“双碳”目标下我国低碳清洁氢能进展与展望

doi:10.19799/j.cnki.2095-4239.2021.0385

储能科学与技术 ›› 2022, Vol. 11 ›› Issue (2): 635-642.doi: 10.19799/j.cnki.2095-4239.2021.0385

“双碳”目标下我国低碳清洁氢能进展与展望

刘玮¹(), 万燕鸣¹, 熊亚林¹(), 刘坚²

^1.国华能源投资有限公司，中国氢能联盟研究院，北京 100007
^2.国家发展和改革委员会能源研究所，北京 100045

收稿日期:2021-08-02 修回日期:2021-09-01 出版日期:2022-02-05 发布日期:2022-02-08
通讯作者: 熊亚林 E-mail:wei.liu@chnenergy.com.cn;yalin.xiong@chnenergy.com.cn
作者简介:刘玮（1977—），男，博士，高级工程师，研究方向为新能源、氢能与燃料电池，E-mail：wei.liu@chnenergy.com.cn；通讯
基金资助:
国家重点研发计划资助项目(2018YFB1503100);国华投资公司科技创新项目（碳中和愿景下公司氢能发展路径研究）

Outlook of low carbon and clean hydrogen in China under the goal of "carbon peak and neutrality"

Wei LIU¹(), Yanming WAN¹, Yalin XIONG¹(), Jian LIU²

^1.Guohua Energy Investment Co. Ltd. , China Hydrogen Alliance Research Institute, Beijing 100007, China
^2.Energy Research Institute of national development and Reform Commission, Beijing 100045, China

Received:2021-08-02 Revised:2021-09-01 Online:2022-02-05 Published:2022-02-08
Contact: Yalin XIONG E-mail:wei.liu@chnenergy.com.cn;yalin.xiong@chnenergy.com.cn

摘要/Abstract

摘要：

2020年是氢能发展加速之年。中国国家主席习近平在第75届联合国大会期间提出，中国二氧化碳排放力争于2030年前达到峰值，努力争取2060年前实现碳中和。应对气候变化的脱碳愿景逐步成为氢能大规模部署的最重要驱动力。但我国目前在碳中和战略下氢能产业发展目标和路径尚不明确，本文应用情景分析方法和长期能源替代规划(LEAP)模型的计算，对我国交通、工业、建筑与发电等领域的氢能进行需求分析测算，研究结果表明，为实现2060年碳中和目标，我国氢气的年需求量将从目前的3342万吨增加至1.3亿吨左右，在终端能源体系中占比达20%。随着深度脱碳需求的增加和低碳清洁氢经济性的提升，氢能在工业、交通、建筑与发电等领域逐步渗透，氢能供给结构从化石能源为主的非低碳氢逐步过渡到以可再生能源为主的清洁氢，并将提供80%氢能需求。2060年，低碳清洁氢供氢体系二氧化碳减排量约17亿吨/年，约占当前我国能源活动二氧化碳总排放量的17%。

关键词: 碳中和, 低碳氢, 清洁氢, 氢能, 展望

Abstract:

2020 was the year of rapid hydrogen energy development. During the seventy-fifth United Nations General Assembly, Chinese President Xi Jinping proposed that China's carbon dioxide emission should peak by 2030 and aim for carbon neutrality by 2060. The decarbonization vision for addressing climate change has gradually become the primary driver of large-scale hydrogen energy deployment. However, the hydrogen industry's development goal and path under the carbon neutrality strategy in China remain unclear. This study analyzes and calculates the demand for hydrogen energy in China's transportation, industrial, construction, and power generating sectors using the scenario analysis method and long-range energy alternatives planning (LEAP) model. The results show that to achieve the carbon neutrality goal in 2060, the annual demand for hydrogen in China will increase from 33.42 million tons to 130 million tons, accounting for 20% of the terminal energy system. With the increasing demand for deep decarbonization and advancements in the low-carbon clean hydrogen economy; hydrogen energy has gradually penetrated the fields of industry, transportation, construction, and power generation. Hydrogen energy supply is gradually shifting away from non-low carbon-hydrogen dominated by fossil energy to clean hydrogen dominated by renewable energy, which will provide 80% of hydrogen energy demand. By 2060, the low-carbon clean hydrogen supply system will have reduced CO₂ emission by about 1.7 billion t/a, accounting for about 17% of China's total CO₂ emission today.

Key words: carbon neutrality, low-carbon hydrogen, clean hydrogen, hydrogen energy, outlook

中图分类号:

TK 91

刘玮, 万燕鸣, 熊亚林, 刘坚. “双碳”目标下我国低碳清洁氢能进展与展望[J]. 储能科学与技术, 2022, 11(2): 635-642.

