未来炼铁技术发展方向探讨以及宝钢探索实践

doi:10.13228/j.boyuan.issn0449-749x.20200212

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Abstract It is of great significance for iron and steel enterprises to accurately grasp the development direction of iron making technology in the future to realize transformation, upgrading and sustainable development. Based on the systematic summary and comparative analysis of the current situation of China's iron and steel industry and ironmaking process, the current situation and progress of iron and steel technology at home and abroad, and the general development law of iron and steel industry, this paper concludes that the future direction of iron making technology is the research and development and application of technology of integration of factories and cities in the short term, and the research and development and application of low-carbon and low-cost technology and intelligent manufacturing equipment technology in the medium and long term. Baosteel ironmaking plant has carried out some attempts and practices, and made a long-term plan for the future development, so as to explore a set of unique and core competitive future ironmaking technology as soon as possible, and promote Baosteel ironmaking to become the best ironmaking in the industry.

Key words： ironmaking low carbon smelting integration of factories and cities intelligent manufacturing

Received: 23 April 2020

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	ZHU Ren-liang

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ZHU Ren-liang. Discussion on future development direction of ironmaking technology and exploratory practice of Baosteel[J]. Iron and Steel, 2020, 55(8): 2-10.

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http://www.chinamet.cn/Jweb_gt/EN/10.13228/j.boyuan.issn0449-749x.20200212 OR http://www.chinamet.cn/Jweb_gt/EN/Y2020/V55/I8/2

