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|a 9780128206263
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|a TK1041
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|a 621.199
|2 23
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|a Polygeneration systems :
|b design, processes and technologies /
|c [edited by] Francesco Calise [and more].
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|a London :
|b Academic Press,
|c 2022.
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|a 1 online resource
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|a text
|b txt
|2 rdacontent
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|a Print version record.
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|a Front Cover -- Polygeneration Systems -- Copyright Page -- Contents -- List of contributors -- 1 Polygeneration -- 1.1 Introduction -- 1.2 Polygeneration: layout -- 1.3 Polygeneration: fuels -- 1.3.1 Fossil fuels -- 1.3.2 Renewable energies -- 1.3.3 Hybrid energy inputs -- 1.4 By-products of polygeneration systems -- 1.5 Distributed generation -- 1.6 Pro and cons -- References -- 2 Components and processes of polygeneration systems -- 2.1 Main components included in polygeneration systems -- 2.1.1 Internal combustion engines -- 2.1.2 Steam turbine cycles -- 2.1.3 Organic Rankine cycles -- 2.1.4 Gas turbine cycles -- 2.1.5 Combined cycles -- 2.1.6 Fuel cells -- 2.1.7 Electric-driven and heat-driven chillers and heat pumps -- 2.1.8 Wind systems -- 2.1.9 Geothermal systems -- 2.1.10 Biomass systems -- 2.1.11 Solar collectors, photovoltaic panels, and concentrated solar power -- 2.1.11.1 Solar stationary collectors -- 2.1.11.2 Solar tracking concentrating collectors -- 2.1.11.3 Photovoltaic panels -- 2.1.12 Hydrosystems -- 2.2 Storage systems -- 2.2.1 Electric energy vehicles -- 2.3 Main processes included in polygeneration systems -- References -- 3 Methodologies for the evaluation of polygeneration systems -- 3.1 Introduction -- 3.2 Basic indicators of energo-environmental performance for polygeneration plants -- 3.3 Fundamentals of eligibility criteria for high-efficiency combined heat and power assessment -- 3.4 Economics of polygeneration systems under market conditions -- 3.5 Evaluation methods for the optimal plant design and operation strategies -- 3.6 Thermoeconomic analysis of polygeneration systems -- 3.7 Conclusions -- References -- Further reading -- 4 Natural gas-based polygeneration systems -- 4.1 Introduction -- 4.2 Natural gas use -- 4.3 Natural gas-driven combined cooling, heat, and power systems.
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|a 4.4 Natural gas-driven polygeneration systems -- 4.1 Natural gas polygeneration systems with desalination processes -- 4.2 Natural gas polygeneration systems based on reforming processes -- 4.3 Natural gas polygeneration systems based on chemical looping -- 4.4 Natural gas and coal or petcoke polygeneration systems -- 4.5 Conclusions -- Acknowledgments -- References -- 5 Biomass-based systems -- 5.1 Introduction to biomass-based polygeneration plants -- 5.2 Biomass feedstocks for polygeneration plants -- 5.2.1 Dedicated energy crops and algae -- 5.2.2 Agricultural and forestry residues -- 5.2.3 Municipal, agroindustrial, and animal industry residues -- 5.3 Biomass polygeneration plant pretreatments -- 5.3.1 Biological pretreatments -- 5.3.2 Nonbiological: physical pretreatments -- 5.3.3 Nonbiological: chemical pretreatments -- 5.3.4 Nonbiological: physical-chemical pretreatments -- 5.4 Thermochemical processes in polygeneration from biomass -- 5.4.1 Pyrolysis for polygeneration -- 5.4.2 Combustion for polygeneration -- 5.4.3 Gasification for polygeneration -- 5.4.4 Purification and conditioning of syngas obtained from biomass -- 5.5 Biochemical processes in polygeneration from biomass -- 5.5.1 Hydrolysate fermentation -- 5.5.1.1 Bioethanol -- 5.5.1.2 Biodiesel -- 5.5.1.3 Hydrogen -- 5.5.2 Syngas fermentation -- 5.6 Outputs of biomass-based polygeneration systems -- 5.6.1 Biomass-based polygeneration systems for energy production -- 5.6.2 Biomass-based polygeneration systems for energy and biofuels production -- 5.6.3 Other outputs of biomass-based polygeneration systems -- References -- 6 Solar-based systems -- 6.1 Introduction -- 6.2 Solar technologies -- 6.2.1 Photovoltaics -- 6.2.2 Concentrating solar power -- 6.2.2.1 Parabolic trough collector -- 6.2.2.2 Linear fresnel reflectors -- 6.2.2.3 Solar power tower -- 6.2.2.4 Solar dish.
