Low-carbon green development path and practice of the iron and steel industry

LI Yiren; XING yi; SUN Yujia; TIAN Jinglei

doi:10.13374/j.issn2095-9389.2022.11.03.003

Volume 45 Issue 9

Sep. 2023

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LI Yiren, XING yi, SUN Yujia, TIAN Jinglei. Low-carbon green development path and practice of the iron and steel industry[J]. Chinese Journal of Engineering, 2023, 45(9): 1583-1591. doi: 10.13374/j.issn2095-9389.2022.11.03.003

Citation:

LI Yiren, XING yi, SUN Yujia, TIAN Jinglei. Low-carbon green development path and practice of the iron and steel industry[J]. Chinese Journal of Engineering, 2023, 45(9): 1583-1591. doi: 10.13374/j.issn2095-9389.2022.11.03.003

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Low-carbon green development path and practice of the iron and steel industry

doi: 10.13374/j.issn2095-9389.2022.11.03.003

LI Yiren^{1, 2},
XING yi³,
SUN Yujia^2
,,
TIAN Jinglei^{2
,
,}

1.
School of Economics and Management, University of Science and Technology Beijing, Beijing 100083, China
2.
HBIS Group Co., Ltd., Shijiazhuang 050023, China
3.
School of Energy and Environmental Engineering, University of Science and Technology Beijing, Beijing 100083, China

More Information

Corresponding author: E-mail：tianjinglei@hbisco.com
Received Date: 2022-11-03
Available Online: 2023-04-25
Publish Date: 2023-09-25

Abstract

Abstract

Coping with climate change is a common topic facing the world. The steel industry is an important basic industry of the national economy; however, it is also a resource-intensive and typical high-carbon-emission industry. Low-carbon green is the inevitable choice and the only way for its high-quality development. Under the background that the world has entered a new stage of low-carbon development, this study analyzes the historical trend that the transfer of steel industry centers in the world is accompanied by technological change. In the new stage that China has become a steel center and will continue for a long time, it is faced with the demand for a significant reduction in carbon emissions, intensity, energy consumption, green trade barriers (such as carbon border tax), green procurement pressure, and breakthrough technology research and development challenges. This study outlines the low-carbon development plan and path of the international and domestic steel industry and focuses on the analysis of the exploration and contribution made by China’s steel industry in low-carbon green development in recent years. This study also aims to analyze the transformation of the future steel industry to low-carbon development based on the continuation of the practical achievements of green manufacturing with practical cases and summarize four types of development paths, which provide practical cases for iron and steel enterprises to help achieve the national goal of “carbon peak, carbon neutral” . The first path is to transition from ultralow-emission-centered development to pollution and carbon reduction and promote sintering flue gas circulation and high-proportion pellet smelting, selective circulation purification of sintering flue gas and waste heat utilization, and other technologies. The second path is to reform the energy structure with hydrogen energy as the center in the energy field, research and develop low-cost, large-scale hydrogen production technology, build a network of hydrogen refueling stations, accelerate the construction of green logistics systems, and lead the industry development in the practice of exploring hydrogen metallurgy technology. The third path is to rely on the cycle sustainability of steel materials (starting from the entire industrial chain and upstream and downstream coordination), utilize a full life cycle assessment platform and products, create a low-carbon green industrial ecosystem, and comprehensively promote green manufacturing in combination with upstream and downstream key enterprises. The fourth path is to conduct cooperative research and development of breakthrough technologies (such as carbon capture utilization and storage and other cutting-edge technologies) to strengthen the cooperation between industry, university, and research and integrate global innovation resources. Finally, based on the current low-carbon development trend of the steel industry and the proposed low-carbon development paths, this study analyzes the impact of international situations (such as the EU carbon border regulation mechanism on China’s steel industry), promotes the full life cycle assessment of steel materials, encourages the construction of hydrogen energy development strategies and energy source systems, establishes a green industrial chain, and recommends collaborative carbon reduction.
- iron and steel industry,
- low-carbon green,
- practice,
- route,
- cases

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References(25)

