燃料电池物流车城市应用准备度评价

doi:10.19799/j.cnki.2095-4239.2020.0152

摘要/Abstract

摘要：

本文从氢能终端消费视角，总结了我国燃料电池汽车推广应用的实践路径与发展趋势，重点研究了其中推广规模最大、商业化程度最高的燃料电池物流车城市应用准备度问题，并提出了提高应对策略。介绍了燃料电池物流车主力车型与应用场景；调研、比较了我国四级代表性城市的应用现状与影响因素，利用层次分析(AHP)、灰色关联、德尔菲等方法，构建了包含地方条件、政策环境、配套设施、车辆运维、市场推广等5个维度的燃料电池物流车城市应用准备度评价指标体系，建立了评价模型，并对上海、佛山等典型城市进行了准备度测度与分析。阐述了我国燃料电池物流车城市准备度整体水平不高；四级城市中，地级城市总体最积极、省会城市最弱；各城市普遍存在政策出台密集但针对性、可实施性不强以及市场推广模式可拓展性不高等问题。提出了四级各类城市优化应用场景与适用车型匹配选择，因地制宜利用可再生能源制氢、优化布局加快建设加氢站，完善燃料电池物流车路权、停放等支持政策，以及支持商业模式创新和创新型运营商培育等提高城市准备度的对策建议。

关键词: 氢能, 燃料电池, 燃料电池物流车, 推广应用, 城市准备度

Abstract:

This study focuses on the research of Chinese city application readiness status and improvement countermeasures of fuel cell logistics vehicles (FCLVs), which have become the vehicles with the largest scale of promotion and the highest degree of commercialization among all three fuel cell vehicle (FCV) types. The study is done from the perspective of hydrogen energy terminal consumption and based on summarizing the practical path and development trend of the promotion and application of FCVs in China. First, the study introduces main vehicle models and application scenarios of FCLVs, and investigates and compares the application status and key influencing factors of some representative Chinese cities from all four kinds of the country’s city-classes. Second, five dimensions including local conditions, policy environments, supporting facilities, vehicle operation and maintenance, as well as market promotion and their sub-level factors are constructed into the evaluating index system for city readiness of FCLVs by using methods of AHP, gray correlation, and Delphi. Deploying the established evaluation model, readiness of typical cities such as Shanghai and Foshan are measured and analyzed. The result shows that the overall level of city readiness of FCLV application in China is not high. Among the four classes of cities, the prefecture-level cities are the most active but the provincial capital cities are the weakest. Common challenges behind the low city readiness include intensive but weakly-targeted and implementable policies, and low expandable market promotion mode. Countermeasures and suggestions for different kinds of cities are put forward to improve their readiness of FCLV application, including optimization of the selection strategy of appropriate matching FCLV models with application scenarios, usage of renewable energy for hydrogen production according to local conditions and acceleration of the layout and construction of hydrogenation stations, enhancement of supporting policies such as the right of way and parking of FCLVs, and support of business model innovation and innovative operators.

Key words: hydrogen energy, fuel cell, fuel cell logistics vehicle, promotion and application, city readiness

中图分类号:

TK 91

吴小员, 左哲伦, 郭诗钰, 汪　茹, 何建辉. 燃料电池物流车城市应用准备度评价[J]. 储能科学与技术, 2020, 9(5): 1574-1584.

Xiaoyuan WU, Zhelun ZUO, Shiyu GUO, Ru WANG, Jianhui HE. Evaluation on city application readiness of fuel cell logistics vehicles[J]. Energy Storage Science and Technology, 2020, 9(5): 1574-1584.

