Preliminary Study on Mechanism and Benefit Analysis of Load Response for Electricity-Carbon Market Collaboration

被引：0

作者：

Pang L. ^{[1
,2
]}

Ji B. ^{[1
,2
]}

Xu F. ^{[1
,2
]}

Chang L. ^{[1
,2
]}

Cao R. ^{[1
,2
]}

机构：

[1] NARI Group Corporation, State Grid Electric Power Research Institute, Nanjing

[2] State Key Laboratory of Smart Grid Protection and Control, Nanjing

来源：

Dianli Xitong Zidonghua/Automation of Electric Power Systems | 2022年 / 46卷 / 22期

关键词：

benefit analysis; carbon right market; collaborative trading; data interaction; demand response; electricity market;

D O I：

10.7500/AEPS20220208003

中图分类号：

学科分类号：

摘要：

In order to maintain the balance between supply and demand of the power grid cleanly and efficiently, the cost of carbon emission from power consumption in the electricity market is considered and a market-oriented source-load interactive trading environment is built. Then, the accounting model of carbon emission from power consumption, the electricity-carbon market collaboration mode, the cost accounting of carbon emission from power consumption and the analysis method of responding market benefit for load subjects participating in the regulation response trading are proposed. By coupling the unbalanced electricity quantity that needs the regulation response by elastic electricity price, the function of tracking and adjusting the settlement electricity price in response to demand can be realized. The proposed electricity-carbon market collaboration mechanism and method are verified by an example, which can couple the unbalanced electricity quantity, change the electricity cost and carbon emission benefit, and encourage the load subjects to participate in the regulation response. The price means and market benefit analysis method of market-oriented regulation of load elastic resources are provided to bring load elastic resources into the regulation scope and improve the regulation economy and environmental protection benefits. © 2022 Automation of Electric Power Systems Press. All rights reserved.

引用

页码：62 / 71

页数：9

共 23 条

[1] Carbon dioxide emissions account for 40 percent，low carbon power helps carbon peak as soon as possible
[2] WANG Caixia, SHI Zhiyong, LIANG Zhifeng, Et al., Key technologies and prospects of demand-side resource utilization for power systems dominated by renewable energy［J］, Automation of Electric Power Systems, 45, 16, pp. 37-48, (2021)
[3] WU Runji, WANG Dongxiao, XIE Changhong, Et al., Distributed control method for air-conditioning load participating in voltage management of distribution network［J］, Automation of Electric Power Systems, 45, 6, pp. 215-222, (2021)
[4] DING Jian, FANG Xiaosong, SONG Yunting, Et al., Conception of electricity and hydrogen integrated energy network for renewable energy transmission in Western China under background of carbon neutralization［J］, Automation of Electric Power Systems, 45, 24, pp. 1-9, (2021)
[5] ZHU Weiye, LUO Yi, HU Bo, Et al., Optimized combined heat and power dispatch considering the coordination of heat load elasticity and time-of-use demand response［J］, Power System Protection and Control, 50, 9, pp. 124-135, (2022)
[6] HU Jiangyi, ZHENG Tao, JIN Yulong, Et al., An aggregation strategy of air conditioning loads considering uncertainty of customer behavior and frequency regulation demand［J］, Power System Technology, 46, 9, pp. 3534-3542, (2022)
[7] ZHANG Wei, WANG Dan, Real-time demand response scheduling strategy for electric vehicles based on cloud edge collaboration［J］, Power System Technology, 46, 4, pp. 1447-1458, (2022)
[8] REN Zhijun, GUO Minhua, GUO Hongxia, Et al., Active distribution network planning method under power-user interaction mode［J］, Renewable Energy Resources, 37, 11, pp. 1643-1649, (2019)
[9] TIAN Hao, LIU Wenying, WANG Fangyu, Et al., Multi-objective optimal method of source-load peaking regulation based on participation of loads［J］, Power System and Clean Energy, 34, 11, pp. 32-38, (2018)
[10] Bin JI, CHANG Li, CHEN Zhenhuan, Et al., Blockchain technology based design and application of market mechanism for power carbon emission allowance trading［J］, Automation of Electric Power Systems, 45, 12, pp. 1-10, (2021)

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