of the advantages is examined as a function of parameters such as natural gas and grid power prices.
Author: Saeed A. Alqaed
Publisher:
ISBN:
Category : Cogeneration of electric power and heat
Languages : en
Pages : 104
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Book Description
Combined heat and power (CHP) systems are increasingly used in conjunction with traditional grid power for industrial and residential applications. This technology most often involves the on-site combustion of primary fuel, such that both electrical and thermal energy can be utilized to increase overall efficiency. It is also possible to create electrical and thermal energy from solar radiation, using hybrid photovoltaics and thermal (PVT) collectors. These are designed to lower the photovoltaic temperature, improving electrical efficiency, while providing useful thermal energy. One of the key steps in deploying CHP technology is optimal sizing and energy dispatch for a particular application. This work considers these problems for a natural gas powered CHP in a multi-family residential building in North America, and PVT for desalination in remote areas in the Kingdom of Saudi Arabia (KSA). It has already been established that CHP for building applications can reduce grid power requirement and lower overall energy costs. However, no comprehensive study has considered optimizing CHPs for multi-family residences. Although this type of building represents a significant fraction of overall energy consumption in the US and world, they have been shown to be significantly less efficient than other types of residences. Also, due to significant thermal demand in the form of hot-water, multi-family residences are particularly well-suited for CHP.Two separate natural gas powered CHP designs for a multi-family residence are presented in this work, both conceived as retrofits to an existing building. These designs use historical demand data from an all-electric 120-unit multi-family residence in Columbus, Ohio, US that was built in 2008 to minimum code standards. The first design uses a CHP that operates intermittently to meet partial loads for electricity and hot water in order to reduce overall energy cost, when considering a demand sensitive grid power cost pricing schedule. A mathematical model is developed for activating the CHP and dispatching its electric power to the building and thermal energy to a central hot water tank. The modeling includes a detailed cost function, which is optimized over the CHP and storage tank sizes under a constraint on the CHP duty cycle.The second CHP design for a multi-family residence considers a cold climate, such that the building would have greater thermal energy needs. In this case, the CHP is used in conjunction with a ground-coupled geothermal heat pump (GCHP) system, forming a hybrid design. GCHP systems use the ground as a heat source or sink to improve the efficiency of space heating and cooling, and GCHP is often used in residential and commercial buildings due to their higher efficiency and lower environmental impact. However, for a heating-dominated climate, the residential building would take more thermal energy from the ground in the winter than it returns in the summer, causing the ground temperature to drop over time. To correct this, the design presented here operates the CHP continuously, and passes its excess thermal energy to the ground, thus enabling the possibility for balancing the heating and cooling of the ground over each year. On the electrical side of the system, a battery storage element is added to better match the variations in load to the continuous CHP electrical output. The third CHP design considered in this work uses PVT for desalination in a hot, dry climate. As global demand for fresh water increases, desalination technology is becoming more important because natural supplies of fresh water are fixed. Desalination activity is largely concentrated in the Middle East, where dry Arab countries rely on desalination to meet their fresh water demand. The energy needed for desalination in the Middle East is mainly provided by burning oil, raising concerns about greenhouse gas (GHG) emissions and, frankly, increasingly depleted supply. In this context, this work presents a PVT design to power reverse-osmosis membrane desalination, most appropriate for small, remote communities in KSA. It has been shown that the energy demands for RO can be reduced by pre-heating the feed brine. Therefore, the design uses the thermal energy from PVT to pre-heat the feedwater and the electrical energy to satisfy the RO pumping demands. Thermal and battery storage, along with conventional backup power, are necessary in order to operate the RO continuously and utilize all of the renewable energy collected by the PVT. The design allows for sizing of the components in order to achieve minimum cost at any desired level of renewable energy penetration. The performance of each design presented in this work is measured primarily in terms of economic cost and carbon reduction. Savings relative to using conventional grid power are computed, allowing for determination of payback time and net present value. Results indicate that each CHP design provides both cost advantage and carbon reduction, spread out over the system lifetime. The scale of the advantages is examined as a function of parameters such as natural gas and grid power prices.
Author: H. Lee Willis
Publisher: CRC Press
ISBN: 9781420030310
Category : Technology & Engineering
Languages : en
Pages : 1246
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Book Description
Providing more than twice the content of the original edition, this new edition is the premier source on the selection, development, and provision of safe, high-quality, and cost-effective electric utility distribution systems, and it promises vast improvements in system reliability and layout by spanning every aspect of system planning including load forecasting, scheduling, performance, and economics. Responding to the evolving needs of electric utilities, Power Distribution Planning Reference Book presents an abundance of real-world examples, procedural and managerial issues, and engineering and analytical methodologies that are crucial to efficient and enhanced system performance.
