科技导报 >

2024 , Vol. 42 >Issue 4: 21 - 30

DOI: https://doi.org/10.3981/j.issn.1000-7857.2024.04.002

专题:生态环境材料及评价技术

水泥制造业绿色低碳技术研究进展

  • 沈鸿海 ,
  • 刘宇 ,
  • 郑焱 ,
  • 龚先政
展开
  • 北京工业大学材料与制造学部, 北京 100124
沈鸿海,硕士研究生,研究方向为材料生命周期评价与生态设计,电子信箱:shenhonghai199@163.com

收稿日期: 2023-07-19

  修回日期: 2023-10-30

  网络出版日期: 2024-04-08

基金资助

国家重点研发计划项目(2022YFC3901205);北京工业大学城市碳中和科技创新基金项目(048000514122666)

收起

Research progress on low-carbon technologies in cement manufacturing industry

  • SHEN Honghai ,
  • LIU Yu ,
  • ZHENG Yan ,
  • GONG Xianzheng
Expand
  • Faculty of Materials and Manufacturing, Beijing University of Technology, Beijing 100124, China

Received date: 2023-07-19

  Revised date: 2023-10-30

  Online published: 2024-04-08

Fold

摘要

随着中国碳达峰、碳中和目标的提出,水泥制造业的绿色低碳转型成为行业发展的主要趋势,相关节能降碳关键技术的研发部署与应用需求日益迫切。从原料替代、燃料替代、节能提效和碳捕集利用4个方面梳理了当前水泥行业已经实现商业化应用与正处于研发阶段的绿色低碳技术,综述了各类技术的碳减排潜力,分析了各种技术的协同环境效益、推广限制条件等因素。

关键词: 碳排放; 水泥; 低碳技术; 碳减排潜力

本文引用格式

沈鸿海 , 刘宇 , 郑焱 , 龚先政 . 水泥制造业绿色低碳技术研究进展[J]. 科技导报, 2024 , 42(4) : 21 -30 . DOI: 10.3981/j.issn.1000-7857.2024.04.002

Abstract

With the goal of emission peak and carbon neutrality, the green and low-carbon transformation of the cement manufacturing industry has become a major trend in the development of the industry, and the R&D deployment and application of related energy-saving and carbon-reducing key technologies are increasingly urgent. This paper systematically compares the green low-carbon technologies that have been commercially applied in the cement industry and those that are in the R&D stage from four aspects: raw material substitution, fuel substitution, energy saving and efficiency improvement, and carbon capture and utilization, reviews the carbon reduction potential of various technologies, and analyzes and discusses the synergistic environmental benefits, promotion constraints and other factors of various technologies to provide suggestions and support for the selection of technologies in the process of low-carbon green transformation in the cement industry.

Key words: carbon emission; cement; low-carbon technology; carbon reduction potential