References

[1]	于勇. 鋼鐵軌跡. 北京: 冶金工業出版社, 2021 Yu Y. Development Path of Steel Industry. Beijing: Metallurgical Industry Press, 2021
[2]	李擁軍, 史慧恩, 高鵬. 美國鋼鐵工業發展對我們的啟示. 中國鋼鐵業, 2008(7):18 doi: 10.3969/j.issn.1672-5115.2008.07.007 Li Y J, Shi H E, Gao P. Enlightenment from the development of American iron and steel industry. China Steel, 2008(7): 18 doi: 10.3969/j.issn.1672-5115.2008.07.007
[3]	于勇. 鋼鐵讓世界更加美好. 中國鋼鐵業, 2019(9):14 doi: 10.3969/j.issn.1672-5115.2019.09.007 Yu Y. Steel makes the world better. China Steel, 2019(9): 14 doi: 10.3969/j.issn.1672-5115.2019.09.007
[4]	鄭國棟, 陳其慎, 邢佳韻, 等. 典型國家鋼鐵產業發展路徑與啟示. 中國國土資源經濟, 2021, 34(8):51 Zheng G D, Chen Q S, Xing J Y, et al. The development path and enlightenment of the steel industry in typical countries. Nat Resour Econ China, 2021, 34(8): 51
[5]	IEA. 鋼鐵技術路線圖[EB/OL]. 科技論文在線(2020-10-01) [2022-10-05]. https://www.iea.org/reports/iron-and-steel-technology-roadmap IEA. Iron and steel technology roadmap [EB/OL]. Sciencepaper Online (2020-10-01) [2022-10-05]. https://www.iea.org/reports/iron-and-steel-technology-roadmap
[6]	項目綜合報告編寫組. 《中國長期低碳發展戰略與轉型路徑研究》綜合報告. 中國人口·資源與環境, 2020, 30(11):1 Project comprehensive report preparation team. Comprehensive report on China’s long-term low-carbon development strategy and transformation path. China Popul Resour Environ, 2020, 30(11): 1
[7]	許英明, 李曉依. 歐盟碳邊境調節機制對中歐貿易的影響及中國對策. 國際經濟合作, 2021(5):25 Xu Y M, Li X Y. Potential implications of EU’s Carbon Border Adjustment Mechanism for Sino-EU trade and suggested policies for China. J Int Econ Coop, 2021(5): 25
[8]	王優酉, 張曉通, 鄒磊, 等. 歐盟碳稅新政: 內容、影響及應對. 國際經濟合作, 2021(5):13 Wang Y Y, Zhang X T, Zou L, et al. An introduction to the content and implications of EU’s Carbon Border Adjustment Mechanism and proposed countermeasures for China. J Int Econ Coop, 2021(5): 13
[9]	李新創, 李晉巖, 霍咚梅, 等. 關于中國鋼鐵行業產品碳足跡評價標準化工作的思考. 中國冶金, 2021, 31(12):1 Li X C, Li J Y, Huo D M, et al. Concerns on drafting standard for evaluating product carbon footprint of China’s steel industry. China Metall, 2021, 31(12): 1
[10]	王新東, 張弛, 孫宇佳, 等. 河鋼唐鋼新區綠色制造技術應用實踐. 環境工程, 2022, 40(7):179 doi: 10.13205/j.hjgc.202207026 Wang X D, Zhang C, Sun Y J, et al. Application practice of green manufacturing technology in tangsteel new district of hbis group. Environ Eng, 2022, 40(7): 179 doi: 10.13205/j.hjgc.202207026
[11]	李建新, 王新東, 李雙江. 河鋼煉鋼技術進步與展望. 煉鋼, 2019, 35(4):1 Li J X, Wang X D, Li S J. Progress and prospects of steelmaking technology in Hesteel. Steelmaking, 2019, 35(4): 1
[12]	王新東, 李建新, 胡啟晨. 基于高爐爐料結構優化的源頭減排技術及應用. 鋼鐵, 2019, 54(12):104 Wang X D, Li J X, Hu Q C. Application practice of source and process sulfur-nitrate reduction technology based on optimization of blast furnace charge structure. Iron &Steel, 2019, 54(12): 104
[13]	王新東, 田京雷, 宋程遠. 大型鋼鐵企業綠色制造創新實踐與展望. 鋼鐵, 2018, 53(2):1 doi: 10.13228/j.boyuan.issn0449-749x.20170533 Wang X D, Tian J L, Song C Y. Innovative practice technology and outlook in large iron and steel enterprise green manufacturing. Iron &Steel, 2018, 53(2): 1 doi: 10.13228/j.boyuan.issn0449-749x.20170533
