Application status and prospect of low carbon technology in iron and steel industry

XING Yi; CUI Yong-kang; TIAN Jing-lei; SU Wei; WANG Wei-li; ZHANG Xi; LIU Yi; ZHAO Xiu-juan

doi:10.13374/j.issn2095-9389.2021.08.01.001

Volume 44 Issue 4

Apr. 2022

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Article Navigation > Chinese Journal of Engineering > 2022 > 44(4): 801-811

XING Yi, CUI Yong-kang, TIAN Jing-lei, SU Wei, WANG Wei-li, ZHANG Xi, LIU Yi, ZHAO Xiu-juan. Application status and prospect of low carbon technology in iron and steel industry[J]. Chinese Journal of Engineering, 2022, 44(4): 801-811. doi: 10.13374/j.issn2095-9389.2021.08.01.001

Citation:

XING Yi, CUI Yong-kang, TIAN Jing-lei, SU Wei, WANG Wei-li, ZHANG Xi, LIU Yi, ZHAO Xiu-juan. Application status and prospect of low carbon technology in iron and steel industry[J]. Chinese Journal of Engineering, 2022, 44(4): 801-811. doi: 10.13374/j.issn2095-9389.2021.08.01.001

Citation:

XING Yi, CUI Yong-kang, TIAN Jing-lei, SU Wei, WANG Wei-li, ZHANG Xi, LIU Yi, ZHAO Xiu-juan. Application status and prospect of low carbon technology in iron and steel industry[J]. Chinese Journal of Engineering, 2022, 44(4): 801-811. doi: 10.13374/j.issn2095-9389.2021.08.01.001

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Application status and prospect of low carbon technology in iron and steel industry

doi: 10.13374/j.issn2095-9389.2021.08.01.001

XING Yi^{1, 2},
CUI Yong-kang^{1, 2},
TIAN Jing-lei³,
SU Wei^{1, 2
,
,},
WANG Wei-li^{1, 2},
ZHANG Xi^{1, 2},
LIU Yi³,
ZHAO Xiu-juan⁴

1.
School of Energy and Environmental Engineering, University of Science and Technology Beijing, Beijing 100083, China
2.
Beijing Key Laboratory of Resource-oriented Treatment of Industrial Pollutants, Beijing 100083, China
3.
HBIS Group Co., Ltd., Shijiazhuang 050023, China
4.
Hebei Vocational University of Industry and Technology, Shijiazhuang 050020, China

More Information

Corresponding author: E-mail: suwei3007@163.com
Received Date: 2021-08-01
Available Online: 2021-09-18
Publish Date: 2022-04-02

Abstract

Abstract

China proposes to achieve carbon peaking and carbon neutralization by 2030 and 2060, respectively. As a heavily carbon-based fuel industry, the carbon dioxide emission of the iron and steel industry is lower than that of the power and transportation industries. In 2020, the carbon dioxide emissions of China’s steel industry were approximately 1.98 billion tons, accounting for more than 18% of the national carbon dioxide emissions. To achieve the “carbon neutral” emission reduction target of the steel industry, the three parts of the entire process of steel production, i.e., “source–process–end,” need to be involved in the exploration of low-carbon technologies. This study summarized the low-carbon technology measures of foreign low-carbon dioxide emission projects and major domestic steel companies’ carbon peaking and carbon neutralization projects; divided and classified the low-carbon technologies in today’s steel industry from three levels, i.e., carbon dioxide emission reduction, zero carbon dioxide emission, and negative carbon dioxide emission; and summarized the carbon dioxide emission reduction, maturity, and promotion time of each low-carbon technology. In terms of carbon dioxide emission reduction, carbon dioxide emissions in the production process of the steel industry were reduced by optimizing processes and process reengineering, such as blast furnace top gas circulation technology. In terms of zero carbon dioxide emissions, hydrogen or clean electricity was used to reduce or replace coal or coke with high carbon dioxide emission factors to reduce carbon dioxide emissions from the source, such as hydrogen metallurgical technology. In terms of negative carbon dioxide emissions, carbon dioxide capture was mainly conducted in the high carbon dioxide emission intensity blast furnace ironmaking process, green recycling was performed in the steel plant, and chemical coproduction was implemented outside the plant to produce high value-added chemical products, such as methanol and ethanol. Finally, geological storage of carbon dioxide on steel near the oil field was implemented to reduce carbon dioxide emissions.
- carbon peak,
- carbon neutral,
- steel industry,
- carbon dioxide emission reduction,
- zero carbon dioxide emission,
- negative carbon dioxide emission