图/表 2

参考文献 35

1	中国氢能联盟. 中国氢能源及燃料电池产业白皮书[EB/OL]. [2019-07-01]. https: //
	.China Hydro-gen Alliance. White paper on China’s hydrogen energy and fuel cell industry [EB/OL]. [2019-07-01]. https: //.
2	魏学哲, 邹广楠, 孙泽昌. 燃料电池汽车中电池建模及其参数估计[J]. 电源技术, 2004(10): 13-16.
	WEI Xuezhe, ZOU Guangnan, SUN Zechang. Modelling and parameter estimation of Li-ion battery in a fuel cell vehicle[J]. Chinese Journal of Power Sources, 2004(10): 13-16.
3	马紫峰, 章冬云. 氢电混合燃料电池汽车动力系统技术[J]. 电源技术, 2008, 32(6): 357-360.
	MA Zifeng, ZHANG Dongyun. Power system technology of hydrogen-electric hybrid fuel cell vehicle[J]. Chinese Journal of Power Sources, 2008, 32(6): 357-360.
4	李正秋, 蒋燕青. 燃料电池汽车整车热管理系统研究[J]. 上海汽车, 2008(2): 4-8.
	LI Zhengqiu, JIANG Yanqing. Research of the thermal management system of fuel cell vehicle[J]. Shanghai Auto, 2008(2): 4-8.
5	王娟. 多级微纳结构Ni/Co基电催化剂的制备及氢能转换中的应用[D]. 北京: 北京化工大学, 2015.
	WANG Juan. Synthesis and application in hydrogen production and utilization of hierarchical micro/nanostructures of Ni/Co based electrocatalysts[D]. Beijing: Beijing University of Chemical Technology, 2015.
6	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 Luling, FAN Shuanshi, CHEN Qiuxiong, et al. Hydrogen storage technology: current status and prospects[J] . Energy Storage Science and Technology, 2018, 7(4): 586-594.
7	谢红梅, 艾咏梅, 陈爽, 等. 超高比表面积活性炭孔分布对氢气储存性能的影响[J]. 重庆工商大学学报(自然科学版), 2013(5): 62-66.
	XIE Hongmei, AI Yongmei, CHEN Shuang, et al. Influence of the pore size distribution of super-high specific surface area activated carbon on the hydrogen storage capacity[J]. Journal of Chongqing Technology and Business (Natural Sciences Edition), 2013(5): 62-66.
8	马建新, 刘绍军, 周伟, 等. 加氢站氢气运输方案比选[J]. 同济大学学报(自然科学版), 2008, 36(5): 615-619.
	MA Jianxin, LIU Shaojun, ZHOU Wei, et al. Comparison of hydrogen transportation methods for hydrogen refueling station[J]. Journal of Tongji University (Natural Science), 2008, 36(5): 615-619.
9	杨黎博, 何旭东. 氯碱企业富余氢气利用方案探讨[J]. 氯碱工业, 2013(11): 25-26.
	YANG Libo, HE Xudong. Discussion on the plans of chlor-alkali enterprises using surplus hydrogen[J]. Chlor-Alkali Industry, 2013(11): 25-26.
10	陈锦芳, 欧向波, 梁晓敏. 天然气重整制氢用于氢燃料电池车的能效分析[C]//2015中国燃气运营与安全研讨会论文集, 2015.CHEN Jinfang, OU Xiangbo, LIANG Xiaomin. The energy efficiency analysis of hydrogen fuel-cell vehicles with hydrogen supplied by natural gas reforming[C]//Proceedings of the 2015 China Gas Operation and Safety Symposium, 2015.
11	王仁广, 郝冬, 王晓兵, 等. 燃料电池汽车氢排放泄漏标准分析[J]. 汽车工程师, 2018(5): 18-20.
	WANG Renguang, HAO Dong, WANG Xiaobing, et al. Analysis on hydrogen discharge and leakage related standards for FCV[J]. Auto Engineer, 2018(5): 18-20.
12	张涛, 宋珂, 章桐. 基于经济性的燃料电池汽车混合度对比研究[J]. 机电一体化, 2015, 21(7): 11-16.
