Multi-Objective Planning of Power-Gas Integrated Energy System Considering Economy and Carbon Emission

被引：0

作者：

Zhu H. ^{[1
]}

Wang J. ^{[1
]}

Chen B. ^{[1
]}

Zhang H. ^{[2
]}

Chen J. ^{[2
]}

Wu Q. ^{[3
]}

机构：

[1] State Grid Weifang Power Supply Company, Shandong, Weifang

[2] School of Electrical Engineering, Shandong University, Jinan

[3] Department of Electrical Engineering, Technical University of Denmark, Kgs. Lyngby

来源：

Shanghai Jiaotong Daxue Xuebao/Journal of Shanghai Jiaotong University | 2023年 / 57卷 / 04期

关键词：

expansion planning; integrated energy; low-carbon transformation; multi-objective;

D O I：

10.16183/j.cnki.jsjtu.2021.513

中图分类号：

学科分类号：

摘要：

In order to accelerate the rapid and economic low-carbon transformation of the power-gas system, a multi-objective stochastic optimization programming model for the whole equipment of the power-gas system was established, which comprehensively considered the economic cost and carbon emissions. First, the mathematical model of the electric-gas network and related equipment was established, and the uncertainty characteristics of the electric and gas loads and photovoltaic output were analyzed by using the scenario method. Next, a mixed-integer quadratically constrained programming (MIQCP) model considering the economic cost and carbon emissions of the system was established. An overall planning was made for power feeders, gas network pipelines, substations, gas distribution stations, gas units, power-to-gas devices, photovoltaic, and energy storage devices. Finally, a numerical example was built to verify the feasibility and effectiveness of the model. The results show that the model can fully consider the coupling relationship between power-gas network lines and a variety of comprehensive energy equipment under different weight choices of objective function, and obtain the overall optimal planning scheme. © 2023 Shanghai Jiao Tong University. All rights reserved.

引用

页码：422 / 431

页数：9

共 16 条

[1] XI Jianming, WU Hanran, Research on the Effect of supply side reform and the de-capacity policy in resource and energy industry, Journal of Industrial Technological Economics, 40, 1, pp. 113-119, (2021)
[2] UNSIHUAY C, MARANGON-LIMA J W, SOUZA A C Z D., Integrated power generation and natural gas expansion planning, 2007 IEEE Lausanne Power Tech, pp. 1-6, (2007)
[3] WEI Zhenbo, GUO Yi, WEI Ping'an, Et al., Distribution robust expansion planning model for integrated natural gas and electric power systems considering transmission switching, Electric Power Automation Equipment, 41, 2, pp. 16-23, (2021)
[4] XUE You, LI Yang, GAO Ying, Et al., Stochastic optimization in integrated electricity-gas energy systems considering stochastic characteristics of wind power outputs, Electric Power Construction, 39, 12, pp. 2-12, (2018)
[5] WANG Peng, LIU Weijia, LIN Zhenzhi, Et al., Scenario analysis based collaborative site selection planning of wind farms and power-to-gas plants, Automation of Electric Power Systems, 41, 6, pp. 20-29, (2017)
[6] LI Zhe, WANG Chengfu, LIANG Jun, Et al., Expansion planning method of integrated energy system considering uncertainty of wind power, Power System Technology, 42, 11, pp. 3477-3487, (2018)
[7] GAO Y, WEN F S, WANG K, Et al., Optimal collaborative planning with demand side management in integrated gas-electricity energy systems, 2018 IEEE Power & Energy Society General Meeting, pp. 1-5, (2018)
[8] JING Q, DONG Z Y, ZHAO J H, Et al., Low carbon oriented expansion planning of integrated gas and power systems, IEEE Transactions on Power Systems, 30, 2, pp. 1035-1046, (2015)
[9] LI Jie, YU Tao, PAN Zhenning, Et al., Real-time stochastic dispatch method for incremental distribution network based on reinforcement learning, Power System Technology, 44, 9, pp. 3321-3332, (2020)
[10] BARAN M, WU F., Optimal sizing of capacitors placed on a radial distribution system, IEEE Transactions on Power Delivery, 4, 1, pp. 735-743, (1989)

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