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References(28)

References

[1]	國家統計局. 中華人民共和國2020年國民經濟和社會發展統計公報. 中國統計, 2021(3):8 National Bureau of Statistics. Statistical communiqué of the People’s Republic of China on the 2020 national economic and social development. China Stat, 2021(3): 8
[2]	Bui M, Adjiman C S, Bardow A, et al. Carbon capture and storage (CCS): The way forward. Energy Environ Sci, 2018, 11(5): 1062 doi: 10.1039/C7EE02342A
[3]	Zhang X Y, Jiao K X, Zhang J L, et al. A review on low carbon emissions projects of steel industry in the World. J Clean Prod, 2021, 306: 127259 doi: 10.1016/j.jclepro.2021.127259
[4]	Quader M A, Ahmed S, Ghazilla R A R, et al. A comprehensive review on energy efficient CO₂ breakthrough technologies for sustainable green iron and steel manufacturing. Renewable Sustainable Energy Rev, 2015, 50: 594 doi: 10.1016/j.rser.2015.05.026
[5]	嚴珺潔. 超低二氧化碳排放煉鋼項目的進展與未來. 中國冶金, 2017, 27(2):6 Yan J J. Progress and future of ultra-low CO₂ steel making program. China Metall, 2017, 27(2): 6
[6]	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 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
[7]	薛慶國, 楊帆, 張欣欣, 等. 氧氣高爐的發展歷程及其在北京科技大學的研究進展. 工程科學學報, 2021, 43(12):1577 Xue Q G, Yang F, Zhang X X, et al. Development of oxygen blast furnace and its research progress in Beijing University of science and technology. Chin J Eng, 2021, 43(12): 1577
[8]	姚聰林, 朱紅春, 姜周華, 等. 全廢鋼連續加料電弧爐短流程碳排放計算及分析. 材料與冶金學報, 2020, 19(4):259 Yao C L, Zhu H C, Jiang Z H, et al. CO₂ emissions calculation and analysis of electric arc furnace with continuous feeding of only scrap. J Mater Metall, 2020, 19(4): 259
[9]	程威. 中國電爐市場與長材連鑄連軋. 冶金經濟與管理, 2020(1):22 Cheng W. The EAF market and the continuous casting and rolling of long products. Metall Econ Manage, 2020(1): 22
[10]	阮清華, 白苗苗. 我國長流程煉鋼與短流程煉鋼成本比較. 中國鋼鐵業, 2019(10):58 doi: 10.3969/j.issn.1672-5115.2019.10.018 Ruan Q H, Bai M M. Comparison of my country’s long-process steelmaking and short-process steelmaking costs. China Steel, 2019(10): 58 doi: 10.3969/j.issn.1672-5115.2019.10.018
[11]	王新江. 中國電爐煉鋼的技術進步. 鋼鐵, 2019, 54(8):1 Wang X J. Technological progress of EAF steelmaking in China. Iron Steel, 2019, 54(8): 1
[12]	姜周華, 姚聰林, 朱紅春, 等. 電弧爐煉鋼技術的發展趨勢. 鋼鐵, 2020, 55(7):1 Jiang Z H, Yao C L, Zhu H C, et al. Technology development trend in electric arc furnace steelmaking. Iron Steel, 2020, 55(7): 1
[13]	李彬. 基于氫氣直接還原鐵冶煉高純鐵和高純軸承鋼的基礎研究[學位論文]. 北京: 北京科技大學, 2020 Li B. Fundamental Study on the Smelting High-Purity Iron and High-Purity Bearing Steel Using Direct Reduced Iron Prepared by Hydrogen [Dissertation]. Beijing: University of Science and Technology Beijing, 2020
[14]	周翔. 直接還原工藝綜述及發展分析. 冶金經濟與管理, 2017(4):53 doi: 10.3969/j.issn.1002-1779.2017.04.016 Zhou X. Overview and development analysis of direct reduction process. Metall Econ Manage, 2017(4): 53 doi: 10.3969/j.issn.1002-1779.2017.04.016
[15]	宋贊, 李相帥, 查春和. 我國直接還原鐵工藝的發展現狀及趨勢. 冶金管理, 2020(16):22 Song Z, Li X S, Zha C H. Development status and trend of direct reduction iron technology in my country. China Steel Focus, 2020(16): 22
