全球主要国家氢能发展战略分析

doi:10.19799/j.cnki.2095-4239.2022.0132

摘要/Abstract

摘要：

全球氢能已进入产业化快速发展新阶段，欧美日韩等20多个主要经济体已将发展氢能提升到国家战略层面，相继制定发展规划、路线图以及相关扶持政策，加快产业化发展进程。本文分析总结了日本、德国、韩国、美国、澳大利亚等国家氢能发展战略，提炼了深度脱碳、保障能源安全和实现经济增长3个发展氢能核心驱动力；基于碳中和目标成为国际共识以及全球地缘政治的扰动分析了氢能发展定位、氢源结构过渡、多元应用场景、产业发展阶段4个方面的趋势。主要国家统筹考虑资源禀赋、技术和产业基础、市场需求等多方面因素，因地制宜推动氢能技术攻关与产业化发展，对我国氢能产业高质量具有重要参考价值。本文从加强国家层面氢能战略引导、加大关键核心技术攻关力度和加速多元化场景示范应用3个方面提出了贯彻落实《氢能产业发展中长期发展规划(2021—2035年)》的建议。

关键词: 氢能, 低碳, 政策研究, 发展战略

Abstract:

The global hydrogen energy industry has entered a new era of rapid industrialization. More than 20 major economies, such as Europe, the United States, Japan, and South Korea, have elevated the development of hydrogen energy to the national strategic level and have successively formulated development plans, roadmaps, and related support policies to accelerate industrialization. This paper analyzes and summarizes the hydrogen development strategies of Japan, Germany, South Korea, the United States, and Australia and refines the three core driving forces for hydrogen development: deep decarbonization, ensuring energy security, and achieving economic growth. The trends of hydrogen development orientation, hydrogen source structure transition, hydrogen application scenarios, and industrial development stages are obtained based on the international consensus on the goal of carbon neutrality and the disruption of global geopolitics. Major countries consider overall resource endowment, technology and industrial base, market demand, and other factors, and promote hydrogen technology research and industrialization development using local conditions, which has important reference value for China's high quality hydrogen industry. This paper proposes three approaches to implementing the "Medium and Long-Term Development Plan for Hydrogen Energy Industry Development (2021-2035)": strengthening national level hydrogen energy strategy guidance; increasing key core technology research efforts; and accelerating the demonstration and application of diverse scenarios.

Key words: hydrogen energy, low carbon, policy research, development strategy

中图分类号:

TK 91

万燕鸣, 熊亚林, 王雪颖. 全球主要国家氢能发展战略分析[J]. 储能科学与技术, 2022, 11(10): 3401-3410.

Yanming WAN, Yalin XIONG, Xueying WANG. Strategic analysis of hydrogen energy development in major countries[J]. Energy Storage Science and Technology, 2022, 11(10): 3401-3410.

