Power Electronic Converters and Systems: Applications (Energy Engineering)

✍ Scribed by Marcelo Godoy Simões (editor), Tiago Davi Curi Busarello (editor)

Publisher: The Institution of Engineering and Technology
Year: 2024
Tongue: English
Leaves: 538
Edition: 2
Category: Library

No coin nor oath required. For personal study only.

✦ Synopsis

Power electronics is a field in constant evolution. Power grids require further developments, and the overall society electrification requires enhanced power electronics and motor drives. New semiconductor wide bandgap devices and modern implementation hardware software play a key role, power converters for the direct current and alternating current electrical conversion, for changing voltage or frequency have become integrated with layers of communication, control, and information processing.

This expanded 2nd edition of Power Electronic Converters and Systems offers an update in two volumes, with a systematic revision of all chapters plus all-new chapters. An overview of modern power electronic converters and systems is provided, and their applications explored. Devices covered include semiconductor switches, various converters, switching power supplies, and smart power electronic modules. Applications approach unique motors and induction motor drives, renewable energy, distribution and microgrids, automotive and shipboard power systems and wireless power transfer, as well as advanced control.

In volume one, chapters cover semiconductor power devices, multilevel and multi-input converters, modular multilevel cascade and matrix converters, soft-switching, source power, and DC/DC converters, smart power electronics, motor drives, switched reluctance machines, reliability in power electronics and hardware-in-the-loop.

In volume two, chapters cover wind and PV energy principles, charging and battery management, DC-DC switched capacitor converters, batteries, shipboard power systems, advanced control and power filter control, more electric aircraft, fault ride through strategies for grid-connected PV, support functions and grid-forming control.

Both volumes offer key insights and up-to-date information for researchers and practicing engineers working in power electronics, converters and machine drives, electric vehicles, ship propulsion, battery storage, wind and photovoltaics solar energy and power conversion.

