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Electrical energy efficiency [[electronic resource] ] : technologies and applications / / [edited by] Andreas Sumper, Angelo Baggini
| Electrical energy efficiency [[electronic resource] ] : technologies and applications / / [edited by] Andreas Sumper, Angelo Baggini |
| Pubbl/distr/stampa | Chichester [England] ; ; Hoboken, N.J., : Wiley, 2012 |
| Descrizione fisica | 1 online resource (420 p.) |
| Disciplina | 621.31 |
| Altri autori (Persone) |
BagginiAngelo B
SumperAndreas |
| Soggetto topico |
Electric power - Conservation - Standards
Energy conservation - Standards Energy dissipation Electric power transmission - Reliability |
| ISBN |
1-119-94206-3
1-280-59079-3 9786613620620 1-119-99004-1 1-119-99005-X |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Machine generated contents note: 1 - OVERVIEW ON STANDARDISATION ON ENERGY EFFICIENCY Franco Bua, Angelo Baggini 1 Introduction 2 Standardisation 2.1 ISO 2.1.1 ISO 50001 2.1.2 ISO/IEC JPC 2 2.2 IEC 2.2.1 SG1 "Energy efficiency and renewable resources" 2.2.2 SG3 "Smart Grid" 2.2.3 SG4 "LVDC distribution systems up to 1 500V DC" 2.3 CEN and CENELEC 2.3.1 SFEM 3. References 2 - CABLES AND LINES Paola Pezzini and Andreas Sumper 2.1. Theory of heat transfer 2.1.1. Conduction 2.1.2. Convection 2.1.3. Radiation 2.2. Current rating of cables installed in free air 2.3. Economical aspects 2.4. Calculation of the current rating: total costs 2.4.1. Evaluation of CJ 2.5. Determination of economic conductor sizes 2.5.1. Economic current range for each conductor in a series of sizes 2.5.2. Economic conductor size for a given load 2.6. Summary References 3 - POWER TRANSFORMERS Roman Targosz, Stefan Fassbinder and Angelo Baggini 1. LOSSES IN TRANSFORMERS 1.1. No-Load losses 1.2. Load losses 1.3. Auxiliary losses 1.4. Extra losses due to harmonics, unbalance and reactive power 1.4.1. Harmonics 1.4.2. Current distortion 1.4.3. Voltage distortion 1.4.4. Mitigation of extra harmonic losses 1.4.5. Unbalance 2. Efficiency and load factor 3. LOSSES AND COOLING SYSTEM 4. ENERGY EFFICIENCY STANDARDS AND REGULATIONS 4.1.1. MEPS 4.1.2. Mandatory Labeling 4.1.3. Voluntary Programs 5. LIFE CYCLE COSTING 5.1. Life cycle cost of transformers 5.2. Detailed considerations 6. DESIGN, MATERIAL AND MANUFACTORING 6.1. Core 6.1.1. Cold rolled grain oriented and HIB magnetic steel 6.1.2. Amorphous steel 6.2. Windings 6.2.1. Superconducting (high temperature, HTS) 6.3. Other developments 6.3.1. Gas insulated transformers 7. CASE STUDY - EVALUATION TOC OF AN INDUSTRIAL TRANSFORMER 7.1. Method 7.2. Results 8. References 9. ANNEX 9.1. Selected MEPS 9.1.1. Australia 9.1.2. USA 9.1.3. Europe 9.1.4. Market figures 9.1.5. Formulas for losses evaluation - American and European 4 - BUILDING AUTOMATION, SUPERVISION, MONITORING AND CONTROL Angelo Baggini, Annalisa Marra 1. Automation functions for energy savings 1.1. Temperature control 1.2. Ligthing 1.3. Drives and motors 1.4. Technical alarms and management 1.5. Remote control 2. Automation systems 2.1. KNX systems 2.1.1. Architecture 2.1.2. Trasmission media 2.1.3. Power Line 2.1.4. Radio wawes 2.1.5. Ethernet 2.1.6. Configuration 2.1.7. Scada systems 2.2. Human Machine Interface 2.2.1. Remote Terminal Unit (RTU) 2.2.2. Supervisory Station 2.2.3. Communication infrastructure and methods 3. Automation device own consumption 4. Basic schemes 4.1. Heating and cooling 4.1.1. Automatic control of every room with thermostatically controlled valves or electronic regulator 4.1.2. Control of water