[14]	王新東. 以“綠色化、智能化、品牌化”為目標規劃設計河鋼唐鋼新區. 鋼鐵, 2021, 56(2):12 doi: 10.13228/j.boyuan.issn0449-749x.20200554 Wang X D. Planning and design of HBIS Group Tangsteel new district with goal of “Green, Intelligent and Brand”. Iron &Steel, 2021, 56(2): 12 doi: 10.13228/j.boyuan.issn0449-749x.20200554
[15]	于勇. 品牌建設照亮高質量發展之路. 經濟, 2020(8):71 Yu Y. Brand building illuminates the road of high-quality development. Economy, 2020(8): 71
[16]	王新東. 河鋼新發展階段技術升級的路徑與措施. 河北冶金, 2022(1):1 doi: 10.13630/j.cnki.13-1172.2022.0101 Wang X D. Paths and measures of technology upgrading in the new development stage of hbis. Hebei Metall, 2022(1): 1 doi: 10.13630/j.cnki.13-1172.2022.0101
[17]	王新東, 侯長江, 田京雷. 鋼鐵行業煙氣多污染物協同控制技術應用實踐. 過程工程學報, 2020, 20(9):997 doi: 10.12034/j.issn.1009-606X.219317 Wang X D, Hou C J, Tian J L. Application and practice of multi-pollutant cooperative control technology for flue gas in iron and steel industry. Chin J Process Eng, 2020, 20(9): 997 doi: 10.12034/j.issn.1009-606X.219317
[18]	萬蕓菲, 崔陽陽, 吳雪芳, 等. 京津冀區域二氧化碳排放特征及其與大氣污染物協同減排潛力分析. 首都師范大學學報(自然科學版), 2022, 43(4):46 doi: 10.19789/j.1004-9398.2022.04.008 Wan Y F, Cui Y Y, Wu X F, et al. Characteristics of carbon dioxide emission in Beijing-Tianjin-Hebei region and its synergistic reduction potential with air pollutants. J Cap Norm Univ (Nat Sci Ed), 2022, 43(4): 46 doi: 10.19789/j.1004-9398.2022.04.008
[19]	薛濤, 劉俊, 張強, 等. 2013—2017年中國PM_2.5污染的快速改善及其健康效益. 中國科學:地球科學, 2020, 50(4):441 doi: 10.1360/SSTe-2019-0245 Xue T, Liu J, Zhang Q, et al. Rapid improvement of PM_2.5 pollution and associated health benefits in China during 2013-2017. Sci Sin (Terrae), 2020, 50(4): 441 doi: 10.1360/SSTe-2019-0245
[20]	朱廷鈺, 劉霄龍. 中國鋼鐵行業“超低排放”向“減污降碳”過渡的技術思考. 過程工程學報, 2022, 22(10): 1360 Zhu T Y, Liu X L. Technical considerations on the transition from "ultra-low emissions" to "pollution reduction and carbon reduction" in China's steel industry Chin J Process Eng, 2022, 22(10): 1360
[21]	車彥民, 曹莉霞, 劉金哲. 氫的大規模制備及在鋼鐵行業的應用和展望. 中國冶金, 2022, 32(9):1 doi: 10.13228/j.boyuan.issn1006-9356.20220201 Che Y M, Cao L X, Liu J Z. Large scale hydrogen production and its application and prospect in iron and steel industry. China Metall, 2022, 32(9): 1 doi: 10.13228/j.boyuan.issn1006-9356.20220201
[22]	魯雄剛, 張玉文, 祝凱, 等. 氫冶金的發展歷程與關鍵問題. 自然雜志, 2022, 44(4):251 doi: 10.3969/j.issn.0253-9608.2022.04.001 Lu X G, Zhang Y W, Zhu K, et al. Development and key problems of hydrogen metallurgy. Chin J Nat, 2022, 44(4): 251 doi: 10.3969/j.issn.0253-9608.2022.04.001
[23]	張建良. 碳中和背景下的低碳煉鐵與氫冶金. 第十三屆中國鋼鐵年會論文集. 重慶, 2022: 49 Zhang J L. Low carbon ironmaking and hydrogen metallurgy in the context of carbon neutralization // Proceedings of the 13th China Iron and Steel Annual Conference. Chongqing, 2022: 49
[24]	朱國海. 高爐富氫還原研究. 鋼鐵, 2020, 55(10):1 doi: 10.13228/j.boyuan.issn0449-749x.20190532 Zhu G H. A review on hydrogen-enriched reduction in blast furnace. Iron Steel, 2020, 55(10): 1 doi: 10.13228/j.boyuan.issn0449-749x.20190532
[25]	王廣, 王靜松, 左海濱, 等. 高爐煤氣循環耦合富氫對中國煉鐵低碳發展的意義. 中國冶金, 2019, 29(10):1 doi: 10.13228/j.boyuan.issn1006-9356.20190107 Wang G, Wang J S, Zuo H B, et al. Effect of blast furnace gas recycling with hydrogen injection on low carbon development of Chinese ironmaking. China Metall, 2019, 29(10): 1 doi: 10.13228/j.boyuan.issn1006-9356.20190107