Verfügbarkeit: Fuel cell micro-grids

Fuel cell micro-grids:

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Bibliographische Detailangaben
1. Verfasser:	Obara, Shin'ya (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	London Springer 2009
Ausgabe:	1. ed.
Schriftenreihe:	Power systems
Schlagworte:	Electric power transmission Fuel cells Netzwerk Brennstoffzelle
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	XX, 251 S. Ill., graph. Darst.
ISBN:	9781848003378

Internformat

MARC


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Datensatz im Suchindex

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adam_text	Contents 1 A Small-scale Fuel Cell Cogeneration System Considering Partial Load and Load Fluctuation ....................................................... 1 1.1 Introduction ................................................................................... 1 1.2 System Configuration .................................................................... 2 1.2.1 System Outline ................................................................. 2 1.2.2 Energy Loss and Mass Loss ............................................. 4 1.2.3 System Model and Equations ........................................... 5 1.2.4 Partial Load Operation ..................................................... 7 1.3 Energy Balance and Objective Function ....................................... 8 1.3.1 Energy Balance ................................................................ 8 1.3.2 Electric Heater Operation ................................................. 9 1.3.3 Thermal Storage Operation .............................................. 11 1.4 Energy Output Characteristics ....................................................... 11 1.4.1 System Operation Map ..................................................... 11 1.4.2 Load Fluctuation and Fuel Consumption ......................... 12 1.5 CaseStudy ..................................................................................... 14 1.5.1 System Outline ................................................................. 14 1.5.2 Results of the Operation Plan ........................................... 14 1.5.3 Annual Operation Cost of the System .............................. 15 1.6 Conclusions ................................................................................... 16 2 Equipment Arrangement Planning of a Fuel Cell Energy Network Optimized for Cost Minimization .......................................................... 17 2.1 Introduction ................................................................................... 17 2.2 System Scheme .............................................................................. 18 2.2.1 The Energy Network ........................................................ 18 2.2.2 Fuel Cell System .............................................................. 19 2.2.3 Heat Source Use Order .................................................... 20 2.2.4 City Gas Reformer ........................................................... 20 2.2.5 Operation Model of the System ....................................... 21 vi Contents 2.3 Amount of Heat Release of the Hot Water Piping Network (HWN) ................................................................. 22 2.4 Energy Balance .............................................................................. 24 2.4.1 The Balance of Power ...................................................... 24 2.4.2 The Balance of Heat ......................................................... 24 2.5 Cost Calculation and Objective Function ...................................... 25 2.5.1 Cost Calculation ............................................................... 25 2.5.2 Objective Function ........................................................... 26 2.6 Analysis Method and Case Study .................................................. 26 2.6.1 Optimization Using a Genetic Algorithm ........................ 26 2.6.2 Equipment Characteristics Model .................................... 27 2.6.3 Operation of the Heat Storage Tank and Boiler ............... 29 2.6.4 Specification of Hot Water Piping and a Hot Water Circulating Pump ............................................................. 29 2.6.5 Analysis Flow .................................................................. 30 2.6.6 Analysis Conditions ......................................................... 32 2.7 Analysis Result .............................................................................. 34 2.7.1 Operation Plan of the Fuel Cell and the Reformer ........... 34 2.7.2 Amount of Hot Water Heat Release and the Hot Water Piping Route ..................................................................... 36 2.7.3 Quantity of Flow of the Hot Water Circulating Pump ..... 38 2.7.4 Operation of the Heat Storage Tank and the Boiler ......... 39 2.7.5 Cost Analysis Results ....................................................... 40 2.7.6 Consideration of Analysis Accuracy ................................ 41 2.8 Conclusions ................................................................................... 42 3 Effective Improvement in Generation Efficiency due to Partition Cooperation Management ...................................................................... 43 3.1 Introduction ................................................................................... 43 3.2 System Configuration .................................................................... 44 3.2.1 Scheme of the FC Micro-grid .......................................... 44 3.2.2 System Configuration ...................................................... 45 3.2.3 Operating Method ............................................................ 46 3.3 Installation Planning of the FC Micro-grid .................................... 46 3.3.1 Generation Efficiency of the Micro-grid .......................... 46 3.3.2 The Power Demand Model .............................................. 49 3.3.3 The Analysis Method ....................................................... 50 3.4 CaseStudy ..................................................................................... 51 3.5 Analysis Results and Discussion ................................................... 52 3.5.1 Generation Efficiency of the Stand-alone System ........... 52 3.5.2 Generation Efficiency of the Central System ................... 