temperature with compensated supply temperature depending on the outside temperature 4.1.3. On / Off Control of distribution pump 4.1.4. Automatic Control Function with a fixed time program 4.1.5. Partial interlock (depending on the HVAC system) 4.1.6. Function of automatic control of any room with communication between the regulators and toward the system BUS 4.1.7. Control of internal temperature 4.1.8. Control of the distribution pumps at a variable speed with AP constant 4.1.9. Automatic control with optimized start /stop 4.1.10. Function of integrated control of all local with management of requests 4.1.11. Function of total Interlock 4.2. Ventilation and air conditioning 4.2.1. Time control 4.2.2. Time on / off control 4.2.3. Defrost control with heat recovery 4.2.4. Control function of the overheating of heat recovery 4.2.5. Night cooling 4.2.6. Constant set point control 4.2.7. Humidity Limitation of the flow air 4.2.8. Automatic control of pressure or flow 4.2.9. Free cooling 4.2.10. Set point external temperature-dependent 4.2.11. Control function of flow air humidity 4.2.12. Presence Control Function 4.2.13. Function to set point, load-dependent 4.3. Lighting 4.3.1. Function of switch on manual and automatic shut-off 4.3.2. Manual Power Control Function and presence detection Auto-On/reduction/Off 4.3.3. Motorized control with automatic drive control of the sunscreens 4.3.4. Automatic daylight control function 4.4. Sunscreens 4.4.1. Control combined light / blinds / HVAC Function 4.5. Technical building management 4.5.1. Function centralized control 4.6. Technical installations in the building 4.6.1. Function of fault detection, diagnosis and provision of technical support 4.6.2. Function of the report on energy use, internal conditions and possibilities for improvement 5. The estimate of building energy performance 5.1. European Standard EN 15232 5.1.1. Automation Classes for energy efficiency 5.1.2. Definition of automation Classes 5.2. Methods comparison: detailed and of the factors 5.2.1. Detailed calculation 6. References 5 - POWER QUALITY PHENOMENA AND INDICATORS Andrei Cziker, Zbigniew Hanzelka, Ireana Wasiak 5.1. RMS voltage level 5.1.1. Sources 5.1.2. Effects on energy efficiency 5.1.3. Mitigation methods 5.2. Voltage fluctuations 5.2.1. Disturbance description 5.2.2. Sources of voltage fluctuations 5.2.3. Effects and cost 5.2.4. Mitigation methods 5.3. Voltage and current unbalance 5.3.1. Disturbance description 5.3.2. Sources 5.3.3. Effect and cost 5.3.4. Mitigation methods 5.4. Voltage and current distortion 5.4.1. Disturbance description 5.4.2. Sources 5.4.3 Effects and cost REFERENCES 6 - ON SITE GENERATION AND MICROGRIDS Irena Wasiak and Zbigniew Hanzelka 6.1. Introduction 6.2. Technologies of distributed energy resources 6.2.1. Energy sources 6.2.2. Energy storage 6.3. Impact of DG on power losses in distribution networks 6.4. Microgrids 6.4.1. Concept 6.4.2. Energy storage applications 6.4.3. Management and control 6.4.4. Power quality and reliability in microgrids References 7 - ELECTRIC MOTORS Joris Lemmens, Wim Deprez 7.1 Losses in electric motors 7.1.1 Power balance and energy efficiency 7.1.2 Loss components classification 7.1.3 Influence factors 7.2 Motor efficiency standards 7.2.1 Efficiency classification standards 7.2.2 Efficiency measurement standards 7.2.3 Future standard for variable speed drives 7.3 High efficiency motor technology 7.3.1 Motor Materials 7.3.2 Motor Design 7.3.3 Motor Manufacturing References 8 - LIGHTING Mircea Chindris, Antoni Sudria-Andreu 8.1. Energy and lighting systems 8.1.1. Energy consumption in lighting systems 8.1.2. Energy efficiency in lighting systems 8.2. Regulations 8.3. Technological advances in lighting systems 8.3.1. Efficient light sources 8.3.2. Efficient ballasts 8.3.3. Efficient luminaries 8.4. Energy efficiency in indoor lighting systems 8.4.1. Policy actions to support energy efficiency 8.4.2. Retrofit or redesign? 