图/表 13

图1

表1

图2

表2

表3

表4

表5

表6

图3

图4

表7

图5

图6

参考文献 33

1	Ludwig-Bölkow-Systemtechnik GmbH (LBST). International Hydrogen Strategies[R/OL]. Germany: LBST, 2020. [2022-02-24]. https://www.weltenergierat.‍de/wp-content/uploads/2020/09/WEC_H2_Strategies_finalreport_200922.pdf.
2	中国氢能联盟. 中国氢能源及燃料电池产业发展报告2020[R]. 北京: 中国氢能联盟, 2021.China Hydrogen Alliance. China hydrogen energy and fuel cell industry development report 2020[R]. Beijing: China Hydrogen Alliance, 2021.
3	Hydrogen Council. Policy tool box for low carbon and renewable hydrogen[R/OL]. [2022-02-24]. https://hydrogencouncil.com/en/policy-toolbox-for-low-carbon-and-renewable-hydrogen/
4	熊华文, 符冠云. 全球氢能发展的四种典型模式及对我国的启示[J]. 环境保护, 2021, 49(1): 52-55.
	XIONG H W, FU G Y. Four typical models of global hydrogen energy industries development and their references for China[J]. Environmental Protection, 2021, 49(1): 52-55.
5	Ministry of Economy, Trade and Industry (METI). Basic hydrogen strategy (key points)[R/OL]. Japan: METI, 2017 [2022-02-24]. https://climatepolicydatabase.org/policies/basic-hydrogen-strategy.
6	Ministry of Economy, Trade and Industry (METI). The strategic road map for hydrogen and fuel cells-industry-academia-government action plan to realize a "hydrogen society"[R/OL]. Japan: METI, 2019 [2022-02-24]. https://www.hydrogenenergysupplychain.com/wp-content/uploads/2021/07/0312_002b.pdf.
7	Ministry of Economy, Trade and Industry (METI). Hydrogen Energy White Paper[R/OL]. Japan: METI, 2015 [2022-02-24]. https://www.enecho.meti.go.jp/about/whitepaper/2015/.
8	New Energy and Industrial Technology Development Organization (NEDO). Green Japan, Green Innovation[EB/OL]. [2022-02-24]. https://www.meti.go.jp/english/policy/energy_environment/global_warming/roadmap/innovation/index.html
9	Ministry of Economy, Trade and Industry (METI). The sixth strategic energy plan[EB/OL]. [2022-02-24]. https://www.meti.go.jp/english/press/2021/1022_002.html
10	International Energy Agency (IEA). Hydrogen economy roadmap of Korea[EB/OL]. [2022-02-24]. https://www.iea.org/policies/6566-korea-hydrogen-economy-roadmap-2040
11	YOON Y G. Current status of the Korean hydrogen economy[EB/OL]. 2020 [2022-02-24]. https://www.wko.at/service/aussenwirtschaft/praesentation-yoon-yeo-gwang.pdf
12	Ministry of Environment (South Korea). The first step towards leapfrogging a leading hydrogen economy[EB/OL]. 2021 [2022-02-24]. http://www.me.go.kr/home/web/board/read.do?boardCategoryId=&boardId=1490210&boardMasterId=1&decorator=‍&maxIndexPages=10&maxPageItems=10&menuId=10525&orgCd=‍&pagerOffset=30&searchKe=&searchValue.
13	Federal Ministry of Economics and Technology (Germany). The national hydrogen strategy[EB/OL]. 2020 [2022-02-24]. https://www.‍bmwi.‍de/Redaktion/EN/Publikationen/Energie/thenational-hydrogen-strategy.html.
14	Fuel Cells and Hydrogen Joint Undertaking (FCH-JU). Hydrogen roadmap Europe[R/OL]. Brussels: FCH-JU, 2019 [2022-02-24]. https://www.fch.europa.eu/sites/default/files/Hydrogen%20Roadmap%20Europe_Report.pdf
15	Department of Energy (DOE). A national vision of America's transition to a hydrogen economy[R/OL]. United States: DOE, 2002 ‍[2022-02-24]. ‍https://www.‍energy.‍gov/eere/vehicles/downloads/national-vision-americas-transition-hydrogen-economy-2030-and-beyond
16	Department of Energy (DOE). National hydrogen energy roadmap[R/OL]. United States: DOE, 2002 [2022-02-24]. https://www.hydrogen.energy.gov/pdfs/national_h2_roadmap.pdf
17	Department of Energy (DOE). Energy department hydrogen program plan[R/OL]. United States: DOE, 2020 [2022-02-24]. https://www.hydrogen.energy.gov/pdfs/hydrogen-program-plan-2020.pdf