✦ Table of Contents

Cover
Contents
About the editors
Foreword
15 Hardware-in-the-Loop technology and applications in power electronics
15.1 Introduction
15.2 Real-time simulators
15.3 Principle of operation and benefits of HIL setups
15.4 Where to use HIL in a research
15.5 Recent publications of research using HIL technology
15.6 Fidelity versus coverage
15.7 C-HIL setup applications
15.7.1 LCL-filtered grid-connected inverter with digital proportional-resonant current controller
15.7.2 Single-phase full-bridge series active filter
15.7.3 Field-oriented control of interior permanent magnet synchronous machines
15.8 Conclusions
References
16 Wind energy systems
16.1 Introduction
16.2 Wind power technologies
16.2.1 Current standard speed controls for WECS
16.2.2 Concepts of power electronic converters for WECS
16.2.3 Types of generators for wind turbines
16.2.3.1 Squirrel cage induction generator (SCIG)
16.2.3.2 Wound rotor induction generator (WRIG)
16.2.3.3 Doubly fed induction generator (DFIG)
16.2.3.4 Wound rotor synchronous generator (WRSG)
16.2.3.5 Permanent magnet synchronous generator (PMSG)
16.3 Power electronic interfaces for variable speed wind turbines
16.3.1 Conventional power electronic blocks
16.3.2 Ordinary power electronic converters for wind turbines
16.3.3 Emerging power electronic converters for wind turbines
16.3.4 Power electronic converters for high-power wind turbines
16.4 WT control algorithms for power electronic converters
16.4.1 Maximum power point tracking (MPPT)
16.4.2 Control by maximizing the power coefficient (Cp)
16.5 Generator-side converter control
16.5.1 Control for DC/DC boost converters
16.5.2 Control for impedance source converters
16.5.3 Field-oriented control (FOC)
16.5.4 Direct torque control space vector modulated (DTC-SVM)
16.6 Grid-side converter control
16.6.1 Voltage-oriented control (VOC)
16.6.2 Direct power control—space vector modulated (DPC—SVM)
16.6.3 Single-phase grid converter control
16.7 Operating control in a stand-alone mode
16.7.1 Electronic droop control
16.7.2 Electronic speed and voltage control by the load
16.7.3 Design of an electronic speed and voltage control by the load
16.7.4 Load selection for an electronic speed and voltage control
16.8 Conclusions
References
17 Photovoltaic energy systems
17.1 Introduction
17.1.1 A brief overview of PV generation
17.1.2 PV inverter circuit
17.1.3 Centralized PV plant
17.2 The technologies
17.2.1 State-of-the-art technologies
17.2.1.1 Power semiconductors
17.2.1.2 Inverter topology
17.2.1.3 Inverter control
17.2.2 Reliability
17.2.2.1 Accelerated aging commonality and underlying physics
17.2.2.2 Power device reliability
17.2.2.3 Field distortion acceleration model
17.2.2.4 Dominant failure mechanisms
17.3 The grid interface
17.3.1 Basic control of real and reactive power in a two-bus power system
17.3.1.1 Reactive power
17.3.1.2 Real power
17.4 The standards
17.4.1 Protection
17.4.1.1 Over/under voltage
17.4.2 Islanding
17.4.2.1 Over/short circuit current
17.4.2.2 Over/under frequency
17.4.2.3 Reconnect after grid failure and restoration
17.4.3 Power quality
17.4.3.1 Current harmonics and inter-harmonics
17.4.3.2 Voltage unbalance
17.4.3.3 Injection of DC into the AC system
17.4.3.4 Flicker and fluctuations
17.4.4 Ancillary services
17.4.4.1 Network voltage support
17.4.4.2 Frequency support
17.4.5 Update of the IEEE 1547 2018
17.5 The field measurements
17.5.1 Intermittence in solar field results
17.5.2 LVRT test results of the 500-kW RX series
17.6 Conclusions
References
18 Advanced charging and battery management systems for E-mobility
18.1 Introduction
18.2 Electric vehicle (EV) batteries
18.2.1 Important characteristics of battery chemistries
18.2.2 Battery parameters
18.2.3 Basic requirements of EV/PHEV batteries
18.2.4 Charging, termination, and cell-balancing techniques and SOC estimation
18.2.4.1 EV battery charging methods
18.2.4.2 Cell balancing
18.2.4.3 State estimation
18.2.5 Thermal management
18.2.5.1 Battery health and thermal management
18.2.5.2 Digital twin–based BMS and TMS
18.3 EV charging
18.3.1 Plugged charging
18.3.1.1 EV normal charging standards
18.3.1.2 DC fast charging converter topologies
18.3.2 EV fast charging standards
18.3.2.1 CHAdeMO DC fast charging
18.3.2.2 Chinese GB DC fast charging standard
18.4 Wireless charging
18.4.1 Types of wireless charging
18.4.2 Necessity of compensation for wireless charging
18.4.3 Analysis of series–series topology
18.4.4 Analysis of series–parallel topology
18.4.5 Peak efficiency of series–series and series–parallel topology
18.4.6 Control strategies for SS and SP topology
18.4.7 Advantages of EV wireless charging
18.5 Battery swapping
18.5.1 Advantages of battery swapping