8.4.3. Lighting controls 8.4.4. Daylighting 8.5. Energy efficiency in outdoor lighting systems 8.5.1. Efficient lamps and luminaires 8.5.2. Outdoor lighting controls 8.6. Maintenance of lighting systems References 9 - ELECTRICAL DRIVES AND POWER ELECTRONICS Daniel Montesinos-Miracle, Joan Bergas-Jane; and Edris Pouresmaeil 9.1. Control methods for induction motors and PMSM 9.1.1. V/f control 9.1.2. Vector control 9.1.3. DTC 9.2. Energy optimal control methods 9.2.1. Converter losses 9.2.2. Motor losses 9.2.3. Energy optimal control strategies 9.3. Topology of the variable speed drive 9.3.1. Input stage 9.3.2. DC bus 9.3.3. The inverter 9.4. New trends on power semiconductors 9.4.1. Modulation Techniques 9.4.2. Review of different modulation methods. 9.4.3. Multilevel inverter topologies References 10 - INDUSTRIAL HEATING PROCESSES Mircea Chindris, Andreas Sumper 10.1. General aspects regarding electroheating in industry 10.2. Main electroheating technologies 10.2.1. Resistance Heating 10.2.2. Infrared Heating 10.2.3. Induction Heating 10.2.4. Dielectric Heating 10.2.5. Arc furnaces 10.3. Specific aspects regarding the increase of energy efficiency in industrial heating processes 10.3.1. Replacement of traditional heating technologies.
10.3.2. Selection of the most suitable electrotechnology 10.3.3. Increasing the efficiency of the existing electroheating equipment REFERENCES 11- HEAT, VENTILATION AND AIR CONDITIONING (HVAC) Roberto Villafa |
| Record Nr. | UNINA-9910141291503321 |
| Chichester [England] ; ; Hoboken, N.J., : Wiley, 2012 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Electrical energy efficiency : technologies and applications / / [edited by] Andreas Sumper, Angelo Baggini
| Electrical energy efficiency : technologies and applications / / [edited by] Andreas Sumper, Angelo Baggini |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Chichester [England] ; ; Hoboken, N.J., : Wiley, 2012 |
| Descrizione fisica | 1 online resource (420 p.) |
| Disciplina | 621.31 |
| Altri autori (Persone) |
BagginiAngelo B
SumperAndreas |
| Soggetto topico |
Electric power - Conservation - Standards
Energy conservation - Standards Energy dissipation Electric power transmission - Reliability |
| ISBN |
1-119-94206-3
1-280-59079-3 9786613620620 1-119-99004-1 1-119-99005-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Machine generated contents note: 1 - OVERVIEW ON STANDARDISATION ON ENERGY EFFICIENCY Franco Bua, Angelo Baggini 1 Introduction 2 Standardisation 2.1 ISO 2.1.1 ISO 50001 2.1.2 ISO/IEC JPC 2 2.2 IEC 2.2.1 SG1 "Energy efficiency and renewable resources" 2.2.2 SG3 "Smart Grid" 2.2.3 SG4 "LVDC distribution systems up to 1 500V DC" 2.3 CEN and CENELEC 2.3.1 SFEM 3. References 2 - CABLES AND LINES Paola Pezzini and Andreas Sumper 2.1. Theory of heat transfer 2.1.1. Conduction 2.1.2. Convection 2.1.3. Radiation 2.2. Current rating of cables installed in free air 2.3. Economical aspects 2.4. Calculation of the current rating: total costs 2.4.1. Evaluation of CJ 2.5. Determination of economic conductor sizes 2.5.1. Economic current range for each conductor in a series of sizes 2.5.2. Economic conductor size for a