18	Department of Energy (DOE). Foundational science for carbon-neutral hydrogen technologies[EB/OL]. [2022-02-24]. https://www.‍osti.‍gov/biblio/1822215-basic-energy-sciences-roundtable-foundational-science-carbon-neutral-hydrogen-technologies-brochure
19	United States Congress. Infrastructure investment and jobs act [R/OL]. United States: United States Congress, 2020 [2022-02-24]. ‍https://www.‍congress.‍gov/bill/117th-congress/house-bill/3684/text.
20	Fuel Cell & Hydrogen Energy Association (FCHEA). Roadmap to a U.S. Hydrogen Economy[R/OL]. United States: FCHEA, 2020 [2022-02-24]. https://www.fchea.org/us-hydrogen-study.
21	COAG Energy Counicl. National hydrogen strategy[R/OL]. Australia: COAG Energy Counicl Hydrogen Working Group, 2019 [2022-02-24]. https://www.industry.gov.au/sites/default/files/2019-11/australias-national-hydrogen-strategy.pdf.
22	Queensland Government Cabinet. Queensland hydrogen industry strategy 2019-2024[R/OL]. Australia: Queensland Government Cabinet, 2019 [2022-02-24]. https://cabinet.qld.gov.au/documents/2019/May/HydrInd/Queensland%20Hydrogen%20Industry%20Strategy%202019-2024.docx.
23	International Energy Agency (IEA). South Australia's hydrogen action plan[EB/OL]. [2022-02-24]. https://www.iea.org/policies/12121-south-australia-hydrogen-action-plan.
24	Victoria State Government. Renewable hydrogen industry development plan[R/OL]. Australia Victoria State Government, 2021 [2022-02-24]. https://www.energy.vic.gov.au/__data/assets/pdf_file/0021/513345/Victorian-Renewable-Hydrogen-Industry-Development-Plan.pdf.
25	刘玮, 万燕鸣, 熊亚林, 等. “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.
	LIU W, WAN Y M, XIONG Y L, et al. 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.
26	李璐伶, 樊栓狮, 陈秋雄, 等. 储氢技术研究现状及展望[J]. 储能科学与技术, 2018, 7(4): 586-594.
	LI L L, FAN S S, CHEN Q X, et al. Hydrogen storage technology: Current status and prospects[J]. Energy Storage Science and Technology, 2018, 7(4): 586-594.
27	俞红梅, 邵志刚, 侯明, 等. 电解水制氢技术研究进展与发展建议[J]. 中国工程科学, 2021, 23(2): 146-152.
	YU H M, SHAO Z G, HOU M, et al. Hydrogen production by water electrolysis: Progress and suggestions[J]. Strategic Study of CAE, 2021, 23(2): 146-152.
28	俞红梅, 衣宝廉. 电解制氢与氢储能[J]. 中国工程科学, 2018, 20(3): 58-65.
	YU H M, YI B L. Hydrogen for energy storage and hydrogen production from electrolysis[J]. Engineering Science, 2018, 20(3): 58-65.
29	中国氢能联盟. 中国氢能源及燃料电池产业白皮书(2019)[R]. 北京: 中国氢能联盟, 2019.China Hydrogen Alliance. China hydrogen energy and fuel cell industry white paper 2019[R]. Beijing: China Hydrogen Alliance, 2019.
30	刘应都, 郭红霞, 欧阳晓平. 氢燃料电池技术发展现状及未来展望[J]. 中国工程科学, 2021, 23(4): 162-171.
	LIU Y D, GUO H X, OUYANG X P. Development status and future prospects of hydrogen fuel cell technology[J]. Strategic Study of CAE, 2021, 23(4): 162-171.
31	曹湘洪, 魏志强. 氢能利用安全技术研究与标准体系建设思考[J]. 中国工程科学, 2020, 22(5): 144-151.
	CAO X H, WEI Z Q. Technologies for the safe use of hydrogen and construction of the safety standards system[J]. Strategic Study of CAE, 2020, 22(5): 144-151.
32	Hydrogen Europe. Green hydrogen for a European green deal-a 2x40 GW initiative[R/OL]. Brussels: Hydrogen Europe, 2020 [2022-02-24]. ‍https://dii-desertenergy.‍org/wp-content/uploads/2020/04/2020-04-01_Dii_Hydrogen_Studie2020_v13_SP.pdf.
33	国家发展改革委, 国家能源局. 氢能产业中长期发展规划(2021-2035)[EB/OL]. [2022-03-25]. http://zfxxgk.nea.gov.cn/2022-03/23/c_1310525630.htm.
	NDRC & NEA. Medium and long term plan for the development of hydrogen energy industry (2021-2035)[EB/OL].[2022-03-25]. http://zfxxgk.nea.gov.cn/2022-03/23/c_1310525630.htm.