54 3.5.3 Generation Efficiency of the Partition Cooperation System ......................................................... 54 3.6 Conclusions ................................................................................... 59 Contents Fuel Cell Network System Considering Reduction in Fuel Cell Capacity Using Load Leveling and Heat Release Loss ........................ 61 4.1 Introduction ................................................................................... 61 4.2 Load Leveling and the Arrangement Plan of the Fuel Cell ........... 62 4.2.1 The Fuel Cell Network System ........................................ 62 4.2.2 Power Generation Characteristics of the Fuel Cell .......... 63 4.2.3 Load Leveling Using Water Electrolysis ......................... 65 4.2.4 Distribution of the Fuel Cell ............................................ 65 4.2.5 Energy Balance Equation ................................................. 66 4.2.6 Operating Method of the System ..................................... 68 4.3 Analysis Method ............................................................................ 68 4.3.1 Procedure of Analysis ...................................................... 68 4.3.2 Solution Parameters ......................................................... 70 4.4 CaseStudy ..................................................................................... 71 4.4.1 Energy Demand Pattern and Network System ................. 71 4.4.2 Reduction Effect of the Fuel Cell Facility Capacity ........ 72 4.4.3 Route Planning Result of the Hot Water Piping ............... 73 4.4.4 Result of the Fuel Cell Arrangement Plan ....................... 75 4.5 Conclusions ................................................................................... 76 Equipment Plan of a Compound Interconnection Micro-grid Composed of Diesel Power Plants and a Fuel Cell ............................... 77 5.1 Introduction ................................................................................... 77 5.2 Compound Interconnection Micro-grid ......................................... 78 5.2.1 The Micro-grid Model ..................................................... 78 5.2.2 The СІМ Model ............................................................... 80 5.2.3 Facility Scheme ................................................................ 80 5.2.4 The СІМ Operating Method ............................................. 82 5.3 Equipment Characteristics ............................................................. 82 5.3.1 Diesel Engine Power Generator ....................................... 82 5.3.2 The Proton Exchange Membrane-type Fuel Cell ............. 84 5.4 Analysis Method ............................................................................ 84 5.4.1 Route Plan of the Compound Interconnection Grid ......... 84 5.4.2 Analysis Flow .................................................................. 85 5.4.3 The Power Demand Model .............................................. 86 5.5 CaseStudy ..................................................................................... 88 5.5.1 The Urban Area Model .................................................... 88 5.5.2 Complex Community ....................................................... 89 5.5.3 The Residential Area Model ............................................ 91 5.6 Conclusions ................................................................................... 93 viii Contents 6 The Effective-use Method of Exhaust Heat for Distributed Fuel Ceils ....................................................................... 95 6.1 Introduction ................................................................................... 95 6.2 Outline of the Fuel Cell Energy Network System ......................... 96 6.2.1 System Outline ................................................................. 96 6.2.2 The Path and the Amount of Heat Release from the Hot Water Piping ............................................... 98 6.2.3 Heat Energy Balance ........................................................ 100 6.2.4 The Heat Release Amount for a Hot Water Network ....... 101 6.3 Model of the Fuel Cell ................................................................... 102 6.3.1 Characteristics of Electric Power and Heat Output .......... 102 6.3.2 Energy Demand Pattern and Capacity of the Fuel Cell .... 103 6.4 Case Analysis ................................................................................ 104 6.4.1 Weather Conditions in Sapporo ....................................... 104 6.4.2 Analysis Method .............................................................. 105 6.5 Analysis Results ............................................................................ 107 6.5.1 The Optimal Path and the Amount of Heat Release from a Hot Water Piping Network ................................... 107 6.5.2 Optimal Path of the Energy Demand Pattern and the Hot Water Piping ................................................. 108 6.5.3 The Influence of Load Fluctuations ................................. 110 6.6 Conclusions ................................................................................... 111 7 Load Response Characteristics of the Fuel Cell for Individual Cold-region Houses ........................................................ 113 7.1 Introduction ................................................................................... 113 7.2 System Configuration .................................................................... 114 7.2.1 System Outline ................................................................. 114 7.2.2 Method of Power Generation ........................................... 116 7.2.3 Method of Heat Supply .................................................... 117 7.2.4 Controller and Auxiliary Machinery ................................ 117 7.2.5 Model of Operation Control ............................................. 118 7.3 The Time Constant of Each Piece of Equipment ........................... 119 7.3.1 The Time Constant of the Fuel Cell Stack ....................... 120 7.3.2 Town Gas Reformer ......................................................... 123 7.3.3 Inverter and System Interconnection Device ................... 124 7.3.4 The Time Constant of the Heat Pump .............................. 124 7.4 Analysis Method ............................................................................ 125 7.5 Results and Discussion .................................................................. 