given load 2.6. Summary References 3 - POWER TRANSFORMERS Roman Targosz, Stefan Fassbinder and Angelo Baggini 1. LOSSES IN TRANSFORMERS 1.1. No-Load losses 1.2. Load losses 1.3. Auxiliary losses 1.4. Extra losses due to harmonics, unbalance and reactive power 1.4.1. Harmonics 1.4.2. Current distortion 1.4.3. Voltage distortion 1.4.4. Mitigation of extra harmonic losses 1.4.5. Unbalance 2. Efficiency and load factor 3. LOSSES AND COOLING SYSTEM 4. ENERGY EFFICIENCY STANDARDS AND REGULATIONS 4.1.1. MEPS 4.1.2. Mandatory Labeling 4.1.3. Voluntary Programs 5. LIFE CYCLE COSTING 5.1. Life cycle cost of transformers 5.2. Detailed considerations 6. DESIGN, MATERIAL AND MANUFACTORING 6.1. Core 6.1.1. Cold rolled grain oriented and HIB magnetic steel 6.1.2. Amorphous steel 6.2. Windings 6.2.1. Superconducting (high temperature, HTS) 6.3. Other developments 6.3.1. Gas insulated transformers 7. CASE STUDY - EVALUATION TOC OF AN INDUSTRIAL TRANSFORMER 7.1. Method 7.2. Results 8. References 9. ANNEX 9.1. Selected MEPS 9.1.1. Australia 9.1.2. USA 9.1.3. Europe 9.1.4. Market figures 9.1.5. Formulas for losses evaluation - American and European 4 - BUILDING AUTOMATION, SUPERVISION, MONITORING AND CONTROL Angelo Baggini, Annalisa Marra 1. Automation functions for energy savings 1.1. Temperature control 1.2. Ligthing 1.3. Drives and motors 1.4. Technical alarms and management 1.5. Remote control 2. Automation systems 2.1. KNX systems 2.1.1. Architecture 2.1.2. Trasmission media 2.1.3. Power Line 2.1.4. Radio wawes 2.1.5. Ethernet 2.1.6. Configuration 2.1.7. Scada systems 2.2. Human Machine Interface 2.2.1. Remote Terminal Unit (RTU) 2.2.2. Supervisory Station 2.2.3. Communication infrastructure and methods 3. Automation device own consumption 4. Basic schemes 4.1. Heating and cooling 4.1.1. Automatic control of every room with thermostatically controlled valves or electronic regulator 4.1.2. Control of water temperature with compensated supply temperature depending on the outside temperature 4.1.3. On / Off Control of distribution pump 4.1.4. Automatic Control Function with a fixed time program 4.1.5. Partial interlock (depending on the HVAC system) 4.1.6. Function of automatic control of any room with communication between the regulators and toward the system BUS 4.1.7. Control of internal temperature 4.1.8. Control of the distribution pumps at a variable speed with AP constant 4.1.9. Automatic control with optimized start /stop 4.1.10. Function of integrated control of all local with management of requests 4.1.11. Function of total Interlock 4.2. Ventilation and air conditioning 4.2.1. Time control 4.2.2. Time on / off control 4.2.3. Defrost control with heat recovery 4.2.4. Control function of the overheating of heat recovery 4.2.5. Night cooling 4.2.6. Constant set point control 4.2.7. Humidity Limitation of the flow air 4.2.8. Automatic control of pressure or flow 4.2.9. Free cooling 4.2.10. Set point external temperature-dependent 4.2.11. Control function of flow air humidity 4.2.12. Presence Control Function 4.2.13. Function to set point, load-dependent 4.3. Lighting 4.3.1. Function of switch on manual and automatic shut-off 4.3.2. Manual Power Control Function and presence detection Auto-On/reduction/Off 4.3.3. Motorized control with automatic drive control of the sunscreens 4.3.4. Automatic daylight control function 4.4. Sunscreens 4.4.1. Control combined light / blinds / HVAC Function 4.5. Technical building management 4.5.1. Function centralized control 4.6. Technical installations in the building 4.6.1. Function of