Hybrid-renewable energy systems in microgrids : integration, developments and control / edited by A. Hina Fathima [and five others].

Format:

Book

Contributor:

Fathima, Hina, editor.

Language:

English

Subjects (All):

Renewable energy sources.

Wind power.

Physical Description:

1 online resource (270 pages)

Edition:

1st ed.

Place of Publication:

Duxford, Kidlington ; Cambridge : Woodhead Publishing, 2018.

Summary:

Hybrid-Renewable Energy Systems in Microgrids: Integration, Developments and Control presents the most up-to-date research and developments on hybrid-renewable energy systems (HRES) in a single, comprehensive resource. With an enriched collection of topics pertaining to the control and management of hybrid renewable systems, this book presents recent innovations that are molding the future of power systems and their developing infrastructure. Topics of note include distinct integration solutions and control techniques being implemented into HRES that are illustrated through the analysis of various global case studies.With a focus on devices and methods to integrate different renewables, this book provides those researching and working in renewable energy solutions and power electronics with a firm understanding of the technologies available, converter and multi-level inverter considerations, and control and operation strategies.- Includes significant case studies of control techniques and integration solutions which provide a deeper level of understanding and knowledge- Combines existing research into a single informative resource on micro grids with HRES integration and control- Includes architectural considerations and various control strategies for the operation of hybrid systems

Contents:

Cover

Title Page

Copyright Page

Contents

List of Contributors

1 - Hybrid PV-wind renewable energy sources for microgrid application: an overview

1 - Introduction

2 - Hybrid renewable energy system and its benefit

3 - Hybrid renewable energy system configuration

4 - Optimization of hybrid system

4.1 - Optimization objectives

4.2 - Optimization practices in HRES

5 - Energy storage system in MG

6 - Stability concerns in a HRES MG system

7 - Simulation

7.1 - Load generator with PV only

7.2 - Load generator with wind only

7.3 - Load generator with PV-wind

7.4 - Comparison of voltages with different combinations of PV/wind

8 - Conclusion

References

2 - Microgrid architecture, control, and operation

2 - Microgrid architecture

3 - Mathematical analysis of microgrid structure

3.1 - AC microgrid

3.2 - DC microgrid

3.3 - AC-DC hybrid microgrid

4 - Microgrid control and operation

4.1 - Hierarchical control of microgrid

5 - Mathematical model of hierarchical control

5.1 - Droop-based control of microgrid

6 - Simulation study

7 - Conclusion

3 - Integrated renewable energy sources with droop control techniques-based microgrid operation

2 - Framework of microgrid technology

2.1 - Physical equipment

2.2 - Protection and control

2.3 - Automation and control

2.4 - Monitoring, scheduling, optimization, and dispatch

2.5 - Energy market and coordinating the response of smart grid operation

3 - DC microgrid and AC microgrid

3.1 - DC microgrid

3.2 - AC microgrid

4 - Proposed structure of grid connected microgrid system

5 - Characteristics and modeling of renewable energy sources

5.1 - Solar PV

5.2 - Battery modeling

6 - Concept of droop control.

6.1 - Droop control techniques in microgrid

6.1.1 - Virtual impedance droop control

7 - Case study of solar PV and BESS with P/Q and V/f droop control

7.1 - Results and discussion

Further reading

4 - Multilevel inverters: an enabling technology

2 - Multilevel inverter topologies

2.1 - Diode-clamped inverter

2.2 - Capacitor-clamped inverter

2.2.1 - Advantages

2.2.2 - Disadvantages

2.3 - Cascaded H bridge inverters

2.4 - Comparison of different multilevel inverters

3 - Matlab/Simulink modeling and simulation of multilevel inverters

3.1 - Single phase three level CMLI

4 - Applications of multilevel inverters

4.1 - Energy and power systems

4.2 - Production

4.3 - Transportation

4.4 - Utilization in grid connected systems

5 - Conclusion

5 - Multilevel inverters for photovoltaic energy systems in hybrid-renewable energy systems

1 - Multilevel inverter topology

1.1 - Switching sequences

1.2 - Number of components

2 - Evolution of hybrid multilevel inverters

3 - Leakage current in photo voltaic inverters

6 - An overview of control techniques and technical challenge for inverters in micro grid

2 - Grid inverter synchronization

2.1 - Highlights of PLL techniques

3 - Controllers based on inverter in microgrids

3.1 - Centralized method

3.2 - Decentralized method

3.3 - Hierarchical control

4 - Dynamic security of microgrids

4.1 - Challenges in microgrid

7 - Study of control strategies of power electronics during faults in microgrids

2 - Instantaneous power theory

3 - Grid-connected mode

3.1 - Flexible oscillating power control

3.2 - Flexible positive- and negative-sequence power control.