[1] 林秀群,吴振嘉,唐向阳. 工业行业全要素碳排放效率及影响因素研究[J]. 昆明理工大学学报:社会科学版,2020,20(2):58.(LIN Xiu-qun,WU Zhen-jia,TANG Xiang-yang. Study on the efficiency and influencing factors of total factor carbon emission in industrial industry[J]. Journal of Kunming University of Science and Technology:Social Science,2020,20 (2):58.)
[2] 郭沛,杨军.中国工业行业FDI对碳排放强度的影响[J].经济问题,2015(8):76.(GUO Pei,YANG Jun. The impact of FDI on carbon intensity in China′s industrial sector[J]. On Economic Problems,2015(8):76.)
[3] 孙少勤,郭琴琴,唐保庆. 基于行业异质性的中国工业发展与碳排放的关系研究[J]. 生态经济,2014,30(11):36.(SUN Shao-qin,GUO Qin-qin,TANG Bao-qing. Analysis on the factors of China′s industrial carbon emission based on industry heterogeneity[J]. Ecological Economy,2014,30 (11):36.)
[4] 陈国康. 产量上升投资下降[N]. 中国冶金报,2014-04-01(004).(CHEN Guo-kang. Increase in output and decrease in investment[N]. China Metallurgical News,2014-04-01(004).)
[5] 《中国钢铁业》编辑部. 每月情况通报[J].中国钢铁业,2019(2):1.(Editorial Department of China Steel. Monthly information[J]. China Steel,2019 (2):1.)
[6] 《世界金属导报》编辑部. 图解2019年全球高炉生铁和直接还原铁产量[J]. 世界金属导报,2020-02-25(F03).(Editorial Department of World Metals Guide. Diagram of global blast furnace pig iron and DRI production in 2019[J]. World Metals, 2020-02-25 (F03).)
[7] 汪鹏,姜泽毅,张欣欣,等. 中国钢铁工业流程结构、能耗和排放长期情景预测[J].北京科技大学学报,2014,36(12):1683.(WANG Peng,JIANG Ze-yi,ZHANG Xin-xin,et al. Long-term scenario forecast of production routes,energy consumption and emissions for Chinese steel industry[J]. Journal of University of Science and Technology Beijing,2014,36 (12):1683.)
[8] 沙永志,宋阳升. 未来高炉炼铁工艺之管见[J].炼铁,2018,37(5):1.(SHA Yong-zhi,SONG Yang-sheng. Outlook of future BF ironmaking technology[J]. Ironmaking,2018,37(5):1.)
[9] 冯士超,毛艳丽,狄嫣,等. 韩国浦项制铁公司科技创新体系概况[J]. 冶金经济与管理,2020(2):54.(FENG Shi-chao,MAO Yan-li,DI Yan,et al. Overview of science and technology innovation system of Korea POSCO[J]. Metallurgical Economy and Management,2020 (2):54.)
[10] 侯波,王铁仁,李宁. 有效降低森吉米尔轧机轧辊成本的方法[J]. 轧钢,2020,37(2):98.(HOU Bo,WANG Tie-ren,LI Ning. Methods to effectively reduce the roll cost of Sendzimir mill[J]. Rolling Steel,2020,37 (2):98.)
[11] 陈健,黄志伟,吴铭. 220 t燃煤锅炉脱硝超净排放调试问题分析与改造实践[J].冶金动力,2020(1):38.(CHEN Jian,HUANG Zhi-wei,WU Ming. Analysis of commissioning problems of denitration and ultra-clean emission of 220 t coal-fired boiler and transformation practice[J]. Metallurgical Power,2020(1):38.)
[12] 徐兆春,章香林,王军. 转炉OG系统湿法除尘超净排放改造技术路径探究[J]. 冶金动力,2019(6):21.(XU Zhao-chun,ZHANG Xiang-lin,WANG Jun. Technical approach for ultra-clean emission transformation of converter OG system wet dedusting[J]. Metallurgical Power,2019(6):21.)
[13] 项钟庸,王筱留,刘云彩,等.用评价高炉生产效率的新方法落实低碳炼铁方针[J].中国冶金,2016,26(7):1.(XIANG Zhong-yong,WANG Xiao-liu,LIU Yun-cai,et al. Policy implementation of low-carbon ironmaking using a new evaluation method of blast furnace production efficiency[J]. China Metallurgy,2016,26(7):1.)
[14] 姜曦,周东东,张明,等. 我国3 000 m³-4 000 m³高炉生产指标浅析[J].中国钢铁业,2018(3):31.(JIANG Xi,ZHOU Dong-dong,ZHANG Ming,et al. Brief analysis on 3 000 m³-4 000 m³ BF production[J]. China Steel,2018(3):31.)
[15] 周东东,姜曦,周翔. 2016年上半年中国大高炉生产指标浅析[J]. 中国冶金,2016,26(12):1.(ZHOU Dong-dong,JIANG Xi,ZHOU Xiang. Analyses of production indexes of large blast furnaces in China during first half of 2016[J]. China Metallurgy,2016,26(12):1.)
[16] 陈若平. 欧冶炉绿色炼铁生产实践[J]. 新疆钢铁,2019(4):44.(CHEN Ruo-ping. Production practice of green ironmaking in the OY Smelter[J]. Xinjiang Iron and Steel,2019(4):44.)
[17] 张建良,张冠琪,刘征建,等. 山东墨龙HIsmelt工艺生产运行概况及主要特点[J]. 中国冶金,2018,28(5):37.(ZHANG Jian-liang,ZHANG Guan-qi,LIU Zheng-jian,et al. Production overview and main characteristics of HIsmelt process in Shandong Molong[J]. China Metallurgy,2018,28(5):37.)
[18] 《中国冶金》编辑部. 首钢国际工程公司设计国内首个HIsmelt熔融还原炼铁项目[J].中国冶金,2015,25(6):61.(Editorial department of China Metallurgy. The first domestic Hismelt smelting reduction iron making project designed by Shougang International Engineering Company[J]. China Metallurgy,2015,25(6):61.)
[19] 张金元,程欣,宋腾飞. 钢铁企业节能诊断及案例分析[J]. 冶金经济与管理,2020(2):44.(ZHANG Jin-yuan,CHENG Xin,SONG Teng-fei. Diagnosis and case analysis of energy saving in iron and steel enterprises[J]. Metallurgical Economy and Management,2020(2):44.)
[20] 王新江. 中国电炉炼钢的技术进步[J]. 钢铁,2019,54(8):1.(WANG Xin-jiang. Technological progress of EAF steelmaking in China[J]. Iron and Steel,2019,54(8):1.)
[21] 刘勇,周小宾,彭世恒,等. 转炉熔池中废钢对混匀影响[J]. 连铸,2019,44(3):6.(LIU Yong,ZHOU Xiao-bin,PENG Shi-heng,et al. Effect of scrap on bath mixing for a BOF converter[J]. Continuous Casting,2019,44(3):6.)
[22] 李新创,李冰. 全球温控目标下中国钢铁工业低碳转型路径[J]. 钢铁,2019,54(8):224.(LI Xin-chuang,LI Bing. Low carbon transition path of China′s iron and steel industry under global temperature-control target[J]. Iron and Steel,2019,54(8):224.)
[23] 张琦,张薇,王玉洁,等. 中国钢铁工业节能减排潜力及能效提升途径[J]. 钢铁,2019,54(2):7.(ZHANG Qi,ZHANG Wei,WANG Yu-jie,et al. Potential of energy saving and emission reduction and energy efficiency improvement of China′s steel industry[J]. Iron and Steel,2019,54(2):7.)
[24] 赵沛,董鹏莉. 碳排放是中国钢铁业未来不容忽视的问题[J]. 钢铁,2018,53(8):1.(ZHAO Pei,DONG Peng-li. Carbon emission cannot be ignored in future of Chinese steel industry[J]. Iron and Steel,2018,53(8):1.)
[25] 张薇,王玉洁,刘帅,等. 基于CSC方法的钢铁行业节能减排技术潜力分析[J]. 中国冶金,2019,29(1):70.(ZHANG Wei,WANG Yu-jie,LIU Shuai,et al. Analysis of energy conservation and emission reduction potential in iron and steel industry based on CSC method[J]. China Metallurgy,2019,29(1):70.)
[26] 严珺洁. 超低二氧化碳排放炼钢项目的进展与未来[J]. 中国冶金,2017,27(2):6.(YAN Jun-jie. Progress and future of ultra-low CO₂ steel making program[J]. China Metallurgy,2017,27(2):6.)
[27] 王海洋,张建良,王广伟,等. 铁前系统的二氧化碳减排技术浅析[J].中国冶金,2018,28(1):1.(WANG Hai-yang,ZHANG Jian-liang,WANG Guang-wei,et al. Analysis of carbon dioxide emission reduction before ironmaking[J]. China Metallurgy,2018,28(1):1.)