126 7.5.1 Control Variables of the Controller .................................. 126 7.5.2 Step Response Characteristics of the System ................... 128 7.5.3 Step Response Characteristics with Power Load Fluctuation ........................................... 130 7.5.4 Application to an Individual Cold-region House ............. 133 7.6 Conclusions ................................................................................... 135 Contents ix 8 Load Response Characteristics of a Fuel Cell Micro-grid with Control of the Number of Units .................................................... 137 8.1 Introduction ................................................................................... 137 8.2 The Micro-grid Model ................................................................... 138 8.2.1 Power Quality of the Micro-grid ...................................... 138 8.3 Response Characteristics of System Configuration Equipment .... 142 8.3.1 Generation Characteristics of the Engine Generator ........ 142 8.3.2 Generation Characteristics of the Fuel Cell ..................... 143 8.3.3 Output Characteristics of the City Gas Reformer ............ 144 8.3.4 Inverter and Interconnection Device ................................ 144 8.3.5 Generation Efficiency of the Fuel Cell System ................ 144 8.4 Control Variables and Analysis Method ........................................ 145 8.5 Load Response Characteristics of the Micro-grid ......................... 147 8.5.1 Step Response Characteristics .......................................... 147 8.5.2 Application of the Electric Power Demand Pattern of a House ........................................................................ 148 8.5.3 Generation Efficiency of the Fuel Cell ............................ 150 8.6 Conclusions ................................................................................... 152 9 Dynamic Characteristics of a PEM-FC/ Woody Biomass Engine Hybrid Micro-grid ......................................... 153 9.1 Introduction ................................................................................... 153 9.2 System Scheme .............................................................................. 154 9.2.1 The Hybrid Micro-grid ..................................................... 154 9.2.2 The Micro-grid System Operating Method ...................... 157 9.3 Control Response Characteristics of РЕМ -FC and SEG ............... 157 9.3.1 The Control Block Diagram ............................................. 157 9.3.2 Response Characteristics of PEM-FC .............................. 159 9.3.3 Response Characteristics of SEG ..................................... 160 9.4 Results of Dynamic Characteristics Analysis of the PWHC Micro-grid ..................................................................................... 161 9.4.1 Power Response Characteristics of PWHC ...................... 161 9.4.2 Response Characteristics of SEG and the PEM-FC Micro-grid Using the Power Load Pattern for Houses ..... 163 9.4.3 Response Characteristics of the PWHC Micro-grid Using the Power Load Pattern for Houses ....................... 165 9.5 Conclusions ................................................................................... 167 10 A Fuel Cell and Hydrogénation Engine Hybrid System Considering Efficiency Improvement for Partial-load Operation ...... 169 10.1 Introduction ................................................................................... 169 10.2 System Scheme .............................................................................. 170 10.2.1 The HCGS Model ............................................................ 170 10.2.2 Operation Method of the System ..................................... 171 x Contents 10.3 Equipment Characteristics ............................................................. 173 10.3.1 Output Characteristics of NEG ........................................ 173 10.3.2 Output Characteristics of РЕМ -FC .................................. 177 10.4 Power and Heat Output Characteristics of HCGS ......................... 179 10.4.1 Output Characteristics of NEG and РЕМ -FC .................. 179 10.4.2 Method Operating FC or NEG with the Threshold Value of the Load (OM-C) ............................................... 180 10.4.3 Operation Method Using РЕМ -FC Corresponding to a Base Load (OM-D) ................................................... 181 10.5 CaseSrudy ..................................................................................... 182 10.5.1 Power and Heat Demand Model ...................................... 182 10.5.2 Analysis Method .............................................................. 183 10.6 Results and Discussion .................................................................. 184 10.6.1 City Gas Consumption ..................................................... 184 10.6.2 Generation Efficiency and Total Efficiency ..................... 185 10.6.3 Carbon Dioxide Emissions ............................................... 186 10.6.4 Capacity of the Heat Storage Tank .................................. 187 10.7 Conclusions ................................................................................... 188 11 CO2 Discharged from a Compound Micro-grid of a Hydrogénation City Gas Engine and a Fuel Cell .......................... 189 11.1 Introduction ................................................................................... 189 11.2 System Scheme .............................................................................. 190 11.2.1 The IMPE Model ............................................................. 190 11.2.2 Operation Method of the Micro-grid ................................ 191 11.2.3 Equipment Scheme .......................................................... 191 11.3 Equipment Characteristics ............................................................. 193 11.3.1 Output Characteristics of the Gas Engine Power Generator .............................................................. 193 11.3.2 Carbon Dioxide Emissions of NEG ................................. 195 11.3.3 The РЕМ -FC System ....................................................... 196 11.4 Case Study ..................................................................................... 197 11.4.1 The Urban Area Model .................................................... 197 11.4.2 The Power Demand Model .............................................. 