3.3 - Inner current controller

3.3.1 - Synchronous reference frame control

3.3.2 - Stationary reference frame control

3.3.3 - Natural reference frame control

3.4 - Converter current limitation

3.4.1 - Flexible positive- and negative-sequence power control

3.4.2 - Flexible oscillating power control

4 - Islanded mode

4.1 - Basic control structure

4.2 - Negative-sequence component control

5 - Simulation results

5.1 - System description

5.2 - Steady state

5.3 - Performance under unbalanced faults

5.4 - Discussion on microgrid protection

8 - Renewable systems and energy storages for hybrid systems

2 - Energy storage systems

3 - Need for ESS

4 - Characteristic features of ESS

5 - Types of ESS

6 - Impact of market infrastructure on energy storage systems

6.1 - Utility scale

6.2 - Behind the Meter

6.3 - Remote power systems

7 - Case studies

8 - Technological challenges for ESS

9 - Conclusion

Further Reading

9 - Sensitivity and transient stability analysis of fixed speed wind generator with series dynamic braking resistor

2 - Modeling of the system

2.1 - Wind turbine modeling

2.2 - Drive train modeling

2.2.1 - Induction generator modeling

2.2.2 - Capacitor bank modeling

2.2.3 - Transmission line modeling

2.2.4 - SDBR modeling

2.3 - Small signal stability analysis

2.3.1 - Analysis using Jacobian Matrix

2.3.2 - Computer simulation (LINMOD)

2.3.3 - Participation factor of the system including SDBR

2.4 - Sensitivity analysis

2.4.1 - Drive train

2.4.2 - Generator parameters

2.4.3 - Transmission line parameters

2.4.4 - Comparative analysis of the system dynamics under voltage dip

2.5 - Transient stability analysis

2.5.1 - Effect of transmission line reactance.

2.5.2 - Effect of shaft stiffness

2.5.3 - Effect of rotor resistance

3 - Conclusion

4 - Appendix

Further Readings

10 - Smart grid and power quality issues

2 - Microgrids in a smart grid

2.1 - Power quality concerns in AC microgrids

2.2 - Power quality concerns in DC microgrids

3 - Potential impact on power quality

3.1 - Slow and rapid voltage variations

3.2 - Short duration under voltages

3.3 - Harmonic distortions

3.4 - Switching transients

3.5 - Power quality concerns related to demand side management

4 - New power quality indices

11 - Techno economic feasibility analysis of different combination of PV-wind-diesel-battery hybrid system

2 - Methodology

2.1 - Hybrid optimization model for electric renewable pro

2.1.1 - Photovoltaic system component analysis

2.1.2 - Sensitivity analysis

2.1.3 - PV array

2.1.4 - Economic analysis

2.1.5 - Input variables

2.1.6 - Analysis

2.2 - Selected cities for modelling

2.3 - Telecom load

2.4 - Solar radiation and wind speed

3 - Results and discussions

4 - Conclusion

12 - Solar-wind hybrid renewable energy system: current status of research on configurations, control, and sizing method...

1.1 - Grid connected systems

1.2 - Standalone systems

1.3 - Hybrid renewable energy systems

2 - Feasibility study

2.1 - Time-series meteorological data

2.2 - Statistical meteorological data

3 - Simulation modelling of HRES components

3.1 - Modelling of photovoltaic system

3.2 - Modelling the wind energy system

3.3 - Modelling of battery storage system

4 - Optimization techniques for hybrid solar-wind system

4.1 - Criteria for hybrid solar-wind system optimization.

4.1.1 - Power reliability analysis

4.1.2 - System Cost analysis

4.2 - Optimum sizing methods for hybrid solar-wind system

4.2.1 - Probabilistic methods

4.2.2 - Analytical methods

4.2.3 - Iterative methods

4.2.4 - Graphic construction technique

4.2.5 - Multi-objective design

4.2.6 - Hybrid methods

4.2.7 - Computing tools

4.2.7.1 - Simulation

4.2.7.2 - Optimization

4.2.7.3 - Sensitivity Analysis

5 - Control of HRES

6 - Conclusion

Index

Back cover.

Notes:

Description based on print version record.

ISBN:

9780081024942

0081024940

9780081024935

0081024932