Verfügbarkeit: Sector Coupling - Energy-Sustainable Economy of the Future

Sector Coupling - Energy-Sustainable Economy of the Future: Fundamentals, Model and Planning Example of a General Energy System (GES)

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Bibliographische Detailangaben
1. Verfasser:	Komarnicki, Przemyslaw (VerfasserIn)
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	Wiesbaden Springer Vieweg. in Springer Fachmedien Wiesbaden GmbH 2022
Ausgabe:	1st ed
Schlagworte:	Interconnected electric utility systems
Online-Zugang:	DE-2070s
Beschreibung:	Description based on publisher supplied metadata and other sources
Beschreibung:	1 Online-Ressource (221 Seiten)
ISBN:	9783658381110

Internformat

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505	8		\|a Intro -- Foreword -- Preface -- Contents -- Abbreviations -- 1: Introduction: Climate Policy Goals of Sustainable Energy Supply -- 1.1 Why Do We Need a General Energy System (GES)? -- 1.1.1 World Population, Energy Resources and the ''Full World'' -- 1.1.2 Energy Consumption and CO2 Emissions: From Kyoto Protocol to Paris Agreement to Green Deal -- 1.1.3 Sector Coupling: What Is It? -- 1.1.3.1 Introduction -- 1.1.3.2 Example Germany -- 1.2 Paradigm Shift in Electrical Energy Supply Due to Regenerative Generation -- 1.2.1 Power, Energy and Efficiency -- 1.2.2 Potentials of Renewable Generation -- 1.2.3 Dunkelflaute and Other Special Features -- 1.2.3.1 General Comments -- 1.2.3.2 Dunkelflaute -- 1.2.3.3 Frequency Maintenance: System Inertia. Can the Electric Power System Remain Stable Without Inertia? [42] -- 1.2.3.4 Offshore Wind and Green Power from Africa -- References -- 2: Methodology and Model Design for Sector Coupling in the General Energy System (GES) -- 2.1 Modelling of a GES -- 2.1.1 Energy Hub Model -- 2.1.2 Temporal Resolution of Energy Flows -- 2.1.3 Substitution of Energy Sources -- 2.2 Optimisation of a GES -- 2.2.1 General Comments -- 2.2.2 Approaches to System Optimisation -- 2.2.2.1 Scenario-Based Optimization -- 2.2.3 Dynamic Programming According to Bellmann -- 2.2.3.1 Optimization by Means of Linear Programming -- References -- 3: Energy Use Sectors and Their Energy Consumption -- 3.1 General Remarks -- 3.2 Energy Supply (Gas, Electricity, Heat) and the Role of Hydrogen (H2) -- 3.3 Industry: Net Zero Factory -- 3.4 Households -- 3.5 Transport: Electric Mobility -- 3.6 Trade: Commerce - Services (GHD) -- References -- 4: Methodology of Modelling the Energy Hub Components -- 4.1 Introduction -- 4.2 Methodology for Modelling Generation Sectors -- 4.2.1 Electricity -- 4.2.1.1 Introduction
505	8		\|a 4.2.1.2 Modelling of Electricity Network Infrastructures -- 4.2.1.3 Simulation and Network Calculation Tool -- 4.2.2 Gas -- 4.2.2.1 Introduction -- 4.2.2.2 Modelling of Gas Network Infrastructures -- 4.2.2.3 Simulation and Software Tools -- 4.2.3 Heat -- 4.2.3.1 Introduction -- 4.2.3.2 Modelling of Heat Network Infrastructures -- 4.2.3.3 Simulation and Software Tools -- 4.2.4 Energy Market Design, Market Roles -- References -- 5: Flexibility of a General Energy System (GES) -- 5.1 Safe Operation of the General Energy System (GES) -- 5.2 Energy Storage -- 5.3 Evaluation of Flexibility -- 5.3.1 Introduction -- 5.3.2 Flexgraphs -- 5.3.3 Buffer Characteristics -- 5.3.4 Variable and Fixed Power Profiles -- 5.3.5 15-min Energy Values -- 5.4 Legal Framework -- 5.4.1 Introduction -- 5.4.2 Disconnectable Loads -- 5.4.3 Interruptible Consumption Units -- 5.4.4 Future Flexibility, System-Side Needs Analysis -- References -- 6: Role of Information and Communication Technology (ICT): Digitalisation of the Energy Industry -- 6.1 Development of Balancing in the Energy System Using the Example of Electricity -- 6.2 Current Balancing for Electricity, Gas