18.6 Conclusions
References
19 Design and control of DC–DC switched capacitor converters
19.1 Introduction
19.2 Derivation, classification and evaluation of DC–DC converter topology based on impedance network
19.3 Topology design and of DC–DC converter
19.3.1 Topology configuration and operating principles
19.3.2 Topology voltage analysis
19.3.3 Parameter selection
19.4 Control system modelling and controller design of DC–DC converters
19.4.1 PID control
19.4.2 Robust PID control
19.4.3 Active disturbance rejection control
19.5 Conclusion
References
20 Batteries as an energy source for stationary andmobile applications – overview onbatteryintegration and control
20.1 Introduction
20.2 Introduction to stationary grid-scale BESSapplications
20.3 Classification of stationary BESS grid applications
20.4 Lithium-ion BESS for stationary applications
20.5 Control design of lithium-ion BESS for stationary applications – active network management case
20.5.1 Proposed active network management scheme
20.5.2 Energy management system design for proposed ANM scheme
20.5.2.1 P-Control
20.6 Current and future of EVs market
20.7 Application of batteries in EVs
20.7.1 Types of batteries in EVs
20.7.1.1 Lithium-ion batteries in EVs
20.7.1.2 Nickel–metal hydride batteries in EVs
20.7.1.3 Lead–acid batteries in EVs
20.7.1.4 Solid-state batteries in EVs
20.7.2 EVs battery charging methods
20.8 Energy management and power control of EVs
20.8.1 EVs battery charging operation
20.9 Discussion and results
20.10 Conclusion
References
21 Shipboard power systems
21.1 Introduction
21.2 Power electronic components for power systems
21.2.1 AC drives
21.2.2 Inverter system components
21.2.2.1 Precharging circuit
21.2.2.2 Motor inverters
21.2.2.3 Generator inverters
21.2.2.4 Grid inverters and low harmonic drives
21.2.2.5 DC/DC converters
21.2.2.6 DC breakers
21.2.2.7 Brake chopper units
21.2.2.8 Crowbar
21.3 Shipboard electric grid topologies
21.3.1 Low and medium voltage distribution
21.3.2 AC distribution
21.3.3 AC–DC hybrid distribution
21.3.3.1 Case study – M/S Aurora Botnia
21.3.4 DC distribution
21.3.4.1 Case study – M/F Grotte
21.3.5 Shore connection integration
21.3.5.1 Direct shore connection
21.3.5.2 Inverter-based shore connection
21.3.5.3 Case study – shore connection for M/F Grotte
21.4 Shipboard power electronic system applications
21.4.1 Shaft generators in mechanical propulsion systems
21.4.1.1 Power-take-out (PTO)
21.4.1.2 Power-take-in (PTI)
21.4.2 Electric propulsion systems
21.4.3 Electromechanical hybrid propulsion systems
21.4.4 Energy storage applications
21.4.4.1 Energy storage maintenance functionalities
21.4.5 Fuel cell applications
21.5 Power quality requirements in shipboard systems
21.5.1 Harmonic distortions
21.5.2 Displacement, distortion and true power factors
21.5.2.1 Power factor sign
21.6 Smart ports
21.6.1 Introduction to smart ports
21.6.1.1 Smart ports as microgrids
21.6.2 Cold Ironing as the first practical step towards smartports
21.6.2.1 Cold ironing
21.6.2.2 Ship requirements while berthing
21.6.2.3 Regulations on cold ironing
21.6.2.4 Current ports with cold ironing systems
21.6.3 Shore-to-ship charging systems in smart ports
21.6.3.1 AC charging systems
21.6.3.2 DC charging systems
21.6.3.3 Inductive charging systems
21.7 Concepts for future shipboard power systems
21.7.1 Power distribution
21.7.2 Power generation
21.7.3 Artificial intelligence
21.8 Conclusions
References
22 Distributed generation and microgrids
22.1 Introduction
22.2 Distribution generators
22.2.1 Examples of distributed generators
22.2.1.1 Wind energy-based distributed generators
22.2.1.2 Solar energy-based distributed generators
22.2.1.3 Fuel cell-based distributed generators
22.2.1.4 Diesel generators
22.2.1.5 Microturbines
22.2.1.6 Heat pumps
22.2.2 Technical impacts due to DG
22.2.3 IEEE1547
22.3 Microgrid
22.3.1 DC and AC microgrids
22.3.2 Stand-alone microgrids
22.3.3 Grid-tied microgrids
22.3.4 Centralized control
22.3.5 Conventional droop control method
22.3.6 Local control
22.3.7 Multifunctional inverter-based operation
References
23 Uninterruptible power supplies
23.1 Introduction
23.2 Topologies
23.2.1 On-line UPS systems
23.2.2 Off-line UPS
23.2.3 Line-interactive UPS
23.2.4 Delta conversion UPS
23.2.5 Tri-mode UPS
23.2.6 Rotary UPS
23.2.7 Hybrid static and rotary UPS
23.2.8 Flywheels
23.2.9 DC UPS for pulse load with power leveling
23.2.10 Redundant bus
23.2.11 UPS system with proton exchange membrane fuel cell (PEMFC)
23.3 Controls for UPS systems
23.4 Applications
23.4.1 Desktop personal computers
23.4.2 Industrial systems
23.4.3 Data centers
23.4.4 Medical equipment
23.5 Conclusion
References
24 Wireless charging for electric vehicles