198 11.4.3 Analysis Flow .................................................................. 198 11.5 Results and Discussion .................................................................. 200 11.5.1 Power Load of the Micro-grid .......................................... 200 11.5.2 Capacity of the Power Plant ............................................. 202 11.5.3 Power Generation Efficiency ........................................... 202 11.5.4 Carbon Dioxide Emissions ............................................... 202 11.5.5 Heat Demand and Exhaust Heat Output .......................... 204 11.6 Conclusions ................................................................................... 204 Contents xi 12 Development of a Fast Operation Algorithm of a Fuel Cell System with Solar Reforming ................................................................ 207 12.1 Introduction ................................................................................... 207 12.2 System Configuration .................................................................... 208 12.2.1 The Fuel Cell System with Bioethanol Solar Reforming (FBSR) ................................................. 208 12.2.2 Installation Method of FBSR ........................................... 209 12.2.3 Control of Reformed Fuel ................................................ 209 12.3 Energy and Mass Balance .............................................................. 210 12.3.1 Energy Balance ................................................................ 210 12.3.2 Mass Balance ................................................................... 210 12.4 Dynamic Operation Prediction of SRF .......................................... 210 12.4.1 Analysis Procedure of the Operation Prediction Algorithm ........................................................ 210 12.4.2 Structure of the Neural Network ...................................... 211 12.4.3 Learning Calculation ........................................................ 212 12.4.4 The Operation Prediction Process .................................... 214 12.5 Preparation of the Training Signal Using a GA ............................. 215 12.5.1 Dynamic Operation Plan of a Representative Day ........... 215 12.5.2 Chromosome Model and Analysis Flow .......................... 216 12.5.3 System Operation ............................................................. 217 12.5.4 Objective Function and Adaptive Value .......................... 217 12.6 CaseStudy ..................................................................................... 218 12.6.1 Analysis System ............................................................... 218 12.6.2 Characteristics of the System ........................................... 218 12.6.3 Analysis Condition ........................................................... 219 12.7 Results and Discussion .................................................................. 221 12.7.1 Energy Supply by FBSR .................................................. 221 12.7.2 Analytic Accuracy of the Operation Prediction ............... 222 12.7.3 Analysis Error of the Heat Storage Prediction ................. 225 12.7.4 Relationship Between the Difference in Weather Characteristics and the Operation Prediction Error .......... 227 12.8 Conclusions ................................................................................... 230 13 Power Characteristics of a Fuel Cell Micro-grid with Wind Power Generation ................................................................ 231 13.1 Introduction ................................................................................... 231 13.2 The Micro-grid Model ................................................................... 232 13.3 Response Characteristics of System Configuration Equipment .... 233 13.3.1 Power Generation Characteristics of the Fuel Cell .......... 233 13.3.2 Output Characteristics of the City Gas Reformer ............ 233 13.3.3 Power Generation Characteristics of Wind Power Generation ............................................... 234 13.3.4 Generation Efficiency of the Fuel Cell System ................ 235 13.3.5 Inverter and System Interconnection Device ................... 236 xii Contents 13.4 Control Parameters and Analysis Method ..................................... 237 13.5 Load Response Characteristics of the Micro-grid ......................... 238 13.5.1 Step Response .................................................................. 238 13.5.2 Load Response Characteristics of Cold-region Houses ... 239 13.5.3 Power Generation Efficiency ........................................... 241 13.6 Conclusions ................................................................................... 242 References ......................................................................................................... 245 Index ................................................................................................................. 251
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spelling	Obara, Shin'ya Verfasser aut Fuel cell micro-grids Shin'ya Obara 1. ed. London Springer 2009 XX, 251 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Power systems Electric power transmission Fuel cells Netzwerk (DE-588)4171529-9 gnd rswk-swf Brennstoffzelle (DE-588)4008195-3 gnd rswk-swf Brennstoffzelle (DE-588)4008195-3 s Netzwerk (DE-588)4171529-9 s DE-604 Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017173857&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Obara, Shin'ya Fuel cell micro-grids Electric power transmission Fuel cells Netzwerk (DE-588)4171529-9 gnd Brennstoffzelle (DE-588)4008195-3 gnd
subject_GND	(DE-588)4171529-9 (DE-588)4008195-3
title	Fuel cell micro-grids
title_auth	Fuel cell micro-grids
title_exact_search	Fuel cell micro-grids
title_full	Fuel cell micro-grids Shin'ya Obara
title_fullStr	Fuel cell micro-grids Shin'ya Obara
title_full_unstemmed	Fuel cell micro-grids Shin'ya Obara
title_short	Fuel cell micro-grids
title_sort	fuel cell micro grids
topic	Electric power transmission Fuel cells Netzwerk (DE-588)4171529-9 gnd Brennstoffzelle (DE-588)4008195-3 gnd
topic_facet	Electric power transmission Fuel cells Netzwerk Brennstoffzelle
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017173857&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT obarashinya fuelcellmicrogrids

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