and Heat Markets -- 6.2.1 Basics of Energy Balancing Using the Example of Electricity -- 6.2.2 Metering Point Operation: Role of the Smart Meter Rollout -- 6.2.3 Market Communication and Measurement Data Analysis -- 6.2.4 Balancing: Comparison Between Gas and Electricity -- 6.3 Role of ICT and Other Innovations in the System Management (Electricity) of the Future -- Literature -- 7: Perspectives of the General Energy System (GES) -- 7.1 Introduction -- 7.2 European Perspective -- 7.3 China Perspective -- 7.4 USA Perspective -- 7.5 Building a Sustainable Hydrogen Economy (Example EU/Germany) -- 7.5.1 Introduction -- 7.5.2 Concept for Germany -- 7.5.3 Regional Concepts Using the Example of the Land of Saxony-Anhalt
505	8		\|a References -- Appendix -- Conversion Chains (Energy Conversion Chains) of the Selected Processes (Table A.1)
650		4	\|a Interconnected electric utility systems
700	1		\|a Kranhold, Michael \|e Sonstige \|4 oth
700	1		\|a Styczynski, Zbigniew A. \|e Sonstige \|4 oth
776	0	8	\|i Erscheint auch als \|n Druck-Ausgabe \|a Komarnicki, Przemyslaw \|t Sector Coupling - Energy-Sustainable Economy of the Future \|d Wiesbaden : Springer Vieweg. in Springer Fachmedien Wiesbaden GmbH,c2022 \|z 9783658381103
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Datensatz im Suchindex

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contents	Intro -- Foreword -- Preface -- Contents -- Abbreviations -- 1: Introduction: Climate Policy Goals of Sustainable Energy Supply -- 1.1 Why Do We Need a General Energy System (GES)? -- 1.1.1 World Population, Energy Resources and the ''Full World'' -- 1.1.2 Energy Consumption and CO2 Emissions: From Kyoto Protocol to Paris Agreement to Green Deal -- 1.1.3 Sector Coupling: What Is It? -- 1.1.3.1 Introduction -- 1.1.3.2 Example Germany -- 1.2 Paradigm Shift in Electrical Energy Supply Due to Regenerative Generation -- 1.2.1 Power, Energy and Efficiency -- 1.2.2 Potentials of Renewable Generation -- 1.2.3 Dunkelflaute and Other Special Features -- 1.2.3.1 General Comments -- 1.2.3.2 Dunkelflaute -- 1.2.3.3 Frequency Maintenance: System Inertia. Can the Electric Power System Remain Stable Without Inertia? [42] -- 1.2.3.4 Offshore Wind and Green Power from Africa -- References -- 2: Methodology and Model Design for Sector Coupling in the General Energy System (GES) -- 2.1 Modelling of a GES -- 2.1.1 Energy Hub Model -- 2.1.2 Temporal Resolution of Energy Flows -- 2.1.3 Substitution of Energy Sources -- 2.2 Optimisation of a GES -- 2.2.1 General Comments -- 2.2.2 Approaches to System Optimisation -- 2.2.2.1 Scenario-Based Optimization -- 2.2.3 Dynamic Programming According to Bellmann -- 2.2.3.1 Optimization by Means of Linear Programming -- References -- 3: Energy Use Sectors and Their Energy Consumption -- 3.1 General Remarks -- 3.2 Energy Supply (Gas, Electricity, Heat) and the Role of Hydrogen (H2) -- 3.3 Industry: Net Zero Factory -- 3.4 Households -- 3.5 Transport: Electric Mobility -- 3.6 Trade: Commerce - Services (GHD) -- References -- 4: Methodology of Modelling the Energy Hub Components -- 4.1 Introduction -- 4.2 Methodology for Modelling Generation Sectors -- 4.2.1 Electricity -- 4.2.1.1 Introduction 4.2.1.2 Modelling of Electricity Network Infrastructures -- 4.2.1.3 Simulation and Network Calculation Tool -- 4.2.2 Gas -- 4.2.2.1 Introduction -- 4.2.2.2 Modelling of Gas Network Infrastructures -- 4.2.2.3 Simulation and Software Tools -- 4.2.3 Heat -- 4.2.3.1 Introduction -- 4.2.3.2 Modelling of Heat Network Infrastructures -- 4.2.3.3 Simulation and Software Tools -- 4.2.4 Energy Market Design, Market Roles -- References -- 5: Flexibility of a General Energy System (GES) -- 5.1 Safe Operation of the General Energy System (GES) -- 5.2 Energy Storage -- 5.3 Evaluation