Wei LIU, Yanming WAN, Yalin XIONG, Jian LIU. Outlook of low carbon and clean hydrogen in China under the goal of "carbon peak and neutrality"[J]. Energy Storage Science and Technology, 2022, 11(2): 635-642.

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参考文献 19

1	PIVOVAR B, RUSTAGI N, SATYAPAL S. Hydrogen at scale (H₂@scale): Key to a clean, economic, and sustainable energy system[J]. The Electrochemical Society Interface, 2018, 27(1): 47-52.
2	郭秀盈, 李先明, 许壮, 等. 可再生能源电解制氢成本分析[J]. 储能科学与技术, 2020, 9(3): 688-695.
	GUO X Y, LI X M, XU Z, et al. Cost analysis of hydrogen production by electrolysis of renewable energy[J]. Energy Storage Science and Technology, 2020, 9(3): 688-695.
3	翟俊香, 何广利, 熊亚林. 燃料电池系统氢气利用率的试验研究[J]. 储能科学与技术, 2020, 9(3): 684-687.
	ZHAI J X, HE G L, XIONG Y L. Experimental study on hydrogen utilization of proton exchange membrane fuel cell system[J]. Energy Storage Science and Technology, 2020, 9(3): 684-687.
4	TAIBI E, MIRANDA R, VANHOUDT W, et al. Hydrogen from renewable power: Technology outlook for the energy transition[R]. IRENA, 2018.
5	Path to hydrogen competitiveness: A cost perspective[R]. Hydrogen council, 2020.
6	中国氢能源及燃料电池产业创新战略联盟.低碳氢、清洁氢与可再生氢的标准与评价: T/CAB 0078—2020[S]. 北京: 中国产学研合作促进会, 2020.
	China Hydrogen Alliance. Standard and evaluation of low-carbon hydrogen, clean hydrogen and renewable hydrogen: T/CAB 0078—2020[S].Beijing:China Industry-University-Research Institute Collaboration Association, 2020.
7	Hydrogen, scaling up: A sustainable pathway for the global energy transition[R]. Hydrogen council, 2017.
8	The national hydrogen strategy[R]. Germany: The federal government, 2020.
9	王灿, 张雅欣. 碳中和愿景的实现路径与政策体系[J]. 中国环境管理, 2020, 12(6): 58-64.
	WANG C, ZHANG Y X. Implementation pathway and policy system of carbon neutrality vision[J]. Chinese Journal of Environmental Management, 2020, 12(6): 58-64.
10	孟翔宇, 顾阿伦, 邬新国, 等. 中国氢能产业高质量发展前景[J]. 科技导报, 2020, 38(14): 77-93.
	MENG X Y, GU A L, WU X G, et al. Prospect of high quality development of hydrogen energy industry in China[J]. Science & Technology Review, 2020, 38(14): 77-93.
11	罗佐县, 曹勇. 氢能产业发展前景及其在中国的发展路径研究[J]. 中外能源, 2020, 25(2): 9-15.
	LUO Z X, CAO Y. Development prospect of hydrogen energy industry and its development path in China[J]. Sino-Global Energy, 2020, 25(2): 9-15.
12	MARTIN A, AGNOLETTI M F, BRANGIER E. Hydrogen energy technologies' acceptance review and perspective: Toward a needs' anticipation approach[C]//Proceedings of the 20th Congress of the International Ergonomics Association (IEA 2018), 2019.
13	ZHANG L L, LONG R Y, CHEN H, et al. A review of China's Road traffic carbon emissions[J]. Journal of Cleaner Production, 2019, 207: 569-581.
14	McKinsey Company. McKinsey China auto consumer insights 2019[R]. 2020.
15	Commission on energy transformation (ETC) and Rocky Mountain Institute (RMI). China 2050: A fully developed rich zero-carbon economy[R]. 2019.
16	REMME U. The future of hydrogen[R]. IEA, 2019.
17	缪平, 姚祯, LEMMON John, 等. 电池储能技术研究进展及展望[J]. 储能科学与技术, 2020, 9(3): 670-678.
	MIAO P, YAO Z, JOHN L, et al. Current situations and prospects of energy storage batteries[J]. Energy Storage Science and Technology, 2020, 9(3): 670-678.
18	吴贤章, 尚晓丽. 可再生能源发电及智能电网储能技术比较[J]. 储能科学与技术, 2013, 2(3): 316-320.
	WU X Z, SHANG X L. A review of electrical energy storage technologies for renewable power generation and smart grids[J]. Energy Storage Science and Technology, 2013, 2(3): 316-320.
19	GIELEN D. Hydrogen: A renewable energy perspective[R]. IRENA, 2019.

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“双碳”目标下我国低碳清洁氢能进展与展望

Outlook of low carbon and clean hydrogen in China under the goal of "carbon peak and neutrality"

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