Polygeneration Process Concept for Hybrid Solar and Biomass Power Plant
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Polygeneration Process Concept for Hybrid Solar and Biomass Power Plant
Simulation, Modelling, and Optimization
John Wiley & Sons Inc
12/2018
294
Dura
Inglês
9781119536093
15 a 20 dias
648
Descrição não disponível.
Contents Foreword ix Preface xi 1. Introduction 1 1.1. Global Scenario on Renewable Energy 3 1.2. Indian Scenario on Renewable Energy 6 Exercise 8 References 9 2. State-of-the-Art Concentrated Solar Thermal Technologies for End Use Applications 11 2.1. Solar Thermal Technologies for Low Grade Heat Applications 11 2.1.1. Flat Plate Collector System 12 2.1.2. Built-In Storage Solar Water Heating System 15 2.1.3. Evacuated Tubular Collector System 16 ETC Water Heating System Specification 18 2.1.4. Cumulative Growth of SWHS Installation Capacity 20 2.1.5. Performance Evaluation of SWHs 20 2.1.6. Cost Benefits Analysis 23 2.2. Solar Cooking 25 2.2.1. Thermal Performance of Solar Box Type Cooker 30 2.3. Solar Thermal Cooling 35 2.4. Desalination System 38 2.5. Industrial Process Heat applications 45 2.6. Solar Thermal Technologies for Power Generation 49 2.6.1. Parabolic Trough Collector 49 2.6.2. Linear Fresnel Reflector 51 2.6.3. Central Solar Tower 53 2.6.4. Parabolic Dish 54 2.7. Cooling with Process Heat in Cogeneration Process for Industrial Applications 57 2.7.1. System Description 58 Exercise 61 References 62 3. Resource Assessment of Solar and Biomass for Hybrid Thermal Power Plant 69 3.1. Apparent Solar Time 70 3.2. Solar Angles 71 3.3. Solar Resources (DNI) In India 76 3.3.1. Solar DNI from Satellite and Ground Measured Data 76 3.3.2. DNI Assessment at NISE 78 3.4. Biomass Resources in India 81 3.5. Analysis of Solar DNI And Biomass Resources for Hybrid Power Plants 83 Exercise 106 References 106 4. Solar Thermal Power Plant 109 4.1. A Case Study of 1 MWe Solar Thermal Power Plant 122 4.2. Major Components 124 4.2.1. Parabolic Trough Collector 124 4.2.2. Linear Fresnel Reflector 125 4.2.3. Storage 127 4.2.4. Nitrogen Blanketing System 129 4.2.5. Heat Exchanger 129 4.2.6. Power Block 132 4.2.7. Balance of Plant-Utility Systems 134 4.3. Performance of the Plant 136 Exercise 161 References 162 5. Modeling and Simulation of Hybrid Solar and Biomass Thermal Power Plant 163 5.1. Modeling Approach of a Hybrid Solar-Biomass Thermal Power Plant 167 5.2. Thermodynamic Evaluation 168 5.2.1. Energy Evaluation 169 5.2.2. Exergy Evaluation 174 5.3. Analysis of Hybrid Solar and Biomass Thermal Power Plant 177 Exercise 181 References 182 6. Modeling, Simulation, Optimization and Cost Analysis of a Polygeneration Hybrid Solar Biomass System 187 6.1. Modeling Approach of Polygeneration Process in an HSB Thermal Power Plant 191 6.2. Thermodynamic Evaluation 193 6.2.1. Energy Evaluation 193 6.2.2. Exergy Evaluation 201 6.3. Primary Energy Savings on the Polygeneration Process in an HSB Thermal Power Plant 206 6.4. Optimization 207 6.4.1. Objective Functions 207 6.4.2. Decision Variable and Constraints 207 6.4.3. Genetic Algorithm (GA) 207 6.5. Cost Analysis 209 6.6. Analysis Of Polygeneration Process in an HSB Thermal Power Plant for Power, Cooling, and Desalination 211 6.7. Optimization of the Polygeneration System 216 6.8. Cost Analysis of a Polygeneration System 220 Exercise 224 References 226 Appendix 1 231 Nomenclature 231 Greek 233 Subscripts 233 Acronyms 234 Appendix 2. 237 EES Software Coding 237 Appendix 3. 253 Multiple Choice Questions (MCQ) with Answers. 253 Answers 274 About the Author 275 Index 277