of Flexibility -- 5.3.1 Introduction -- 5.3.2 Flexgraphs -- 5.3.3 Buffer Characteristics -- 5.3.4 Variable and Fixed Power Profiles -- 5.3.5 15-min Energy Values -- 5.4 Legal Framework -- 5.4.1 Introduction -- 5.4.2 Disconnectable Loads -- 5.4.3 Interruptible Consumption Units -- 5.4.4 Future Flexibility, System-Side Needs Analysis -- References -- 6: Role of Information and Communication Technology (ICT): Digitalisation of the Energy Industry -- 6.1 Development of Balancing in the Energy System Using the Example of Electricity -- 6.2 Current Balancing for Electricity, Gas and Heat Markets -- 6.2.1 Basics of Energy Balancing Using the Example of Electricity -- 6.2.2 Metering Point Operation: Role of the Smart Meter Rollout -- 6.2.3 Market Communication and Measurement Data Analysis -- 6.2.4 Balancing: Comparison Between Gas and Electricity -- 6.3 Role of ICT and Other Innovations in the System Management (Electricity) of the Future -- Literature -- 7: Perspectives of the General Energy System (GES) -- 7.1 Introduction -- 7.2 European Perspective -- 7.3 China Perspective -- 7.4 USA Perspective -- 7.5 Building a Sustainable Hydrogen Economy (Example EU/Germany) -- 7.5.1 Introduction -- 7.5.2 Concept for Germany -- 7.5.3 Regional Concepts Using the Example of the Land of Saxony-Anhalt References -- Appendix -- Conversion Chains (Energy Conversion Chains) of the Selected Processes (Table A.1)
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spelling	Komarnicki, Przemyslaw Verfasser aut Sector Coupling - Energy-Sustainable Economy of the Future Fundamentals, Model and Planning Example of a General Energy System (GES) 1st ed Wiesbaden Springer Vieweg. in Springer Fachmedien Wiesbaden GmbH 2022 ©2023 1 Online-Ressource (221 Seiten) txt rdacontent c rdamedia cr rdacarrier Description based on publisher supplied metadata and other sources Intro -- Foreword -- Preface -- Contents -- Abbreviations -- 1: Introduction: Climate Policy Goals of Sustainable Energy Supply -- 1.1 Why Do We Need a General Energy System (GES)? -- 1.1.1 World Population, Energy Resources and the ''Full World'' -- 1.1.2 Energy Consumption and CO2 Emissions: From Kyoto Protocol to Paris Agreement to Green Deal -- 1.1.3 Sector Coupling: What Is It? -- 1.1.3.1 Introduction -- 1.1.3.2 Example Germany -- 1.2 Paradigm Shift in Electrical Energy Supply Due to Regenerative Generation -- 1.2.1 Power, Energy and Efficiency -- 1.2.2 Potentials of Renewable Generation -- 1.2.3 Dunkelflaute and Other Special Features -- 1.2.3.1 General Comments -- 1.2.3.2 Dunkelflaute -- 1.2.3.3 Frequency Maintenance: System Inertia. Can the Electric Power System Remain Stable Without Inertia? [42] -- 1.2.3.4 Offshore Wind and Green Power from Africa -- References -- 2: Methodology and Model Design for Sector Coupling in the General Energy System (GES) -- 2.1 Modelling of a GES -- 2.1.1 Energy Hub Model -- 2.1.2 Temporal Resolution of Energy Flows -- 2.1.3 Substitution of Energy Sources -- 2.2 Optimisation of a GES -- 2.2.1 General Comments -- 2.2.2 Approaches to System Optimisation -- 2.2.2.1 Scenario-Based Optimization -- 2.2.3 Dynamic Programming According to Bellmann -- 2.2.3.1 Optimization by Means of Linear Programming -- References -- 3: Energy Use Sectors and Their Energy Consumption -- 3.1 General Remarks -- 3.2 Energy Supply (Gas, Electricity, Heat) and the Role of Hydrogen (H2) -- 3.3 Industry: Net Zero Factory -- 3.4 Households -- 3.5 Transport: Electric Mobility -- 3.6 Trade: Commerce - Services (GHD) -- References -- 4: Methodology of Modelling the Energy Hub Components -- 4.1 Introduction -- 4.2 Methodology for Modelling Generation Sectors -- 4.2.1 Electricity -- 4.2.1.1 Introduction 4.2.1.2 Modelling of Electricity Network Infrastructures -- 4.2.1.3 Simulation and