	ZHANG Tao, SONG Ke, ZHANG Tong. Comparative study on degree of hybridization for fuel cell electric vehicle based on economy[J]. Mechatronics, 2015, 21(7): 11-16.
13	王菊, 尤可为, 于丹. 燃料电池公共汽车在北京和上海载客示范评价[J]. 汽车技术, 2013(10): 19-21, 22.
	WANG Ju, YOU Kewei, YU Dan. Evaluation on fuel cell bus demonstration in Beijing and Shanghai[J]. Automobile Technology, 2013(10): 19-21, 22.
14	杨伟辉, 高波, 李洋. 云南省新能源汽车推广应用的问题及对策[J]. 云南科技管理, 2016, 29(2): 20-22.
	YANG Weihui, GAO Bo, LI Yang. Problems and countermeasures of new energy vehicle promotion and application in Yunnan province[J]. Yunnan Science and Technology Management, 2016, 29(2): 20-22.
15	徐慧. 基于史密斯模型的合肥市新能源汽车推广政策执行问题研究[D]. 合肥: 安徽大学, 2017.
	XU Hui. Research on the implementation of new energy vehicles promotion policy in Hefei based on Smith model[D]. Hefei: Anhui University, 2017.
16	周丽. 泸州市新能源汽车推广应用对策研究[J]. 现代商贸工业, 2015, 36(24): 42-43.
	ZHOU Li. Research on promotion strategies of new energy vehicles in Luzhou[J]. Modern Business Trade Industry, 2015, 36(24): 42-43.
17	陈尧. 我国新能源汽车推广应用模式及效应探讨[J]. 时代汽车, 2019(12): 60-61.
	CHEN Yao. Discussion on the application model and effect of new energy vehicles in China[J]. Auto Time, 2019(12): 60-61.
18	李新波, 潘增友. 我国新能源卡车全生命周期成本费用分析[J]. 商用汽车, 2017(8): 62-63.
	LI Xinbo, PAN Zengyou. Analysis of the TCO of domestic new energy vehicle[J]. Commercial Vehicle, 2017(8): 62-63.
19	张潇文. 新能源汽车在城市物流配送的商业模式应用及经济性分析[D]. 北京: 北京交通大学, 2016.
	ZHANG Xiaowen. Economic analysis of application new energy logistics business model[D]. Beijing: Beijing Jiaotong University, 2016.
20	高婧. 不同应用场景下燃料电池与纯电动汽车成本对比分析[J] . 时代汽车, 2019(18): 63-64.
	GAO Jing. Comparative analysis of the cost of fuel cell and battery electric vehicle in different application scenarios[J]. Auto Time, 2019(18): 63-64.
21	高工产研氢电研究所. 2019年中国氢燃料电池汽车产量3018辆[EB/OL]. [2020-01-08]. http: //.
	Gao Gong Industry Institute. China’s output of hydrogen fuel cell vehicles in 2019 was 3, 018 [EB/OL]. [2020-01-08]. http: //.
22	盖世汽车. 郑州宇通客车李高鹏: 新能源客车技术进步与可持续发展[EB/OL]. [2020-01-14]. https: //xw. qq. com/cmsid/20200114A0F56100.
	Gasgoo. Li Gaopeng of Zhengzhou Yutong Bus: Technical progress and sustainable development of new energy buses[EB/OL]. [2020-01-14]. https: //xw. qq. com/cmsid/20200114A0F56100.
23	中国经济网. 我国汽车保有量2.5亿辆[EB/OL]. [2019-07-04]. http: //auto. ce. cn/auto/gundong/201907/04/t20190704_32523168.
	shtml.
	China Economic Net. China’s car ownership is 250 million[EB/OL]. [2019-07-04]. http: //auto. ce. cn/auto/gundong/201907/04/t20190704_32523168.
	shtml.
24	经济参考报. 万亿级城市配送市场或迎变革[EB/OL]. [2017-04-25]. http: //field. 10jqka. com. cn/20170425/c598113363. shtml.
	Economic Information Daily. Trillion level city distribution market may be facing change[EB/OL]. [2017-04-25]. http: //field. 10jqka. com. cn/20170425/c598113363. shtml.