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groundbreaking; practical; new; theory; indepth; method; study; applications; alternative; renewable; sources; energy; development; global warming; significant; phenomenon; issue; technologies; sustainability; worldwide; system
Contents Foreword ix Preface xi 1. Introduction 1 1.1. Global Scenario on Renewable Energy 3 1.2. Indian Scenario on Renewable Energy 6 Exercise 8 References 9 2. State-of-the-Art Concentrated Solar Thermal Technologies for End Use Applications 11 2.1. Solar Thermal Technologies for Low Grade Heat Applications 11 2.1.1. Flat Plate Collector System 12 2.1.2. Built-In Storage Solar Water Heating System 15 2.1.3. Evacuated Tubular Collector System 16 ETC Water Heating System Specification 18 2.1.4. Cumulative Growth of SWHS Installation Capacity 20 2.1.5. Performance Evaluation of SWHs 20 2.1.6. Cost Benefits Analysis 23 2.2. Solar Cooking 25 2.2.1. Thermal Performance of Solar Box Type Cooker 30 2.3. Solar Thermal Cooling 35 2.4. Desalination System 38 2.5. Industrial Process Heat applications 45 2.6. Solar Thermal Technologies for Power Generation 49 2.6.1. Parabolic Trough Collector 49 2.6.2. Linear Fresnel Reflector 51 2.6.3. Central Solar Tower 53 2.6.4. Parabolic Dish 54 2.7. Cooling with Process Heat in Cogeneration Process for Industrial Applications 57 2.7.1. System Description 58 Exercise 61 References 62 3. Resource Assessment of Solar and Biomass for Hybrid Thermal Power Plant 69 3.1. Apparent Solar Time 70 3.2. Solar Angles 71 3.3. Solar Resources (DNI) In India 76 3.3.1. Solar DNI from Satellite and Ground Measured Data 76 3.3.2. DNI Assessment at NISE 78 3.4. Biomass Resources in India 81 3.5. Analysis of Solar DNI And Biomass Resources for Hybrid Power Plants 83 Exercise 106 References 106 4. Solar Thermal Power Plant 109 4.1. A Case Study of 1 MWe Solar Thermal Power Plant 122 4.2. Major Components 124 4.2.1. Parabolic Trough Collector 124 4.2.2. Linear Fresnel Reflector 125 4.2.3. Storage 127 4.2.4. Nitrogen Blanketing System 129 4.2.5. Heat Exchanger 129 4.2.6. Power Block 132 4.2.7. Balance of Plant-Utility Systems 134 4.3. Performance of the Plant 136 Exercise 161 References 162 5. Modeling and Simulation of Hybrid Solar and Biomass Thermal Power Plant 163 5.1. Modeling Approach of a Hybrid Solar-Biomass Thermal Power Plant 167 5.2. Thermodynamic Evaluation 168 5.2.1. Energy Evaluation 169 5.2.2. Exergy Evaluation 174 5.3. Analysis of Hybrid Solar and Biomass Thermal Power Plant 177 Exercise 181 References 182 6. Modeling, Simulation, Optimization and Cost Analysis of a Polygeneration Hybrid Solar Biomass System 187 6.1. Modeling Approach of Polygeneration Process in an HSB Thermal Power Plant 191 6.2. Thermodynamic Evaluation 193 6.2.1. Energy Evaluation 193 6.2.2. Exergy Evaluation 201 6.3. Primary Energy Savings on the Polygeneration Process in an HSB Thermal Power Plant 206 6.4. Optimization 207 6.4.1. Objective Functions 207 6.4.2. Decision Variable and Constraints 207 6.4.3. Genetic Algorithm (GA) 207 6.5. Cost Analysis 209 6.6. Analysis Of Polygeneration Process in an HSB Thermal Power Plant for Power, Cooling, and Desalination 211 6.7. Optimization of the Polygeneration System 216 6.8. Cost Analysis of a Polygeneration System 220 Exercise 224 References 226 Appendix 1 231 Nomenclature 231 Greek 233 Subscripts 233 Acronyms 234 Appendix 2. 237 EES Software Coding 237 Appendix 3. 253 Multiple Choice Questions (MCQ) with Answers. 253 Answers 274 About the Author 275 Index 277
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