项目	深度脱碳	经济增长	能源安全
代表国家	德国、法国、英国、荷兰	韩国、澳大利亚、俄罗斯	日本
模式特点	结合可再生能源制氢进行多场景示范应用，以能源结构清洁化转型、产业脱碳为核心目的	拥有先进核心技术或氢源优势，通过技术出口或者氢资源出口，以打造新经济增长极为目标，打造氢能产业集群	开展国际间氢资源供应链与贸易，国内进行发电等综合示范应用，替代石油、煤炭等化石资源
发展概括	应对气候变化为主快速推进项目示范	培育经济增长点	保障能源安全与技术优势

项目		2018年	2022年	2040年
氢燃料电池汽车 (国内)		1800台 (900台)	8.1万台 (6.7万台)	620万台 (290万台)
燃料电池	大型固定式燃料电池 (国内)	307 MW (307 MW)	1.5 GW (1 GW)	15 GW (8 GW)
燃料电池	家庭、建筑用	7 MW	50 MW	2.1 GW
加氢站		14座	310座	1200座
氢气供给		13万t/年	47万t/年	526万t/年以上
氢气价格		8000韩元/kg	6000韩元/kg	3000韩元/kg

氢能产业链环节		具体行动
氢气制取		提升可再生能源制氢效率，为电解水制氢价格制定财税优惠措施；探索新商业模式，并完善监管；加大对可再生能源电解水制氢系统的投资；加快推进海上风电制氢的研究示范
产业支撑	研究与创新	制定德国联合氢能路线图；开展绿氢示范应用；开展“氢能技术2030”专项研究；设立氢能政策建议咨询项目；进行氢能在航空、航运方面的技术研究与推进；强化氢能公共教育与培训
	欧盟层面需求	支持标准法规的制定；建设欧洲共同利益(IPCEI)氢能项目；实施欧盟氢能倡议；建立泛欧氢能合资公司
	国际合作	建立能源伙伴关系，推动先进氢能技术的出口；推进与氢能国家组织的合作；开展国际合作示范项目；加强与化石能源出口国及重点企业的对话
应用	交通运输	利用绿氢替代传统燃油；持续实施NIP计划；推动加氢基础设施建设；鼓励氢能交通工具参与跨境运输；支持建立具有成本竞争力的燃料电池系统供应链；支持零排放车辆的部署；倡导以碳排放为计量基础的卡车通行费差异化；倡导氢能标准国际化与统一化
	工业原料/燃料	推动清洁氢在钢铁、化工等领域作为工业燃料使用；创造对低碳排放工艺和氢基产品的需求；制定钢铁、化工、物流、航空业等领域的长期脱碳战略
	供热	持续执行能源效率激励计划；为氢能热电联产系统部署提供资金支持
	基础设施建设	对现有基础设施进行评估；加强电网、天然气管网和供暖基础设施的协调性；按需新建基础设施

项	目前	2022年	2025年	2030年
氢能需求/(百万t/年)	11	12	13	17
FCEV销售量/(辆/年)	2500	30000	150000	1200000
燃料电池叉车/辆	25000	50000	125000	300000
加氢站/座	63	165	1000	4300
年度投资额度/亿美元	—	10	20	80

氢能价值链	商业模式	政策/监管	技术研发
制氢	获取廉价可再生电力；打造制氢基地	—	提高制氢工厂效率和固定资产寿命；研发固体氧化物电解水、甲烷裂解等新兴技术
氢储运	氢消纳点就近制氢	修订燃气管道法规以运输氢气	研发液氢基础技术、纯氢管道材料、高效压缩技术和地质存储技术
加氢站	建立加氢站合资企业，进行加氢站推广工作	车辆排放标准和燃料电池汽车激励政策	—
工业原料	—	清洁氢作为工业原料的激励政策	—
出口	就氢气出口优惠关税进行谈判；签订政府间氢能出口协议	可再生能源土地使用政策；与国际海事组织等机构合作，确保氢能运输监管合理	—
合成燃料	—	制定低排放燃料供应目标；航空和航运业使用合成燃料的激励措施	投资可再生能源电解水制氢合成燃料技术
供热	与他国政府协调，为跨国家电制造商提供市场参考	明确天然气的浓缩和排放政策；立法制造和使用标准化、易于转换的电器	研发纯氢电器；持续示范天然气掺氢；进行纯氢管道可行性研究