fault detection, diagnosis and provision of technical support 4.6.2. Function of the report on energy use, internal conditions and possibilities for improvement 5. The estimate of building energy performance 5.1. European Standard EN 15232 5.1.1. Automation Classes for energy efficiency 5.1.2. Definition of automation Classes 5.2. Methods comparison: detailed and of the factors 5.2.1. Detailed calculation 6. References 5 - POWER QUALITY PHENOMENA AND INDICATORS Andrei Cziker, Zbigniew Hanzelka, Ireana Wasiak 5.1. RMS voltage level 5.1.1. Sources 5.1.2. Effects on energy efficiency 5.1.3. Mitigation methods 5.2. Voltage fluctuations 5.2.1. Disturbance description 5.2.2. Sources of voltage fluctuations 5.2.3. Effects and cost 5.2.4. Mitigation methods 5.3. Voltage and current unbalance 5.3.1. Disturbance description 5.3.2. Sources 5.3.3. Effect and cost 5.3.4. Mitigation methods 5.4. Voltage and current distortion 5.4.1. Disturbance description 5.4.2. Sources 5.4.3 Effects and cost REFERENCES 6 - ON SITE GENERATION AND MICROGRIDS Irena Wasiak and Zbigniew Hanzelka 6.1. Introduction 6.2. Technologies of distributed energy resources 6.2.1. Energy sources 6.2.2. Energy storage 6.3. Impact of DG on power losses in distribution networks 6.4. Microgrids 6.4.1. Concept 6.4.2. Energy storage applications 6.4.3. Management and control 6.4.4. Power quality and reliability in microgrids References 7 - ELECTRIC MOTORS Joris Lemmens, Wim Deprez 7.1 Losses in electric motors 7.1.1 Power balance and energy efficiency 7.1.2 Loss components classification 7.1.3 Influence factors 7.2 Motor efficiency standards 7.2.1 Efficiency classification standards 7.2.2 Efficiency measurement standards 7.2.3 Future standard for variable speed drives 7.3 High efficiency motor technology 7.3.1 Motor Materials 7.3.2 Motor Design 7.3.3 Motor Manufacturing References 8 - LIGHTING Mircea Chindris, Antoni Sudria-Andreu 8.1. Energy and lighting systems 8.1.1. Energy consumption in lighting systems 8.1.2. Energy efficiency in lighting systems 8.2. Regulations 8.3. Technological advances in lighting systems 8.3.1. Efficient light sources 8.3.2. Efficient ballasts 8.3.3. Efficient luminaries 8.4. Energy efficiency in indoor lighting systems 8.4.1. Policy actions to support energy efficiency 8.4.2. Retrofit or redesign? 8.4.3. Lighting controls 8.4.4. Daylighting 8.5. Energy efficiency in outdoor lighting systems 8.5.1. Efficient lamps and luminaires 8.5.2. Outdoor lighting controls 8.6. Maintenance of lighting systems References 9 - ELECTRICAL DRIVES AND POWER ELECTRONICS Daniel Montesinos-Miracle, Joan Bergas-Jane; and Edris Pouresmaeil 9.1. Control methods for induction motors and PMSM 9.1.1. V/f control 9.1.2. Vector control 9.1.3. DTC 9.2. Energy optimal control methods 9.2.1. Converter losses 9.2.2. Motor losses 9.2.3. Energy optimal control strategies 9.3. Topology of the variable speed drive 9.3.1. Input stage 9.3.2. DC bus 9.3.3. The inverter 9.4. New trends on power semiconductors 9.4.1. Modulation Techniques 9.4.2. Review of different modulation methods. 9.4.3. Multilevel inverter topologies References 10 - INDUSTRIAL HEATING PROCESSES Mircea Chindris, Andreas Sumper 10.1. General aspects regarding electroheating in industry 10.2. Main electroheating technologies 10.2.1. Resistance Heating 10.2.2. Infrared Heating 10.2.3. Induction Heating 10.2.4. Dielectric Heating 10.2.5. Arc furnaces 10.3. Specific aspects regarding the increase of energy efficiency in industrial heating processes 10.3.1. Replacement of traditional heating technologies.