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|a 6.2.3 Solar thermal heating and cooling -- 6.2.3.1 Flat-plate collectors -- 6.2.3.2 Evacuated tube collectors -- 6.2.3.3 Compound parabolic collectors -- 6.3 Solar polygeneration systems -- 6.4 Hybridized solar polygeneration systems -- 6.5 Example of a solar-based polygeneration system -- 6.5.1 System layout and operation strategy -- 6.5.2 Methodology -- 6.5.2.1 Energy savings and economic model -- 6.5.2.2 Case study -- 6.5.3 Presentation of the results -- 6.5.3.1 Weekly analysis -- 6.5.3.2 Yearly results -- 6.5.3.3 Sensitivity analysis -- Nomenclature -- References -- 7 Hybrid fossil fuel/renewable systems for polygeneration -- 7.1 Introduction -- 7.2 Natural gas and solar energy systems -- 7.2.1 Natural gas and solar thermal systems -- 7.2.2 Natural gas and photovoltaic panels -- 7.2.3 Natural gas and solar energy for cogeneration -- 7.2.4 Natural gas and fuel cell systems -- 7.3 Natural gas, biomass, and geothermal systems -- 7.4 Diesel and solar energy systems -- 7.5 Generation of alternative fuels in fossil/RES hybrid/polygeneration plants -- 7.5.1 Alternative fuels for internal use in a system -- 7.5.2 Alternative fuels as products of a system -- 7.6 Conclusions -- Nomenclature -- References -- 8 Combined cooling, heat, and power systems -- 8.1 Introduction -- 8.2 Absorption-based trigeneration systems -- 8.2.1 Introductory notes on absorption chillers -- 8.2.2 Literature overview -- 8.3 Adsorption-based trigeneration systems -- 8.3.1 Introductory notes on adsorption chillers -- 8.3.2 Literature overview -- 8.4 Desiccant cooling-based trigeneration systems -- 8.4.1 Introductory notes on desiccant cooling systems -- 8.4.2 Literature overview -- 8.5 Other trigeneration systems -- 8.5.1 Combined cooling, heating, and power systems based on ejector refrigeration cycles -- 8.5.2 Ammonia-water cycle configurations -- 8.6 Conclusions -- References.
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|a 9 Fourth generation district heating and cooling -- 9.1 Introduction -- 9.2 Smart energy system -- 9.3 Fourth generation district heating and cooling integrated into smart energy system -- 9.3.1 Polygeneration and energy sources for fourth GDHC -- 9.3.2 Control strategy -- 9.3.3 Storage -- 9.3.4 Main indices to evaluate the energetic, environmental, and economic characteristics of fourth GDHC -- 9.4 Outlook of the fourth generation district heating and cooling network -- 9.5 Example of fourth generation district heating -- 9.5.1 System layout and operation strategy -- 9.5.2 Model -- 9.5.2.1 Building -- 9.5.2.2 Reversible heat pump -- 9.5.2.3 Pipe -- 9.5.3 Presentation of the results -- 9.6 Conclusion -- Nomenclature -- References -- 10 Polygeneration systems in buildings -- 10.1 Introduction -- 10.2 Energy in buildings -- 10.2.1 Demand types and intensities -- 10.2.2 Space heating and cooling -- 10.2.3 Serving demand through polygeneration -- 10.2.4 Storage and demand response -- 10.2.5 Zero and Positive Energy Buildings -- 10.2.6 Energy vectors -- 10.3 Fuel-based polygeneration approaches -- 10.3.1 Fuel combustion and heat engines -- 10.3.2 Fuel cells -- 10.4 Solar-based polygeneration approaches -- 10.4.1 Solar energy resources -- 10.4.2 Solar thermal systems -- 10.4.3 Photovoltaics -- 10.4.4 Photovoltaic-thermal systems -- 10.4.5 Solar CHP building integration with hydronic systems -- 10.4.6 Solar CHP building integration with ventilation systems -- 10.4.7 Solar-based CCHP systems -- 10.4.8 Solar polygeneration building envelopes with daylighting functions -- 10.4.9 Multifunction solar polygeneration building envelopes -- References -- Supplementary references for Figure 10.3 -- 11 Polygeneration systems in industry -- 11.1 Introduction -- 11.2 Evolution of the concept of polygeneration -- 11.3 Industrial polygeneration.
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|a 11.3.1 Coal-based industrial polygeneration -- 11.3.2 Polygeneration in existing industrial units -- 11.3.2.1 Scope of polygeneration in iron and steel industries -- 11.3.2.2 Scope of polygeneration in cement plant -- 11.3.2.3 Scope of polygeneration in an aluminum production unit -- 11.3.2.4 Scope of polygeneration in oil refineries -- 11.3.2.5 Scope of polygeneration in the sugarcane industry -- 11.3.2.6 Scope of polygeneration in a glass manufacturing unit -- 11.3.2.7 Scope of polygeneration in marine ship -- 11.3.2.8 Polygeneration integrated into the pulp and paper mill -- 11.3.2.9 Scope of polygeneration in the high water cut stage of an oilfield -- 11.3.3 Scope of using low-grade industrial waste heat in polygeneration -- 11.4 Conclusions -- References -- Index -- Back Cover.
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650 |
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0 |
|a Cogeneration of electric power and heat.
|
650 |
|
0 |
|a Hybrid power systems.
|
650 |
|
6 |
|a Cog�en�eration de chaleur et d'�electricit�e.
|0 (CaQQLa)201-0066603
|
650 |
|
6 |
|a �Energie
|x Syst�emes hybrides.
|0 (CaQQLa)201-0419235
|
650 |
|
7 |
|a cogeneration plants.
|2 aat
|0 (CStmoGRI)aat300188636
|
650 |
|
7 |
|a Cogeneration of electric power and heat
|2 fast
|0 (OCoLC)fst00866437
|
650 |
|
7 |
|a Hybrid power systems
|2 fast
|0 (OCoLC)fst00964524
|
700 |
1 |
|
|a Calise, Francesco.
|
776 |
0 |
8 |
|i Print version:
|z 9780128206263
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776 |
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8 |
|i Print version:
|z 012820625X
|z 9780128206256
|w (OCoLC)1245344028
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856 |
4 |
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|u https://sciencedirect.uam.elogim.com/science/book/9780128206256
|z Texto completo
|