Foundations and Trends® in Electric Energy Systems > Vol 7 > Issue 2

Operational Planning for Emerging Distribution Systems: A Unique Perspective on Grid Expansion

By Anna Stuhlmacher, Michigan Technological University, USA, annastu@mtu.edu | Chee-Wooi Ten, Michigan Technological University, USA, ten@mtu.edu | Lawrence Dilworth, Michigan Technological University, USA, ldilwort@mtu.edu | Yachen Tang, Envision Digital, Inc., USA, yachen.tang@envision-digital.com

 
Suggested Citation
Anna Stuhlmacher, Chee-Wooi Ten, Lawrence Dilworth and Yachen Tang (2023), "Operational Planning for Emerging Distribution Systems: A Unique Perspective on Grid Expansion", Foundations and Trends® in Electric Energy Systems: Vol. 7: No. 2, pp 63-164. http://dx.doi.org/10.1561/3100000033

Publication Date: 14 Dec 2023
© 2023 A. Stuhlmacher et al.
 
Subjects
Power system planning,  Demand-side and grid scale data analytics,  Distribution systems,  Integration of renewable energy resources,  Microgrids
 

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In this article:
1. Introduction
2. Emerging Technologies in Distribution Systems
3. Distributed Energy Resources in Distribution Systems
4. Renewable Energy Sources in Distribution Systems
5. Battery Energy Storage Systems in Distribution Systems
6. Flexible Loads in Distribution Systems
7. Extension of Approximate Models with Net-Negative and Net-Zero Loads
8. Concluding Remarks
Acronyms
Acknowledgements
References

Abstract

The electrical grid has undergone significant transformations, which have had a profound impact on its distribution system development and expansion. These changes have been primarily driven by changing load profiles, distributed generation sources, and increasingly extreme weather events. Advancements in sensor and communication technologies have played a pivotal role in addressing and adapting to these changes. These changes have also led to an increased focus on reliability and resilience in planning, with priority placed on ensuring robust grid connectivity and flexibility.

Three decades ago, power distribution systems were primarily radial with unidirectional power flow. Today’s electrical distribution systems have distributed energy resources, leading to bidirectional power flow. The utility’s geographic information system network, advanced metering infrastructure, and other technologies are leveraged to allow feeders and distributed energy resources to be interconnected. This has facilitated the integration of the electric grid with networked microgrids, which has improved the overall resilience and efficiency of the distribution system.

While there have been notable improvements in grid planning, the power grid remains vulnerable to high-impact, low-frequency events caused by climate change, such as hurricanes and tornadoes. This monograph outlines potential solutions for addressing future electric grid issues, including transformer overloading due to electric vehicles, optimization challenges, advanced feeder reconfiguration, and contingency planning for extreme events. The proposed approaches focus on the implementation and operation of new technologies, such as renewable energy sources, batteries, flexible loads, and advanced sensors, that have the potential to transform distribution network planning and operation. From traditional methods to innovative networked microgrids within existing infrastructure and non-wire alternative strategies, this monograph provides a comprehensive overview of stateof- the-art strategies for future problems.

DOI:10.1561/3100000033
ISBN: 978-1-63828-300-3
116 pp. $80.00
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ISBN: 978-1-63828-301-0
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Table of contents:
1. Introduction
2. Emerging Technologies in Distribution Systems
3. Distributed Energy Resources in Distribution Systems
4. Renewable Energy Sources in Distribution Systems
5. Battery Energy Storage Systems in Distribution Systems
6. Flexible Loads in Distribution Systems
7. Extension of Approximate Models with Net-Negative and Net-Zero Loads
8. Concluding Remarks
Acronyms
Acknowledgements
References

Operational Planning for Emerging Distribution Systems: A Unique Perspective on Grid Expansion

The electrical distribution system has undergone significant transformations, which have had a profound impact on distribution system development and expansion. These changes have been primarily driven by changing load profiles, distributed generation sources, and increasingly extreme weather events. Advancements in sensor and communication technologies have played a pivotal role in addressing and adapting to these changes. These changes have also led to an increased focus on reliability and resilience in planning, with priority placed on ensuring robust grid connectivity and flexibility.

Three decades ago, power distribution systems were primarily radial with unidirectional power flow. Today’s electrical distribution systems have distributed energy resources, leading to bidirectional power flow. The utility’s geographic information system network, advanced metering infrastructure, and other technologies are leveraged to allow feeders and distributed energy resources to be interconnected. This has facilitated the integration of the electric grid with networked microgrids, which has improved the overall resilience and efficiency of the distribution system.

While there have been notable improvements in grid planning, the power grid remains vulnerable to high-impact, low-frequency events caused by climate change, such as hurricanes and tornadoes. This book outlines potential solutions for addressing future electric grid issues, including transformer overloading due to electric vehicles, optimization challenges, advanced feeder reconfiguration, and contingency planning for extreme events. The proposed approach focuses on the implementation and operation of new technologies, such as renewable energy sources, batteries, flexible loads, and advanced sensors, that have the potential to transform distribution network planning and operation. From traditional methods to innovative networked microgrids within existing infrastructure and non-wire alternative strategies, this book provides a comprehensive overview of state-of-the-art strategies for future problems.

 
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