Network Calculation Tool -- 4.2.2 Gas -- 4.2.2.1 Introduction -- 4.2.2.2 Modelling of Gas Network Infrastructures -- 4.2.2.3 Simulation and Software Tools -- 4.2.3 Heat -- 4.2.3.1 Introduction -- 4.2.3.2 Modelling of Heat Network Infrastructures -- 4.2.3.3 Simulation and Software Tools -- 4.2.4 Energy Market Design, Market Roles -- References -- 5: Flexibility of a General Energy System (GES) -- 5.1 Safe Operation of the General Energy System (GES) -- 5.2 Energy Storage -- 5.3 Evaluation of Flexibility -- 5.3.1 Introduction -- 5.3.2 Flexgraphs -- 5.3.3 Buffer Characteristics -- 5.3.4 Variable and Fixed Power Profiles -- 5.3.5 15-min Energy Values -- 5.4 Legal Framework -- 5.4.1 Introduction -- 5.4.2 Disconnectable Loads -- 5.4.3 Interruptible Consumption Units -- 5.4.4 Future Flexibility, System-Side Needs Analysis -- References -- 6: Role of Information and Communication Technology (ICT): Digitalisation of the Energy Industry -- 6.1 Development of Balancing in the Energy System Using the Example of Electricity -- 6.2 Current Balancing for Electricity, Gas and Heat Markets -- 6.2.1 Basics of Energy Balancing Using the Example of Electricity -- 6.2.2 Metering Point Operation: Role of the Smart Meter Rollout -- 6.2.3 Market Communication and Measurement Data Analysis -- 6.2.4 Balancing: Comparison Between Gas and Electricity -- 6.3 Role of ICT and Other Innovations in the System Management (Electricity) of the Future -- Literature -- 7: Perspectives of the General Energy System (GES) -- 7.1 Introduction -- 7.2 European Perspective -- 7.3 China Perspective -- 7.4 USA Perspective -- 7.5 Building a Sustainable Hydrogen Economy (Example EU/Germany) -- 7.5.1 Introduction -- 7.5.2 Concept for Germany -- 7.5.3 Regional Concepts Using the Example of the Land of Saxony-Anhalt References -- Appendix -- Conversion Chains (Energy Conversion Chains) of the Selected Processes (Table A.1) Interconnected electric utility systems Kranhold, Michael Sonstige oth Styczynski, Zbigniew A. Sonstige oth Erscheint auch als Druck-Ausgabe Komarnicki, Przemyslaw Sector Coupling - Energy-Sustainable Economy of the Future Wiesbaden : Springer Vieweg. in Springer Fachmedien Wiesbaden GmbH,c2022 9783658381103
spellingShingle	Komarnicki, Przemyslaw Sector Coupling - Energy-Sustainable Economy of the Future Fundamentals, Model and Planning Example of a General Energy System (GES) Intro -- Foreword -- Preface -- Contents -- Abbreviations -- 1: Introduction: Climate Policy Goals of Sustainable Energy Supply -- 1.1 Why Do We Need a General Energy System (GES)? -- 1.1.1 World Population, Energy Resources and the ''Full World'' -- 1.1.2 Energy Consumption and CO2 Emissions: From Kyoto Protocol to Paris Agreement to Green Deal -- 1.1.3 Sector Coupling: What Is It? -- 1.1.3.1 Introduction -- 1.1.3.2 Example Germany -- 1.2 Paradigm Shift in Electrical Energy Supply Due to Regenerative Generation -- 1.2.1 Power, Energy and Efficiency -- 1.2.2 Potentials of Renewable Generation -- 1.2.3 Dunkelflaute and Other Special Features -- 1.2.3.1 General Comments -- 1.2.3.2 Dunkelflaute -- 1.2.3.3 Frequency Maintenance: System Inertia. Can the Electric Power System Remain Stable Without Inertia? [42] -- 1.2.3.4 Offshore Wind and Green Power from Africa -- References -- 2: Methodology and Model Design for Sector Coupling in the General Energy System (GES) -- 2.1 Modelling of a GES -- 2.1.1 Energy Hub Model -- 2.1.2 Temporal Resolution of Energy Flows -- 2.1.3 Substitution of Energy Sources -- 2.2 Optimisation of a GES -- 2.2.1 General Comments -- 2.2.2 Approaches to System Optimisation -- 2.2.2.1 Scenario-Based Optimization -- 2.2.3 Dynamic Programming According to Bellmann -- 2.2.3.1 Optimization by Means of Linear Programming -- References -- 3: Energy Use Sectors and Their