24.1 Introduction
24.2 Inductive power transfer systems
24.2.1 Magnetic coupler system architecture
24.2.1.1 Stationary IPT
24.2.1.2 In-motion IPT
24.2.2 Compensation networks
24.2.3 Converter topologies
24.2.3.1 Transmitter-side conversion
24.2.3.2 Receiver-side converters
24.2.4 State of the art
24.2.4.1 Stationary inductive charging
24.2.4.2 In-motion inductive charging
24.2.5 Challenges and opportunities
24.2.5.1 Implementation
24.2.5.2 Safety concerns
24.2.5.3 Technologies
24.3 Conclusion
References
25 Advanced control of power-electronic systems
25.1 Introduction
25.2 Brief overview of historic advanced nonlinear controllers for PES applications
25.3 Switching-sequence-based control
25.3.1 SBC for standalone PES
25.3.1.1 Description of the SBC scheme
25.3.1.2 Application of SBC to a standalone PES
25.3.2 SBC for networked PESs
25.4 Model predictive control
25.4.1 Description of the MPC scheme
25.4.2 Application of the MPC to a grid-interactive PES
25.4.2.1 MPC formulation of CMI
25.4.2.2 Multiobjective MPC constrained algorithm-based state-of-the-charge of battery cells
25.4.2.3 Performance analysis of constrained multiobjective MPC
25.5 Conclusion
Disclaimer
References
26 Active power filter control methods for power quality improvement in more electric aircraft applications
26.1 Overview of more electric aircraft power system
26.2 Power electronic converters in electric aircraft
26.2.1 AC–DC converters
26.2.2 DC–DC converters
26.2.3 DC–AC converters
26.3 Power quality issues in aircraft systems
26.3.1 Harmonics issues
26.3.2 Power factor correction
26.3.3 Unbalancing issues
26.4 Power quality improvement in more electric aircraft
26.4.1 Principles and configurations of active power filters (APFs)
26.4.2 Other important configurations of APFs
26.4.2.1 Four-leg inverter
26.4.2.2 Multi-level inverters
26.5 Control methodologies for active power filters in more electric aircraft grids
26.5.1 Reference current extraction schemes
26.5.1.1 Time domain schemes
26.5.1.2 Frequency domain schemes
26.5.2 Prominent linear/nonlinear current control methods
26.5.2.1 Hysteresis current control
26.5.2.2 Multiresolution control
26.5.2.3 Iterative learning control (ILC)
26.5.2.4 Deadbeat current control
26.5.2.5 Quasi-proportional-resonant (quasi-PR) current controller
26.5.2.6 Feed forward compensation
26.5.2.7 Repetitive control (RC)
26.5.3 DC link voltage controllers
26.5.3.1 Linear PI controller
26.5.3.2 Nonlinear controllers
26.5.3.3 Artificial intelligence (AI) control
26.5.4 Role of synchronization schemes
26.6 Performance evaluation
26.7 Summary
References
27 An overview on fault ride through strategies for grid-connected photovoltaic system
27.1 Introduction
27.2 FRT requirements
27.2.1 LVRT requirement
27.2.2 HVRT requirement
27.2.3 Other modern grid code requirements
27.3 FRT methods for grid-connected PV system
27.3.1 FRT control capability: an overview
27.3.2 FRT and MPPT strategies
27.3.3 Methods for sag detection
27.4 Overview on various FRT strategies
27.4.1 External devices-based FRT control methods
27.4.1.1 Protection based on braking chopper
27.4.1.2 FRT based on energy storage systems
27.4.1.3 Flexible alternating current transmission system devices
27.4.1.4 Additional methodologies
27.4.2 Improved controller-based approaches
27.4.2.1 Modified inverter controllers
27.4.2.2 Computational approaches
27.4.2.3 Other methods
27.4.3 Comparison of FRT strategies based on technical, complexity, and economic aspects
27.5 External devices-based methods: a case study
27.5.1 Design of FRT strategies
27.5.1.1 Design of conventional crowbar strategy
27.5.1.2 Design of bridge-type fault current limiters
27.5.1.3 Design of switch-type fault current limiters (STFCL)
27.5.2 Proposed model
27.5.3 Performance evaluations
27.6 Discussion
27.7 Conclusion
References
28 Support functions and grid-forming control ongrid connected inverters
28.1 Introduction
28.2 GCI support functions
28.2.1 Volt–VAr and Volt–Watt
28.2.2 Freq–Watt
28.2.3 Watt–VAr
28.2.4 Ride-through
28.2.5 Voltage ride-through
28.2.6 Frequency ride-through
28.3 Overview of grid-forming controllers
28.3.1 Power-synchronisation and voltage amplitude control
28.4 GCI control system design
28.4.1 Converter topology and output filter
28.4.2 Inner voltage-controller design
28.4.3 Power loop design
28.5 Experimental results of a bidirectional DER
28.5.1 BESS implementing the Freq–Watt function
28.5.2 BESS implementing the Volt–VAr function
28.6 Conclusion
A.1 Instantaneous power theory
A.2 Synchronous reference frame power theory
B.1 Transformations among frames
B.2 Phase-locked loops
References
Conclusion
Index
Back Cover

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