Fast Decomposed Method for Dynamic Energy Flow Calculation in Integrated Electricity and Heat System

被引:2
作者
Ma, Rui [1 ]
Liu, Hongzhi [2 ]
Geng, Jialu [2 ]
Zhu, Dongge [1 ]
Yan, Zhenhua [1 ]
Luo, Zhao [2 ]
Zhang, Qingping [1 ]
Li, Xuefeng [1 ]
机构
[1] State Grid Ningxia Elect Power Co Ltd, Elect Power Res Inst, Yinchuan 750002, Ningxia, Peoples R China
[2] Kunming Univ Sci & Technol, Fac Elect Power Engn, Kunming 650500, Yunnan, Peoples R China
来源
IEEE ACCESS | 2021年 / 9卷
关键词
Resistance heating; Power systems; Power system dynamics; Computational modeling; Hydraulic systems; Cogeneration; Mathematical models; Integrated electricity and heat system; energy flow calculation; decomposed method; modification mode; GAS; POWER; TIME;
D O I
10.1109/ACCESS.2021.3116810
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
The development of integrated electricity and heat system (IEHS) promotes the renewable energy penetration and the complementary coupling between the electric power system (EPS) and the district heat system (DHS). The efficient energy flow calculation (EFC) in the IEHS has become a hotspot as the system scale and complexity increase. This paper firstly constructed the dynamic DHS model using Euler difference scheme. On this basis, the fast decomposed method is proposed to decompose the system with various scales and topologies, which improves the computation efficiency. Moreover, the modification mode is then developed to modify the EFC results in the decomposed systems and ensure the accuracy. Numerical simulation verifies the accuracy of the proposed method and its superiority in computation efficiency.
引用
收藏
页码:168760 / 168766
页数:7
相关论文
共 50 条
[31]   Electricity and Heat Sector Coupling for Domestic Energy Systems Benefits of Integrated Energy System Modelling [J].
Jambagi, Akhila ;
Kramer, Michael ;
Cheng, Vicky .
SMARTGREENS 2015 PROCEEDINGS OF THE 4TH INTERNATIONAL CONFERENCE ON SMART CITIES AND GREEN ICT SYSTEMS, 2015, :66-71
[32]   Bilevel Heat-Electricity Energy Sharing for Integrated Energy Systems With Energy Hubs and Prosumers [J].
Liu, Nian ;
Tan, Lu ;
Sun, Haonan ;
Zhou, Zhenyu ;
Guo, Bin .
IEEE TRANSACTIONS ON INDUSTRIAL INFORMATICS, 2022, 18 (06) :3754-3765
[33]   High-Resolution Modeling and Decentralized Dispatch of Heat and Electricity Integrated Energy System [J].
Lu, Shuai ;
Gu, Wei ;
Zhou, Suyang ;
Yu, Wenwu ;
Yao, Shuai ;
Pan, Guangsheng .
IEEE TRANSACTIONS ON SUSTAINABLE ENERGY, 2020, 11 (03) :1451-1463
[34]   Exploiting Internet Data Centers as Energy Prosumers in Integrated Electricity-Heat System [J].
Yin, Xunhu ;
Ye, Chengjin ;
Ding, Yi ;
Song, Yonghua .
IEEE TRANSACTIONS ON SMART GRID, 2023, 14 (01) :167-182
[35]   Analysis of Probabilistic Energy Flow for Integrated Electricity-Gas Energy System with P2G Based on Cumulant Method [J].
Hu, Qiang ;
Zeng, Bo ;
Zhang, Yuying ;
Hu, Hao ;
Liu, Wenxia .
2017 IEEE CONFERENCE ON ENERGY INTERNET AND ENERGY SYSTEM INTEGRATION (EI2), 2017, :436-441
[36]   Distributed Dispatch of Integrated Electricity-Heat Systems With Variable Mass Flow [J].
Zheng, Weiye ;
Zhu, Jizhong ;
Luo, Qingju .
IEEE TRANSACTIONS ON SMART GRID, 2023, 14 (03) :1907-1919
[37]   Unit Commitment of Integrated Electricity and Heat System with Bi-directional Variable Mass Flow [J].
Wu, Xuewei ;
Chen, Zhe ;
Fang, Jiakun .
2020 IEEE POWER & ENERGY SOCIETY GENERAL MEETING (PESGM), 2020,
[38]   Coordinated scheduling of electricity-heat-gas integrated energy system considering emerging energy conversion technologies [J].
Liang, Bomiao ;
Liu, Weijia ;
Zhang, Jinjiang .
ENERGY REPORTS, 2023, 9 :136-144
[39]   Optimal scheduling of electricity-gas-heat integrated energy system with coordination of flexibility and reliability [J].
Zhang, Yumin ;
Li, Jingrui ;
Ji, Xingquan ;
Yang, Ming ;
Ye, Pingfeng .
SUSTAINABLE ENERGY TECHNOLOGIES AND ASSESSMENTS, 2024, 71
[40]   Risk assessment of integrated electricity and heat system with independent energy operators based on Stackelberg game [J].
Wang, Can ;
Yan, Chao ;
Li, Gengfeng ;
Liu, Shiyu ;
Bie, Zhaohong .
ENERGY, 2020, 198
12345