Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat Systems

Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat Systems

Implementing integrated electric-heat systems (IEHSs) with coupled power distribution networks and district heating networks is an essential means to solve current energy problems. However, prosumers with multiple energy forms coupled and renewable energy sources with natural uncertainties pose chal...

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Main Authors: Wei Zhao, Hanbin Diao, Peiqiang Li, Xiaoxiu Lv, Ertao Lei, Zhenyu Mao, Wenqi Xue
Format: Article
Language:English
Published: IEEE 2021-01-01
Series:IEEE Access
Subjects:
Integrated electric-heat system
transactive energy
joint energy and reserve dispatch
Stackelberg game
two-stage robust optimization
Online Access:https://ieeexplore.ieee.org/document/9326308/
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spelling doaj-72ddd4c7614b412d87ebcb7451924a312021-03-30T15:11:51ZengIEEEIEEE Access2169-35362021-01-019144911450310.1109/ACCESS.2021.30520519326308Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat SystemsWei Zhao0Hanbin Diao1https://orcid.org/0000-0002-6766-1212Peiqiang Li2Xiaoxiu Lv3Ertao Lei4https://orcid.org/0000-0002-7238-2816Zhenyu Mao5Wenqi Xue6https://orcid.org/0000-0003-3551-8128Electric Power Research Institute of Guangdong Power Grid Corporation, Guangzhou, ChinaCollege of Electrical and Information Engineering, Hunan University, Changsha, ChinaCollege of Electrical and Information Engineering, Hunan University, Changsha, ChinaCollege of Electrical and Information Engineering, Hunan University, Changsha, ChinaElectric Power Research Institute of Guangdong Power Grid Corporation, Guangzhou, ChinaCollege of Electrical and Information Engineering, Hunan University, Changsha, ChinaCollege of Electrical and Information Engineering, Hunan University, Changsha, ChinaImplementing integrated electric-heat systems (IEHSs) with coupled power distribution networks and district heating networks is an essential means to solve current energy problems. However, prosumers with multiple energy forms coupled and renewable energy sources with natural uncertainties pose challenges to the operation of IEHSs. This paper proposes a joint energy and reserve dispatch model for IEHSs based on transactive energy, which is a coordinated combination of a bi-level Stackelberg game and two-stage robust optimization. The bi-level Stackelberg game is used to realize the equilibrium of interests among three transacting parties, namely, integrated energy service provider (IESP), multi-carrier prosumer (MCP), and load aggregator (LA). The two-stage robust optimization is employed to ensure the reliability of the system operation under renewable energy uncertainty. In the upper level of the Stackelberg game, the IESP perform pricing and reserve dispatch, while the MCP and LA maximize their benefits via energy management in the lower level. Linearization techniques are utilized to approximate the bi-level Stackelberg game model into a single-level mixed-integer linear programming problem. The converted single-level game model is subsequently regarded as the first stage, while the real-time feasibility check is regarded as the second stage to form a two-stage robust optimization model, which is solved by a modified C&CG algorithm. Case studies demonstrate that the proposed joint energy and reserve dispatch method effectively achieves economic and reliable operation.https://ieeexplore.ieee.org/document/9326308/Integrated electric-heat systemtransactive energyjoint energy and reserve dispatchStackelberg gametwo-stage robust optimization
collection DOAJ
language English
format Article
sources DOAJ
author Wei Zhao
Hanbin Diao
Peiqiang Li
Xiaoxiu Lv
Ertao Lei
Zhenyu Mao
Wenqi Xue
spellingShingle Wei Zhao
Hanbin Diao
Peiqiang Li
Xiaoxiu Lv
Ertao Lei
Zhenyu Mao
Wenqi Xue
Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat Systems
IEEE Access
Integrated electric-heat system
transactive energy
joint energy and reserve dispatch
Stackelberg game
two-stage robust optimization
author_facet Wei Zhao
Hanbin Diao
Peiqiang Li
Xiaoxiu Lv
Ertao Lei
Zhenyu Mao
Wenqi Xue
author_sort Wei Zhao
title Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat Systems
title_short Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat Systems
title_full Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat Systems
title_fullStr Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat Systems
title_full_unstemmed Transactive Energy-Based Joint Optimization of Energy and Flexible Reserve for Integrated Electric-Heat Systems
title_sort transactive energy-based joint optimization of energy and flexible reserve for integrated electric-heat systems
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2021-01-01
description Implementing integrated electric-heat systems (IEHSs) with coupled power distribution networks and district heating networks is an essential means to solve current energy problems. However, prosumers with multiple energy forms coupled and renewable energy sources with natural uncertainties pose challenges to the operation of IEHSs. This paper proposes a joint energy and reserve dispatch model for IEHSs based on transactive energy, which is a coordinated combination of a bi-level Stackelberg game and two-stage robust optimization. The bi-level Stackelberg game is used to realize the equilibrium of interests among three transacting parties, namely, integrated energy service provider (IESP), multi-carrier prosumer (MCP), and load aggregator (LA). The two-stage robust optimization is employed to ensure the reliability of the system operation under renewable energy uncertainty. In the upper level of the Stackelberg game, the IESP perform pricing and reserve dispatch, while the MCP and LA maximize their benefits via energy management in the lower level. Linearization techniques are utilized to approximate the bi-level Stackelberg game model into a single-level mixed-integer linear programming problem. The converted single-level game model is subsequently regarded as the first stage, while the real-time feasibility check is regarded as the second stage to form a two-stage robust optimization model, which is solved by a modified C&CG algorithm. Case studies demonstrate that the proposed joint energy and reserve dispatch method effectively achieves economic and reliable operation.
topic Integrated electric-heat system
transactive energy
joint energy and reserve dispatch
Stackelberg game
two-stage robust optimization
url https://ieeexplore.ieee.org/document/9326308/
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AT hanbindiao transactiveenergybasedjointoptimizationofenergyandflexiblereserveforintegratedelectricheatsystems
AT peiqiangli transactiveenergybasedjointoptimizationofenergyandflexiblereserveforintegratedelectricheatsystems
AT xiaoxiulv transactiveenergybasedjointoptimizationofenergyandflexiblereserveforintegratedelectricheatsystems
AT ertaolei transactiveenergybasedjointoptimizationofenergyandflexiblereserveforintegratedelectricheatsystems
AT zhenyumao transactiveenergybasedjointoptimizationofenergyandflexiblereserveforintegratedelectricheatsystems
AT wenqixue transactiveenergybasedjointoptimizationofenergyandflexiblereserveforintegratedelectricheatsystems
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