10.3.2. Selection of the most suitable electrotechnology 10.3.3. Increasing the efficiency of the existing electroheating equipment REFERENCES 11- HEAT, VENTILATION AND AIR CONDITIONING (HVAC) Roberto Villafa |
| Record Nr. | UNINA-9910816557203321 |
| Chichester [England] ; ; Hoboken, N.J., : Wiley, 2012 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Energy storage in power systems / / Francisco Diaz-Gonzalez, Andreas Sumper, Oriol Gomis-Bellmunt
| Energy storage in power systems / / Francisco Diaz-Gonzalez, Andreas Sumper, Oriol Gomis-Bellmunt |
| Autore | Díaz-González Francisco |
| Pubbl/distr/stampa | Chichester, [England] : , : Wiley, , 2016 |
| Descrizione fisica | 1 online resource (311 p.) |
| Disciplina | 621.31/26 |
| Soggetto topico |
Energy storage
Electric power systems - Reliability Peak load |
| ISBN |
1-118-97130-2
1-118-97131-0 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
ENERGY STORAGE IN POWER SYSTEMS; Contents; Foreword; Preface; 1 An Introduction to Modern Power Systems; 1.1 Introduction; 1.2 The Smart Grid Architecture Model; 1.3 The Electric Power System; 1.3.1 The Structure of the Power System; 1.3.2 The Fundamentals of Power System Analysis; 1.4 Energy Management Systems; 1.5 Computational Techniques; 1.5.1 Optimization Methods and Optimal Power Flow; 1.5.2 Security-Constrained Optimal Power Flow; 1.6 Microgrids; 1.7 The Regulation of the Electricity System and the Electrical Markets; 1.8 Exercise: A Load-Flow Algorithm with Gauss-Seidel
2 Generating Systems Based on Renewable Power 2.1 Renewable Power Systems; 2.1.1 Wind Power Systems; 2.1.2 Solar Photovoltaic Power Systems; 2.2 Renewable Power Generation Technologies; 2.2.1 Renewable Power Generation Technology Based on Rotative Electrical Generators; 2.2.2 Wind Turbine Technology; 2.2.3 Photovoltaic Power Plants; 2.3 Grid Code Requirements; 2.4 Conclusions; 3 Frequency Support Grid Code Requirements for Wind Power Plants; 3.1 A Review of European Grid Codes Regarding Participation in Frequency Control; 3.1.1 Nomenclature and the Definition of Power Reserves 3.1.2 The Deployment Sequence of Power Reserves for Frequency Control 3.1.3 A Detailed View on the Requirements for WPPs in the Irish Grid Code; 3.1.4 A Detailed View on the Requirements for WPPs in the UK Grid Code; 3.1.5 Future Trends Regarding the Provision of Primary Reserves and Synthetic Inertia by WPPs; 3.2 Participation Methods for WPPs with Regard to Primary Frequency Control and Synthetic Inertia; 3.2.1 Deloading Methods of Wind Turbines for Primary Frequency Control; 3.2.2 Synthetic Inertia; 3.3 Conclusions; 4 Energy Storage Technologies; 4.1 Introduction 4.2 The Description of the Technology 4.2.1 Pumped Hydroelectric Storage (PHS); 4.2.2 Compressed Air Energy Storage (CAES); 4.2.3 Conventional Batteries and Flow Batteries; 4.2.4 The Hydrogen-Based Energy Storage System (HESS); 4.2.5 The Flywheel Energy Storage System (FESS); 4.2.6 Superconducting Magnetic Energy Storage (SMES); 4.2.7 The Supercapacitor Energy Storage System; 4.2.8 Notes on Other Energy Storage Systems; 4.3 Power Conversion Systems for Electrical Storage; 4.3.1 Application: Electric Power Systems; 4.3.2 Other Applications