Calculation and Sharing of Regional Carbon Emission Reduction Considering Construction of Ultra High Voltage AC Projects

doi:10.11930/j.issn.1004-9649.202305128

Abstract

Abstract:

Under the "dual carbon" goal, the ultra-high voltage (UHV) AC project, with its advanced technological means, will play a greater role in consuming clean energy and reducing transmission losses. Considering that there is relatively little research on the carbon reduction benefits of UHV AC projects. this paper proposes a quantitative method for evaluating the carbon reduction benefits of UHV AC projects, taking the load landing area as the research object. Firstly, the distribution of power flow at both ends of the transmission and reception is simulated to determine the power flow proportion of the transmission channel. Secondly, an analysis is conducted on the electricity balance of the power supply area to determine the amount of clean energy transmitted by the UHV AC project. The carbon reduction emissions in the load area is calculated based on carbon emission factors, and the Shapley value is used to calculate the carbon reduction benefits of the UHV AC project based on its contribution. Finally, an actual project is taken as an example for numerical analysis. The results indicate that the UHV AC project can reduce carbon emissions by improving the ability to accommodate clean energy.

Key words: UHV AC project, time series production simulation, power flow calculation, Shapley value

Shuo WANG, Huijuan HUO, Dan XU, Xin QIE, Cheng XIN, Weiwei LI, Jing DUAN. Calculation and Sharing of Regional Carbon Emission Reduction Considering Construction of Ultra High Voltage AC Projects[J]. Electric Power, 2024, 57(7): 163-172.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202305128

https://www.electricpower.com.cn/EN/Y2024/V57/I7/163

Figures/Tables 14

References 28

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运行方式和时段	特高压通道潮流/ 万kW	500 kV 通道潮流/ 万kW	特高压通道潮流占比/%	500 kV 通道潮流占比/%
2025年夏季低谷	267	620	30	70
2025年夏季腰荷	318	728	30	70
2025年夏季高峰	352	805	30	70
2025年汛期高峰	376	816	32	68
2025年夏季风电大发	346	799	30	70
2030年夏季高峰	515	685	43	57
2030年汛期高峰	524	702	43	57
2030年夏季风电大发	548	742	42	58

运行方式和时段	特高压通道潮流/ 万kW	500 kV 通道潮流/ 万kW	特高压通道潮流占比/%	500 kV 通道潮流占比/%
2025年夏季低谷	267	620	30	70
2025年夏季腰荷	318	728	30	70
2025年夏季高峰	352	805	30	70
2025年汛期高峰	376	816	32	68
2025年夏季风电大发	346	799	30	70
2030年夏季高峰	515	685	43	57
2030年汛期高峰	524	702	43	57
2030年夏季风电大发	548	742	42	58

场景	年份	北电南送通道断面电量	特高压通道电量	特高压通道清洁电量
不外送	2025	645	194	107
不外送	2030	763	320	224
外送100亿kW·h	2025	603	181	100
外送100亿kW·h	2030	719	302	211
外送150亿kW·h	2025	582	175	96
外送150亿kW·h	2030	697	293	205

场景	年份	北电南送通道断面电量	特高压通道电量	特高压通道清洁电量
不外送	2025	645	194	107
不外送	2030	763	320	224
外送100亿kW·h	2025	603	181	100
外送100亿kW·h	2030	719	302	211
外送150亿kW·h	2025	582	175	96
外送150亿kW·h	2030	697	293	205

场景	年份	煤电	清洁电源	其他火电	合计
不外送	2025	736	352	179	1267
不外送	2030	737	383	216	1336
外送100亿kW·h	2025	724	399	186	1309
外送100亿kW·h	2030	716	441	223	1380
外送150亿kW·h	2025	718	422	190	1330
外送150亿kW·h	2030	705	470	226	1402