25	新能源汽车国家大数据联盟. 全国氢燃料电池汽车数据分析报告[EB/OL]. [2020-02-05]. https: //mp. weixin. qq. com/s/mhOohzmrS1TY4ooRZXuGsA.
	National Big Data Alliance of New Energy Vehicles. National hydrogen fuel cell vehicle data analysis report[EB/OL]. [2020-02-05]. https: //mp. weixin. qq. com/s/mhOohzmrS1TY4ooRZXuGsA.
26	新能源汽车国家大数据联盟. 全国新能源物流车数据分析报告[EB/OL]. [2020-02-18]. https: //mp. weixin. qq. com/s/L_7KxHrjarqsdmCZGLQSaw.
	National Big Data Alliance of New Energy Vehicles. National new energy logistics vehicle data analysis report [EB/OL]. [2020-02-18]. https: //mp. weixin. qq. com/s/L_7KxHrjarqsdmCZGLQSaw.
27	符钢战, 梁炉, 唐茂钢, 等. 汽车产业分析[M]. 上海: 同济大学出版社, 2018: 20-80.
	FU Gangzhan, LIANG Lu, TANG Maogang, et al. Automotive industry analysis[M]. Shanghai: Tongji University Press, 2018: 20-80.
28	张震, 刘雪梦. 新时代我国15个副省级城市经济高质量发展评价体系构建与测度[J]. 经济问题探索, 2019(6): 20-31.
	ZHANG Zhen, LIU Xuemeng. Construction and measurement of the evaluation system of high-quality economic development of 15 sub-provincial cities in China in the new era[J]. Inquiry into Economic Issues, 2019(6): 20-31.
29	何琴. 基于AHP的智慧城市建设水平评价模型及实证[J]. 统计与决策, 2019(19): 64-67.
	HE Qin. Evaluation model and demonstration of smart city construction level based on AHP[J]. Statistics & Decision, 2019(19): 64-67.
30	王春枝, 斯琴. 德尔菲法中的数据统计处理方法及其应用研究[J] . 内蒙古财经学院学报(综合版), 2011, 9(4): 92-96.
	WANG Chunzhi, SI Qin. A study of data statistical processing method of Delphi method and its application[J]. Journal of Inner Mongolia Finance and Economics College, 2011, 9(4): 92-96.
31	崔杰, 党耀国, 刘思峰. 基于灰色关联度求解指标权重的改进方法[J]. 中国管理科学, 2008(5): 143-147.
	CUI Jie, DANG Yaoguo, LIU Sifeng. An improved approach for determining weights of attributes in decision making based on grey incidence[J]. Chinese Journal of Management Science, 2008(5): 143-147.
32	孙逢春, 孙立清, 白文杰. 氢燃料电池技术及其在汽车领域的应用现状[C]//全国氢能学术会议, 2001.SUN Fengchun, SUN Liqing, BAI Wenjie. Hydrogen fuel cell technology and its current status of application in the field of vehicle[C]//Chinese Hydrogen Energy Conference, 2001.
33	邢春礼, 费颖, 韩俊, 等. 氢能与燃料电池能源系统[J]. 节能技术, 2009, 27(3): 287-290.
	XING Chunli, FEI Ying, HAN Jun, et al. Hydrogen energy and fuel cell energy system[J]. Energy Conservation Technology, 2009, 27(3): 287-290.
34	冯丹, 胡利明, 宗营. 氢能燃料电池发展关键路径分析[J]. 化工时刊, 2018(9): 36-38.
	FENG Dan, HU Liming, ZONG Ying. The critical path analysis of hydrogen fuel cells[J]. Chemical Industry Times, 2018(9): 36-38.
35	国家能源局. 关于《中华人民共和国能源法(征求意见稿)》公开征求意见的公告[EB/OL]. [2020-04-10]. http: //.
	National energy administration. Announcement on public consultation on “Energy Law of the People’s Republic of China (Consultation Draft)”[EB/OL]. [2020-04-10]. http: //.

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