I: The Field of Electromobility 4.3.3 Other Applications II: Buildings 4.3.4 The Battery Management System (BMS); 4.4 Conclusions; 5 Cost Models and Economic Analysis; 5.1 Introduction; 5.2 A Cost Model for Storage Technologies; 5.2.1 The Capital Costs; 5.2.2 Operating and Maintenance Costs; 5.2.3 Replacement Costs; 5.2.4 End-of-Life Costs; 5.2.5 The Synthesis of a Cost Model; 5.3 An Example of an Application; 5.3.1 The Collection of Data for Evaluation of the Cost Model; 5.3.2 Analysis of the Results; 5.4 Conclusions; 6 Modeling, Control, and Simulation; 6.1 Introduction 6.2 Modeling of Storage Technologies: A General Approach Orientated to Simulation Objectives |
| Record Nr. | UNINA-9910136351803321 |
Díaz-González Francisco
|
||
| Chichester, [England] : , : Wiley, , 2016 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Energy storage in power systems / / Francisco Diaz-Gonzalez, Andreas Sumper, Oriol Gomis-Bellmunt
| Energy storage in power systems / / Francisco Diaz-Gonzalez, Andreas Sumper, Oriol Gomis-Bellmunt |
| Autore | Díaz-González Francisco |
| Pubbl/distr/stampa | Chichester, [England] : , : Wiley, , 2016 |
| Descrizione fisica | 1 online resource (311 p.) |
| Disciplina | 621.31/26 |
| Soggetto topico |
Energy storage
Electric power systems - Reliability Peak load |
| ISBN |
1-118-97130-2
1-118-97131-0 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
ENERGY STORAGE IN POWER SYSTEMS; Contents; Foreword; Preface; 1 An Introduction to Modern Power Systems; 1.1 Introduction; 1.2 The Smart Grid Architecture Model; 1.3 The Electric Power System; 1.3.1 The Structure of the Power System; 1.3.2 The Fundamentals of Power System Analysis; 1.4 Energy Management Systems; 1.5 Computational Techniques; 1.5.1 Optimization Methods and Optimal Power Flow; 1.5.2 Security-Constrained Optimal Power Flow; 1.6 Microgrids; 1.7 The Regulation of the Electricity System and the Electrical Markets; 1.8 Exercise: A Load-Flow Algorithm with Gauss-Seidel
2 Generating Systems Based on Renewable Power 2.1 Renewable Power Systems; 2.1.1 Wind Power Systems; 2.1.2 Solar Photovoltaic Power Systems; 2.2 Renewable Power Generation Technologies; 2.2.1 Renewable Power Generation Technology Based on Rotative Electrical Generators; 2.2.2 Wind Turbine Technology; 2.2.3 Photovoltaic Power Plants; 2.3 Grid Code Requirements; 2.4 Conclusions; 3 Frequency Support Grid Code Requirements for Wind Power Plants; 3.1 A Review of European Grid Codes Regarding Participation in Frequency Control; 3.1.1 Nomenclature and the Definition of Power Reserves 3.1.2 The Deployment Sequence of Power Reserves for Frequency Control 3.1.3 A Detailed View on the Requirements for WPPs in the Irish Grid Code; 3.1.4 A Detailed View on the Requirements for WPPs in the UK Grid Code; 3.1.5 Future Trends Regarding the Provision of Primary Reserves and Synthetic Inertia by WPPs; 3.2 Participation Methods for WPPs with Regard to Primary Frequency Control and Synthetic Inertia; 3.2.1 Deloading Methods of Wind Turbines for Primary Frequency Control; 3.2.2 Synthetic Inertia; 3.3 Conclusions; 4 Energy Storage Technologies; 4.1 Introduction 4.2 The Description of the Technology 4.2.1 Pumped Hydroelectric