Allocation of carbon emission flow in hybrid electricity market

被引：0

作者：

Chen D. ^{[1
]}

Xian W. ^{[2
]}

Wu T. ^{[3
]}

Yu X. ^{[4
]}

Guo R. ^{[1
]}

机构：

[1] College of Electrical Engineering, Zhejiang University, Hangzhou, 310027, Zhejiang Province

[2] State Grid Qinghai Electric Power Company, Xining, 810008, Qinghai Province

[3] State Grid Jibei Electric Power Research Institute, Xicheng District, Beijing

[4] State Grid Fujian Electric Power Company, Fuzhou, 350003, Fujian Province

来源：

Dianwang Jishu/Power System Technology | 2016年 / 40卷 / 06期

关键词：

Carbon emission flow; Hybrid market; Loss allocation; Low-carbon electricity;

D O I：

10.13335/j.1000-3673.pst.2016.06.011

中图分类号：

学科分类号：

摘要：

Learning carbon emissions from consumption perspective is helpful to realize carbon emission reduction. In power system, carbon emission flow conception has been proposed to calculate carbon emissions associated with electrical consumption. In this paper, a transaction based calculation model is proposed to handle carbon emissions calculation in hybrid market. The proposed method takes difference between bilateral and pool transactions into consideration. Firstly, carbon emissions associated with network losses are allocated to individual transactions according to their contribution to branch loss. Then, separation of bilateral and pool transactions is realized by subtracting network losses from original network. Finally, rest carbon emissions are further allocated to individual transactions in lossless network derived from original lossy network. Combining previous calculation processes, carbon emission for each load is obtained. Results can provide consumers with carbon emission information associated with their consumed electricity and promote low-carbon electricity development. Results from a case study show feasibility and effectiveness of the proposed model. © 2016, Power System Technology Press. All right reserved.

引用

页码：1683 / 1688

页数：5

共 19 条

[1] Malla S., CO<sub>2</sub> emissions from electricity generation in seven Asia- Pacific and North American countries: a decomposition analysis, Energy Policy, 37, 1, pp. 1-9, (2009)
[2] Song X., Mo J., Xiang T., Initial allocation mechanism of carbon emission permit in electric power industry, Electric Power Automation Equipment, 33, 1, pp. 44-49, (2013)
[3] Chattopadhyay D., Modeling greenhouse gas reduction from the Australian electricity sector, IEEE Transactions on Power Systems, 25, 2, pp. 729-740, (2010)
[4] Gil H., Joos G., Generalized estimation of average displaced emissions by wind generation, IEEE Transactions on Power Systems, 22, 3, pp. 1035-1043, (2007)
[5] Lenzen M., Munksgaard J., Energy and CO<sub>2</sub> life-cycle analyses of wind turbines-review and applications, Renewable Energy, 26, 3, pp. 339-362, (2002)
[6] Zhou T., Kang C., Xu Q., Et al., Preliminary theoretical investigation on power system carbon emission flow, Automation of Electric Power Systems, 36, 7, pp. 38-43, (2012)
[7] Zhou T., Kang C., Xu Q., Et al., Preliminary theoretical investigation on power system carbon emission flow, Automation of Electric Power Systems, 36, 11, pp. 44-49, (2012)
[8] Li B., Hu Z., Song Y., Et al., Principle and model for assessment on carbon emission intensity caused by electricity at consumer side, Power System Technology, 8, 8, pp. 6-11, (2012)
[9] Zhou T., Kang C., Xu Q., Et al., Analysis on distribution characteristics and mechanisms of carbon emission flow in electric power network, Automation of Electric Power Systems, 36, 15, pp. 39-44, (2012)
[10] Kang C., Zhou T., Chen Q., Et al., Carbon emission flow in networks, Scientific Reports, 31, 2, pp. 219-226, (2012)

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