[16]	石禹. 世界直接還原鐵產量首次超過億噸. 冶金管理, 2020(18):30 Shi Y. The world's direct reduced iron production exceeded 100 million tons for the first time. China Steel Focus, 2020(18): 30
[17]	應自偉, 儲滿生, 唐玨, 等. 非高爐煉鐵工藝現狀及未來適應性分析. 河北冶金, 2019(6):1 Ying Z W, Chu M S, Tang J, et al. Current situation and future adaptability analysis of non-blast furnace ironmaking process. Hebei Metall, 2019(6): 1
[18]	Ren L, Zhou S, Peng T D, et al. A review of CO₂ emissions reduction technologies and low-carbon development in the iron and steel industry focusing on China. Renewable Sustainable Energy Rev, 2021, 143: 110846 doi: 10.1016/j.rser.2021.110846
[19]	唐玨, 儲滿生, 李峰, 等. 我國氫冶金發展現狀及未來趨勢. 河北冶金, 2020(8):1 Tang J, Chu M S, Li F, et al. Development status and future trend of hydrogen metallurgy in China. Hebei Metall, 2020(8): 1
[20]	Yilmaz C, Wendelstorf J, Turek T. Modeling and simulation of hydrogen injection into a blast furnace to reduce carbon dioxide emissions. J Clean Prod, 2017, 154: 488 doi: 10.1016/j.jclepro.2017.03.162
[21]	趙毅, 王永斌, 王添顥. 有機胺法吸收二氧化碳的研究進展. 再生資源與循環經濟, 2020, 13(7):26 doi: 10.3969/j.issn.1674-0912.2020.07.009 Zhao Y, Wang Y B, Wang T H. Research progress on the absorption of carbon dioxide by organic amine method. Recycl Resour Circ Econ, 2020, 13(7): 26 doi: 10.3969/j.issn.1674-0912.2020.07.009
[22]	李建光, 李進中, 欽柏豪. 模擬鋼鐵行業煙氣中CO₂捕獲與解析實驗研究. 能源環境保護, 2019, 33(5):23 doi: 10.3969/j.issn.1006-8759.2019.05.005 Li J G, Li J Z, Qin B H. Simulation of carbon dioxide capture and desorption in steel industry flue gas. Energy Environ Prot, 2019, 33(5): 23 doi: 10.3969/j.issn.1006-8759.2019.05.005
[23]	張培昆, 張震威, 王立. 用于CO₂捕集的新型石灰煅燒過程的數值分析. 工程科學學報,https://doi.org/10.13374/j.issn2095-9389.2021.03.22.002 Zhang P K, Zhang Z W, Wang L. Numerical analysis of novel lime calcination process for CO₂ capture. Chin J Eng, https://doi.org/10.13374/j.issn2095-9389.2021.03.22.002
[24]	朱榮, 王雪亮, 劉潤藻. 二氧化碳在鋼鐵冶金流程應用研究現狀與展望. 中國冶金, 2017, 27(4):1 Zhu R, Wang X L, Liu R Z. Recent progress and prospective of application of carbon dioxide in ferrous metallurgy process. China Metall, 2017, 27(4): 1
[25]	吳志連, 王輝, 楊培志, 等. 鋼鐵工業尾氣制無水乙醇商業進展. 中國新技術新產品, 2019(13):133 doi: 10.3969/j.issn.1673-9957.2019.13.077 Wu Z L, Wang H, Yang P Z, et al. Commercial progress in the production of absolute ethanol from tail gas in the iron and steel industry. New Technol New Prod China, 2019(13): 133 doi: 10.3969/j.issn.1673-9957.2019.13.077
[26]	Budinis S, Krevor S, Mac Dowell N, et al. An assessment of CCS costs, barriers and potential. Energy Strategy Rev, 2018, 22: 61
[27]	桑樹勛. 二氧化碳地質存儲與煤層氣強化開發有效性研究述評. 煤田地質與勘探, 2018, 46(5):1 doi: 10.3969/j.issn.1001-1986.2018.05.001 Sang S X. Research review on technical effectiveness of CO₂ geological storage and enhanced coalbed methane recovery. Coal Geol Explor, 2018, 46(5): 1 doi: 10.3969/j.issn.1001-1986.2018.05.001
[28]	王保登, 趙興雷, 崔倩, 等. 中國神華煤制油深部咸水層CO₂地質封存示范項目監測技術分析. 環境工程, 2018, 36(2):33 Wang B D, Zhao X L, Cui Q, et al. Environmental monitoring analysis of injected CO₂ in saline layer for Shenhua CO₂ storage project. Environ Eng, 2018, 36(2): 33