Storage (PHS); 4.2.2 Compressed Air Energy Storage (CAES); 4.2.3 Conventional Batteries and Flow Batteries; 4.2.4 The Hydrogen-Based Energy Storage System (HESS); 4.2.5 The Flywheel Energy Storage System (FESS); 4.2.6 Superconducting Magnetic Energy Storage (SMES); 4.2.7 The Supercapacitor Energy Storage System; 4.2.8 Notes on Other Energy Storage Systems; 4.3 Power Conversion Systems for Electrical Storage; 4.3.1 Application: Electric Power Systems; 4.3.2 Other Applications I: The Field of Electromobility 4.3.3 Other Applications II: Buildings 4.3.4 The Battery Management System (BMS); 4.4 Conclusions; 5 Cost Models and Economic Analysis; 5.1 Introduction; 5.2 A Cost Model for Storage Technologies; 5.2.1 The Capital Costs; 5.2.2 Operating and Maintenance Costs; 5.2.3 Replacement Costs; 5.2.4 End-of-Life Costs; 5.2.5 The Synthesis of a Cost Model; 5.3 An Example of an Application; 5.3.1 The Collection of Data for Evaluation of the Cost Model; 5.3.2 Analysis of the Results; 5.4 Conclusions; 6 Modeling, Control, and Simulation; 6.1 Introduction 6.2 Modeling of Storage Technologies: A General Approach Orientated to Simulation Objectives |
| Record Nr. | UNINA-9910828183803321 |
|
Díaz-González Francisco
|
||
| Chichester, [England] : , : Wiley, , 2016 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Micro and local power markets / / edited by Andreas Sumper
| Micro and local power markets / / edited by Andreas Sumper |
| Autore | Sumper Andreas |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, , [2019] |
| Descrizione fisica | 1 online resource (234 pages) |
| Disciplina | 333.79320688 |
| Soggetto topico |
Electric power - Marketing
Electric utilities Microgrids (Smart power grids) Energy policy Interconnected electric utility systems |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-119-43456-4
1-119-43457-2 1-119-43454-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910555129903321 |
|
Sumper Andreas
|
||
| Hoboken, New Jersey : , : Wiley, , [2019] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Micro and local power markets / / edited by Andreas Sumper
| Micro and local power markets / / edited by Andreas Sumper |
| Autore | Sumper Andreas |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, , [2019] |
| Descrizione fisica | 1 online resource (234 pages) |
| Disciplina | 333.79320688 |
| Soggetto topico |
Electric power - Marketing
Electric utilities Microgrids (Smart power grids) Energy policy Interconnected electric utility systems |
| ISBN |
1-119-43456-4
1-119-43457-2 1-119-43454-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Power market fundamentals / Ingrid Munne-Collado, Pol Olivella-Rosell and Andreas Sumper -- Local and micro power markets / Ingrid Munn-Collado, Eduard Bullich-Massaguo, Monica Aragüos-Peñalba and Pol Olivella-Rosell -- Micromarket in microgrids / Bernt Bremdal and Iliana Ilieva. |
| Record Nr. | UNINA-9910830667703321 |
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Sumper Andreas
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| Hoboken, New Jersey : , : Wiley, , [2019] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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