Smart Hybrid AC/DC Microgrids: Power Management, Energy Management, and Power Quality Control

Smart Hybrid AC/DC Microgrids: Power Management,Energy Management,and Power Quality Control provides comprehensive coverage of interconnected smart hybrid microgrids,their different structures,and the technical issues associated with their control and implementation in the next generation of smart grids.

Format: Hardback
Length: 416 pages
Publication date: 22 September 2022
Publisher: John Wiley and Sons Ltd

Hybrid AC/DC microgrids are a promising solution for the next generation of smart grids, combining the benefits of both AC and DC power systems. However, implementing these microgrids presents several technical challenges that must be addressed. This book provides comprehensive coverage of interconnected smart hybrid microgrids, their different structures, and the technical issues associated with their control and implementation.

Power Management:

Hybrid AC/DC microgrids require efficient power management to balance the supply and demand of electricity. This involves controlling power sources, such as renewable energy sources, batteries, and generators, to ensure that the microgrid operates at optimal efficiency.

Energy Management:

Energy management is another critical aspect of hybrid AC/DC microgrids. This involves optimizing the use of energy resources and minimizing energy waste. This can be achieved through various techniques, such as energy storage, demand response, and energy trading.

Power Quality Control:

Power quality is a major concern in hybrid AC/DC microgrids, as the power sources may have different characteristics and may introduce disturbances to the grid. This involves controlling power converters, power electronics, and other components to ensure that the power quality is maintained within acceptable limits.

Renewable Generation Integration:

Hybrid AC/DC microgrids can integrate renewable energy sources, such as solar and wind power, to reduce dependence on fossil fuels and mitigate climate change. This involves coordinating the generation and consumption of renewable energy to ensure that the microgrid operates smoothly.

Energy Storage:

Energy storage is an essential component of hybrid AC/DC microgrids, as it allows for the smoothing of fluctuations in renewable energy generation and the storage of excess energy for use during peak demand.

Communication and Security:

Hybrid AC/DC microgrids require robust communication and security systems to ensure that the grid operates safely and securely. This involves protecting against cyberattacks, ensuring data privacy, and maintaining communication between different components of the microgrid.

Control Strategies:

Various control strategies are used in hybrid AC/DC microgrids, including predictive control, model predictive control, and artificial intelligence-based control. These strategies aim to optimize the operation of the microgrid and improve its performance.

Case Studies:

The book includes numerous case studies that highlight effective solutions for critical issues in hybrid microgrid operation, control, and power quality compensation. These case studies provide practical insights into the challenges and opportunities associated with implementing hybrid AC/DC microgrids.

Conclusion:

Hybrid AC/DC microgrids are a promising solution for the next generation of smart grids, combining the benefits of both AC and DC power systems. However, implementing these microgrids presents several technical challenges that must be addressed. This book provides comprehensive coverage of interconnected smart hybrid microgrids, their different structures, and the technical issues associated with their control and implementation. By understanding these challenges and implementing effective solutions, hybrid AC/DC microgrids can play a significant role in the development of sustainable and resilient energy systems.

Hybrid AC/DC microgrids are a promising solution for the next generation of smart grids, combining the benefits of both AC and DC power systems. However, implementing these microgrids presents several technical challenges that must be addressed. This book provides comprehensive coverage of interconnected smart hybrid microgrids, their different structures, and the technical issues associated with their control and implementation.

Power Management:

Hybrid AC/DC microgrids require efficient power management to balance the supply and demand of electricity. This involves controlling power sources, such as renewable energy sources, batteries, and generators, to ensure that the microgrid operates at optimal efficiency.

Energy Management:

Energy management is another critical aspect of hybrid AC/DC microgrids. This involves optimizing the use of energy resources and minimizing energy waste. This can be achieved through various techniques, such as energy storage, demand response, and energy trading.

Power Quality Control:

Power quality is a major concern in hybrid AC/DC microgrids, as the power sources may have different characteristics and may introduce disturbances to the grid. This involves controlling power converters, power electronics, and other components to ensure that the power quality is maintained within acceptable limits.

Renewable Generation Integration:

Hybrid AC/DC microgrids can integrate renewable energy sources, such as solar and wind power, to reduce dependence on fossil fuels and mitigate climate change. This involves coordinating the generation and consumption of renewable energy to ensure that the microgrid operates smoothly.

Energy Storage:

Energy storage is an essential component of hybrid AC/DC microgrids, as it allows for the smoothing of fluctuations in renewable energy generation and the storage of excess energy for use during peak demand.

Communication and Security:

Hybrid AC/DC microgrids require robust communication and security systems to ensure that the grid operates safely and securely. This involves protecting against cyberattacks, ensuring data privacy, and maintaining communication between different components of the microgrid.

Control Strategies:

Various control strategies are used in hybrid AC/DC microgrids, including predictive control, model predictive control, and artificial intelligence-based control. These strategies aim to optimize the operation of the microgrid and improve its performance.

Case Studies:

The book includes numerous case studies that highlight effective solutions for critical issues in hybrid microgrid operation, control, and power quality compensation. These case studies provide practical insights into the challenges and opportunities associated with implementing hybrid AC/DC microgrids.

Conclusion:

Hybrid AC/DC microgrids are a promising solution for the next generation of smart grids, combining the benefits of both AC and DC power systems. However, implementing these microgrids presents several technical challenges that must be addressed. This book provides comprehensive coverage of interconnected smart hybrid microgrids, their different structures, and the technical issues associated with their control and implementation. By understanding these challenges and implementing effective solutions, hybrid AC/DC microgrids can play a significant role in the development of sustainable and resilient energy systems.

Weight: 736g
Dimension: 158 x 235 x 31 (mm)
ISBN-13: 9781119598374