Author: Andreas Deppe
Publisher:
ISBN:
Category :
Languages : en
Pages : 268
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Book Description
Author: R Beith
Publisher: Elsevier
ISBN: 0857092758
Category : Technology & Engineering
Languages : en
Pages : 553
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Book Description
Small and micro combined heat and power (CHP) systems are a form of cogeneration technology suitable for domestic and community buildings, commercial establishments and industrial facilities, as well as local heat networks. One of the benefits of using cogeneration plant is a vastly improved energy efficiency: in some cases achieving up to 80–90% systems efficiency, whereas small-scale electricity production is typically at well below 40% efficiency, using the same amount of fuel. This higher efficiency affords users greater energy security and increased long-term sustainability of energy resources, while lower overall emissions levels also contribute to an improved environmental performance.Small and micro combined heat and power (CHP) systems provides a systematic and comprehensive review of the technological and practical developments of small and micro CHP systems.Part one opens with reviews of small and micro CHP systems and their techno-economic and performance assessment, as well as their integration into distributed energy systems and their increasing utilisation of biomass fuels. Part two focuses on the development of different types of CHP technology, including internal combustion and reciprocating engines, gas turbines and microturbines, Stirling engines, organic Rankine cycle process and fuel cell systems. Heat-activated cooling (i.e. trigeneration) technologies and energy storage systems, of importance to the regional/seasonal viability of this technology round out this section. Finally, part three covers the range of applications of small and micro CHP systems, from residential buildings and district heating, to commercial buildings and industrial applications, as well as reviewing the market deployment of this important technology.With its distinguished editor and international team of expert contributors, Small and micro combined heat and power (CHP) systems is an essential reference work for anyone involved or interested in the design, development, installation and optimisation of small and micro CHP systems. - Reviews small- and micro-CHP systems and their techno-economic and performance assessment - Explores integration into distributed energy systems and their increasing utilisation of biomass fuels - Focuses on the development of different types of CHP technology, including internal combustion and reciprocating engines
Author: M M. Dewhirst
Publisher:
ISBN:
Category : Energy conservation
Languages : en
Pages : 4
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Author:
Publisher:
ISBN:
Category : Aeronautics
Languages : en
Pages : 1280
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Author: Patrick Whitefield
Publisher: Permanent Publications
ISBN: 9781856230216
Category : Business & Economics
Languages : en
Pages : 496
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Book Description
The long-awaited exploration of permaculture specifically for cooler Northern Hemisphere climates is finally here! Already regarded as the definitive book on the subject, The Earth Care Manual is accessible to the curious novice as much as it is essential for the knowledgeable practitioner. Permaculture started out in the 1970s as a sustainable alternative to modern agriculture, taking its inspiration from natural ecosystems. It has always placed an emphasis on gardening, but since then it has expanded to include many other aspects, from community design to energy use. It can be seen as an overall framework that puts a diversity of green ideas into perspective. Its aims are low work, high output, and genuine sustainability.
Author:
Publisher:
ISBN:
Category : Solar energy
Languages : en
Pages : 348
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Book Description
Author:
Publisher:
ISBN:
Category : Power resources
Languages : en
Pages : 906
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Book Description
Semiannual, with semiannual and annual indexes. References to all scientific and technical literature coming from DOE, its laboratories, energy centers, and contractors. Includes all works deriving from DOE, other related government-sponsored information, and foreign nonnuclear information. Arranged under 39 categories, e.g., Biomedical sciences, basic studies; Biomedical sciences, applied studies; Health and safety; and Fusion energy. Entry gives bibliographical information and abstract. Corporate, author, subject, report number indexes.
Author: Francesco Calise
Publisher: Academic Press
ISBN: 0128206268
Category : Technology & Engineering
Languages : en
Pages : 453
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Book Description
The support for polygeneration lies in the possibility of integrating different technologies into a single energy system, to maximize the utilization of both fossil and renewable fuels. A system that delivers multiple forms of energy to users, maximizing the overall efficiency makes polygeneration an emerging and viable option for energy consuming industries. Polygeneration Systems: Design, Processes and Technologies provides simple and advanced calculation techniques to evaluate energy, environmental and economic performance of polygeneration systems under analysis. With specific design guidelines for each type of polygeneration system and experimental performance data, referred both to single components and overall systems, this title covers all aspects of polygeneration from design to operation, optimization and practical implementation. Giving different aspects of both fossil and non-fossil fuel based polygeneration and the wider area of polygeneration processes, this book helps readers learn general principles to specific system design and development through analysis of case studies, examples, simulation characteristics and thermodynamic and economic data. - Detailed economic data for technology to assist developing feasibility studies regarding the possible application of polygeneration technologies - Offers a comprehensive list of all current numerical and experimental results of polygeneration available - Includes simulation models, cost figures, demonstration projects and test standards for designers and researchers to validate their own models and/or to test the reliability of their results
