Analysis and Prospect of China&apos;s Energy Structure Transformation Based on Energy Flow Chart and Carbon Flow Chart

Wenwen SUN; Guoqing HE

doi:10.16513/j.2096-2185.DE.2207402

TSINGHUA JOURNALS HOME

Source Journal for Chinese Scientific and Technical Papers and Citations

RCCSE Chinese Core Academic Journals

Classification Catalogue of High Quality Scientific Journals in the field of Energy and Power

Classification Catalogue of High Quality Scientific Journals in Coal Field

PDF(2456 KB)

Distributed Energy ›› 2022, Vol. 7 ›› Issue (4) : 10-17. DOI: 10.16513/j.2096-2185.DE.2207402

Basic Research

Analysis and Prospect of China's Energy Structure Transformation Based on Energy Flow Chart and Carbon Flow Chart

Wenwen SUN ,
Guoqing HE

Author information +

History +

HeighLight

Dual carbon target is an important measure for our country to respond to global climate change and practice the new strategy of energy security. Under the dual carbon target, our country will accelerate the transformation and adjustment of energy industry structure, and accelerate the construction of a new power system with new energy as the main part. Firstly, the energy flow chart of 2018 is drawn, and the specific profiles of primary energy production, processing and conversion and terminal consumption energy are analyzed in detail. On this basis, the carbon flow chart in 2018 is drawn, and the main sources of carbon emissions and the size of carbon emissions in each sector of the terminal are expounded. Finally, the transformation of energy in China is prospected from three aspects of energy supply, terminal energy use and energy processing transformation.

Key words

dual carbon targets / energy flow graph / carbon flow graph / energy transformation

Cite this article

EndNote

Ris (Procite)

Bibtex

Download Citations

Wenwen SUN , Guoqing HE. Analysis and Prospect of China's Energy Structure Transformation Based on Energy Flow Chart and Carbon Flow Chart[J]. Distributed Energy Resources. 2022, 7(4): 10-17 https://doi.org/10.16513/j.2096-2185.DE.2207402

References

List( Publishing order | Descend order by publishing year | Descend order by cited within ) Chart analysis

[1]

解

振华

. 坚持积极应对气候变化战略定力　继续做全球生态文明建设的重要参与者、贡献者和引领者——纪念《巴黎协定》达成五周年[J]. 环境与可持续发展，2021, 46(1): 3-10.

XIE

Zhenhua

. Adhere to the strategic determination to actively respond to climate change and continue to be an important participant, contributor and leader in the construction of global ecological civilization: Commemorating the fifth anniversary of the Paris Agreement[J]. Environment and Sustainable Development, 2021, 46(01): 3-10.

Cited in this article [1]

[2]	文明凯，舒晓惠，沈炳良，等. 中国实施《巴黎协定》任务的方案研究[J]. 当代经济，2021(3): 74-76. Cited in this article [1]

[3]	中国共产党新闻网. 习近平在第七十五届联合国大会一般性辩论上发表重要讲话[N/OL]. [2020-09-23]. http://cpc.people.com.cn/n1/2020/0923/c64094-31871240.html Cited in this article [1]

[4]	中国共产党新闻网. 习近平在气候雄心峰会上的讲话[N/OL]. [2020-09-23]. http://cpc.people.com.cn/n1/2020/1213/c64036-31964469.html Cited in this article [1]

[5]	李明节，陈国平，董存，等. 新能源电力系统电力电量平衡问题研究[J]. 电网技术，2019, 43(11): 3979-3986. LI Mingjie, CHEN Guoping, DONG Cun, et al. Research on power balance of high proportion renewable energy system[J]. Power System Technology, 2019, 43(11): 3979-3986. Cited in this article [1]

[6]	胡伟，戚宇辰，张鸿轩，等. 风光水多能源电力系统互补智能优化运行策略[J]. 发电技术，2020, 41(1): 9-18. HU Wei, QI Yuchen, ZHANG Hongxuan, et al. Complementary intelligent optimization operation strategy of wind-solar-hydro multi-energy power system[J]. Power Generation Technology, 2020, 41(1): 9-18. Cited in this article [1]

[7]

王

博

，杨

德友

，蔡

国伟

. 高比例新能源接入下电力系统惯量相关问题研究综述[J]. 电网技术，2020, 44(8): 2998-3007.

WANG

, YANG

Deyou

, CAI

Guowei

. Review of research on power system inertia related issues in the context of high penetration of renewable power generation[J]. Power System Technology, 2020, 44(8): 2998-3007.

Cited in this article [2]

[8]	王梓珺，王承民，谢宁. 基于柔性计算的高比例新能源环境下的电力电量平衡[J]. 智慧电力，2021, 49(8): 15-22. WANG Zijun, WANG Chengmin, XIE Ning. Electric power and energy balance based on flexible computing in energy internet with high proportion of new energy[J]. Smart Power, 2021, 49(8): 15-22. Cited in this article [1]

[9]	于鹏伟，张豪，魏世杰，等. 2017年中国能源流和碳流分析[J]. 煤炭经济研究，2019, 39(10): 15-22. YU Pengwei, ZHANG Hao, WEI Shijie, et al. Analysis on the energy flow and carbon flow of China in 2017[J]. Coal Economic Research, 2019, 39(10): 15-22. Cited in this article [1]

[10]	张豪，樊静丽，汪航，等. 2016年中国能源流和碳流分析[J]. 中国煤炭，2018, 44(12): 15-19, 50. ZHANG Hao, FAN Jingli, WANG Hang, et al. Analysis of China's energy and carbon flow in 2016[J]. China Coal, 2018, 44(12): 15-19, 50. Cited in this article [1]

[11]	樊静丽，魏世杰，张贤. 2015年中国能源流与碳流分析[J]. 北京理工大学学报(社会科学版), 2018, 20(4): 40-45. FAN Jingli, WEI Shijie, ZHANG Xian. Analysis of energy flow and carbon flow of China in 2015[J]. Journal of Beijing Institute of Technology(Social Sciences Edition), 2018, 20(4): 40-45. Cited in this article [1]

[12]	国家统计局. 中国能源统计年鉴(2019)[M]. 北京：中国统计出版社，2020. Cited in this article [1]

[13]	SCHMIDT M. The sankey diagram in energy and material flow management[J]. Journal of Industrial Ecology, 2008, 12(1): 27-34. Cited in this article [1]

[14]	董东林，张一艳，林刚. 基于能流图的山东省能源平衡分析及能源需求预测[J]. 煤炭经济研究，2020, 40(2): 31-38. DONG Donglin, ZHANG Yiyan, LIN Gang. Analysis of energy balance and energy demand forecast in Shangdong Province based on energy flow chart[J]. Coal Economic Research, 2020, 40(2): 31-38. Cited in this article [1]

[15]

朱

伟业

，罗

毅

，胡

博

，等. 热负荷弹性与分时电价需求侧响应协同促进碳减排的电热优化调度[J]. 电网技术，2021, 45(10): 3803-3813.

ZHU

Weiye

, LUO

, HU

, et al. Optimized combined heat and power dispatch considering decreasing carbon emission by coordination of heat load elasticity and time-of-use demand response[J]. Power System Technology, 2021, 45(10): 3803-3813.

Cited in this article [1]

[16]	IPCC. 2006 IPCC guidelines for national greenhouse gas inventories[R]. IGS, Japan: The National Greenhouse Gas Inventories Program, 2006. Cited in this article [1]