Equivalent Model and Static Flow Analysis Method for Electricity and Heating Network System

被引：0

作者：

Peng S. ^{[1
]}

Xie N. ^{[1
]}

Wang C. ^{[1
]}

Huang C. ^{[1
]}

机构：

[1] School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai

来源：

Dianli Xitong Zidonghua/Automation of Electric Power Systems | 2022年 / 46卷 / 13期

关键词：

average temperature response; electric boiler; electric heating efficiency; integrated energy system; power flow calculation; static analysis;

D O I：

10.7500/AEPS20210719007

中图分类号：

学科分类号：

摘要：

With the continuous growth of clean energy, such as photovoltaic power, wind power, etc., the electricity-heating hybrid system will be the development trend of the integrated energy system in the future. Firstly, an equivalent relationship between the electric power of the power system and the fluid mass flow rate of the heating network system is built to ensure that the electric power flow and heating power flow can be analyzed on the same time-domain scale. On this basis, the average temperature response model of the heating network system and the external characteristic model of the electric boiler are respectively constructed, thereby confirming the response status of the heating network system and the interactional variables between the electric and heating power flows. Based on the fundamental principles of the Newton method and hydraulic calculation of the heating network system, the power flow correction equations of the electricity and heating network system are deduced as well as its Jacobian matrix, thus developing a static power flow analysis method for the electricity-heating hybrid system considering the variation of the electric heating efficiency with the system operation environment. Finally, the case analysis is given to demonstrate the feasibility and practicability of the proposed method. © 2022 Automation of Electric Power Systems Press. All rights reserved.

引用

页码：62 / 73

页数：11

共 26 条

[1] LIU Xuezhi, YAN Zheng, XIE Da, Et al., Research and prospects of a pathway to tight coupling between electricity and heat networks, Automation of Electric Power Systems
[2] SHU Yinbiao, XUE Yusheng, CAI Bin, Et al., A review of energy transition analysis:Part one elements and paradigms, Automation of Electric Power Systems, 42, 9, pp. 1-15, (2018)
[3] YU Xiaodan, XU Xiandong, CHEN Shuoyi, Et al., A brief review to integrated energy system and Energy Internet, Transactions of China Electrotechnical Society, 31, 1, pp. 1-13, (2016)
[4] QU Ziqing, XIN Jieqing, WU Liang, Et al., Argument on boundary conditions of selection electric energy substitution technologies with electric heating for commercial customers, Automation of Electric Power Systems, 40, 13, pp. 48-54, (2016)
[5] ZHANG Yuman, LIU Xuezhi, YAN Zheng, Et al., Decomposition-coordination based optimization for PV-BESS-CHP integrated energy systems, Transactions of China Electrotechnical Society, 35, 11, pp. 2372-2386, (2020)
[6] SUN Hongyu, ZHANG Peichao, DU Wei, Et al., Power flow calculation method of integrated electricity and heat system based on power conservation principle, Electric Power Automation Equipment, 40, 11, pp. 54-62, (2020)
[7] LIU Hong, ZHAO Chenxiao, GE Shaoyun, Et al., Sequential power flow calculation of power-heat integrated energy system based on refined heat network model, Automation of Electric Power Systems, 45, 4, pp. 63-72, (2021)
[8] ZHANG Yizhi, WANG Xiaojun, HE Jinghan, Et al., Optimal energy flow calculation method of integrated energy system considering thermal system modeling, Transactions of China Electrotechnical Society, 34, 3, pp. 562-570, (2019)
[9] YANG J W, ZHANG N, BOTTERUD A, Et al., On an equivalent representation of the dynamics in district heating networks for combined electricity-heat operation [J], IEEE Transactions on Power Systems, 35, 1, pp. 560-570, (2020)
[10] CHEN Binbin, SUN Hongbin, YIN Guanxiong, Et al., Energy circuit theory of integrated energy system analysis (II): hydraulic circuit and thermal circuit, Proceedings of the CSEE, 40, 7, pp. 2133-2142, (2020)

← 1 2 3 →