Energy Consumption -- 3.1 General Remarks -- 3.2 Energy Supply (Gas, Electricity, Heat) and the Role of Hydrogen (H2) -- 3.3 Industry: Net Zero Factory -- 3.4 Households -- 3.5 Transport: Electric Mobility -- 3.6 Trade: Commerce - Services (GHD) -- References -- 4: Methodology of Modelling the Energy Hub Components -- 4.1 Introduction -- 4.2 Methodology for Modelling Generation Sectors -- 4.2.1 Electricity -- 4.2.1.1 Introduction 4.2.1.2 Modelling of Electricity Network Infrastructures -- 4.2.1.3 Simulation and Network Calculation Tool -- 4.2.2 Gas -- 4.2.2.1 Introduction -- 4.2.2.2 Modelling of Gas Network Infrastructures -- 4.2.2.3 Simulation and Software Tools -- 4.2.3 Heat -- 4.2.3.1 Introduction -- 4.2.3.2 Modelling of Heat Network Infrastructures -- 4.2.3.3 Simulation and Software Tools -- 4.2.4 Energy Market Design, Market Roles -- References -- 5: Flexibility of a General Energy System (GES) -- 5.1 Safe Operation of the General Energy System (GES) -- 5.2 Energy Storage -- 5.3 Evaluation of Flexibility -- 5.3.1 Introduction -- 5.3.2 Flexgraphs -- 5.3.3 Buffer Characteristics -- 5.3.4 Variable and Fixed Power Profiles -- 5.3.5 15-min Energy Values -- 5.4 Legal Framework -- 5.4.1 Introduction -- 5.4.2 Disconnectable Loads -- 5.4.3 Interruptible Consumption Units -- 5.4.4 Future Flexibility, System-Side Needs Analysis -- References -- 6: Role of Information and Communication Technology (ICT): Digitalisation of the Energy Industry -- 6.1 Development of Balancing in the Energy System Using the Example of Electricity -- 6.2 Current Balancing for Electricity, Gas and Heat Markets -- 6.2.1 Basics of Energy Balancing Using the Example of Electricity -- 6.2.2 Metering Point Operation: Role of the Smart Meter Rollout -- 6.2.3 Market Communication and Measurement Data Analysis -- 6.2.4 Balancing: Comparison Between Gas and Electricity -- 6.3 Role of ICT and Other Innovations in the System Management (Electricity) of the Future -- Literature -- 7: Perspectives of the General Energy System (GES) -- 7.1 Introduction -- 7.2 European Perspective -- 7.3 China Perspective -- 7.4 USA Perspective -- 7.5 Building a Sustainable Hydrogen Economy (Example EU/Germany) -- 7.5.1 Introduction -- 7.5.2 Concept for Germany -- 7.5.3 Regional Concepts Using the Example of the Land of Saxony-Anhalt References -- Appendix -- Conversion Chains (Energy Conversion Chains) of the Selected Processes (Table A.1) Interconnected electric utility systems
title	Sector Coupling - Energy-Sustainable Economy of the Future Fundamentals, Model and Planning Example of a General Energy System (GES)
title_auth	Sector Coupling - Energy-Sustainable Economy of the Future Fundamentals, Model and Planning Example of a General Energy System (GES)
title_exact_search	Sector Coupling - Energy-Sustainable Economy of the Future Fundamentals, Model and Planning Example of a General Energy System (GES)
title_full	Sector Coupling - Energy-Sustainable Economy of the Future Fundamentals, Model and Planning Example of a General Energy System (GES)
title_fullStr	Sector Coupling - Energy-Sustainable Economy of the Future Fundamentals, Model and Planning Example of a General Energy System (GES)
title_full_unstemmed	Sector Coupling - Energy-Sustainable Economy of the Future Fundamentals, Model and Planning Example of a General Energy System (GES)
title_short	Sector Coupling - Energy-Sustainable Economy of the Future
title_sort	sector coupling energy sustainable economy of the future fundamentals model and planning example of a general energy system ges
title_sub	Fundamentals, Model and Planning Example of a General Energy System (GES)
topic	Interconnected electric utility systems
topic_facet	Interconnected electric utility systems
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