参考文献

[1] 胡鞍钢.中国实现2030年前碳达峰目标及主要途径[J].北京工业大学学报(社会科学版), 2021, 21(3):1-15.
[2] Sui X, Zhang Y, Shao S, et al. Exergetic life cycle assessment of cement production process with waste heat power generation[J]. Energy Conversion and Management, 2014,88:684-692.
[3] Zhi X, An X, et al. Low carbon technology roadmap of China cement industry[J]. Journal of Sustainable CementBased Materials, 2023, 12(6):771-774.
[4] Naqi A, Jang J G. Recent progress in green cement technology utilizing low-carbon emission fuels and raw materials:A review[J]. Sustainability, 2019, 11(02):1-18.
[5] 罗雷,郭旸旸,李寅,等.碳中和下水泥行业低碳发展技术路径及预测研究[J].环境科学研究, 2022, 35(6):1527-1537.
[6] 王勇,张萌,曹元辉,等.电石渣水泥生产对水泥行业碳减排的影响分析[J].水泥, 2022, 545(7):10-12.
[7] 刘丽芬,张文生,涂长江,等.利用硅钙渣部分替代石灰石生产硅酸盐水泥熟料的工业试验[J].水泥, 2015, 453(3):12-13.
[8] 刘晶,汪澜.应用替代原料减少水泥行业CO2排放实例分析[J].新型建筑材料, 2017, 44(7):97-99.
[9] 李鹏鹏,任强强,吕清刚,等.面向双碳的低碳水泥原料/燃料替代技术综述[J].洁净煤技术, 2022, 28(8):35-42.
[10] Gartner E, Sui T. Alternative cement clinkers[J]. Cement and Concrete Research, 2018, 114:27-39.
[11] 张宾,赵有强,林永权,等.水泥工业二氧化碳循环利用现状[J].中国水泥, 2021(4):75-81.
[12] Environment U N, Scrivener K L, John V M, et al. Ecoefficient cements:Potential economically viable solutions for a low-CO2 cement-based materials industry[J].Cement and Concrete Research, 2018, 114:2-26.
[13] Taylor-Lange S C, Lamon E L, Riding K A, et al. Calcined kaolinite-bentonite clay blends as supplementary cementitious materials[J]. Applied Clay Science, 2015,108(5):84-93.
[14] Martirena F, Scrivener K. Low carbon cement LC3 in Cuba:Ways to achieve a sustainable growth of cement production in emerging economies[M]. Dordrecht:Springer,2018.
[15] Habert G. Assessing the environmental impact of conventional and "green" cement production[J]. Eco-efficient Construction and Building Materials, 2014, 46:199-238.
[16] 姜乐乐,姜福香.碱激发胶凝材料的研究进展[J].上海涂料, 2021, 59(2):42-47.
[17] Chen L. Perforated cenospheres:A reactive internal curing agent for alkali activated slag mortars[J]. Cement&concrete composites, 2019, 104:35-44.
[18] Teh S H, Wiedmann T, Castel A, et al. Hybrid life cycle assessment of greenhouse gas emissions from cement,concrete and geopolymer concrete in Australia[J]. Journal of Cleaner Production, 2017, 152:312-320.
[19] 童国庆,张吾渝,高义婷,等.碱激发粉煤灰地聚物的力学性能及微观机制研究[J].材料导报, 2022, 36(4):129-134.
[20] Zhao H T, Liu Y, Li X Q, et al. Research progress on low-carbon technologies and assessment methods in cement industry[J]. Materials Science Forum, 2021, 103:933-943.
[21] Wang Q, Yan P Y, Han S. The influence of steel slag on the hydration of cement during the hydration process of complex binder[J].中国科学:技术科学(英文版), 2011,54(2):7.
[22] 魏丽颖,汪澜,颜碧兰.国内外低碳水泥的研究新进展[J].水泥, 2014, 450(12):1-3.
[23] Habert G, Billard C, Rossi P, et al. Cement production technology improvement compared to factor 4 objectives[J]. Cement&Concrete Research, 2010, 40(5):820-826.
[24] 张邦松.生物质秸秆作为替代燃料在水泥工厂的应用[J].中国水泥, 2023(2):56-58.
[25] 罗志斌,孙潇,高啸天,等.双碳背景下绿色氨能的应用场景及展望[J].南方能源建设, 2023, 10(3):47-54.
[26] Sakri A, Aouabed A, Nassour A, et al. Refuse-derived fuel potential production for co-combustion in the cement industry in Algeria[J]. Waste Management&Research, 2021, 39(9):1174-1184.
[27] 马旭,吴佳泺,李文祎.碳中和背景下我国水泥工业替代燃料发展的若干思考[J].新世纪水泥导报, 2022, 28(3):1-5.
[28] Ankaya S. Investigating the environmental impacts of alternative fuel usage in cement production:A life cycle approach[J]. Environment, Development and Sustainability:A Multidisciplinary Approach to the Theory and Practice of Sustainable Development, 2020, 22:18-39.
[29] 崔源声,方艳欣,王硕.国外水泥工业替代燃料的最新发展趋势[J].水泥, 2018(1):9-12.
[30] Schneider M, Romer M, Tschudin M. Sustainable cement production-present and future[J]. Cement and Concrete Research, 2011,(7):41.
[31] Zheng C, Zhang H, Cai X, et al. Characteristics of CO2 and atmospheric pollutant emissions from China's cement industry:A life-cycle perspective[J]. Journal of Cleaner Production, 2020, 282(7):124533.1-124533.10.
[32] 佟庆,魏欣旸,秦旭映,等.我国水泥和钢铁行业突破性低碳技术研究[J].上海节能, 2020(5):380-385.
[33] Atmaca A, Kanoglu M. Reducing energy consumption of a raw mill in cement industry[J]. Energy, 2012, 42(1):261-269.
[34] 赵计辉,王栋民,王学光.现代水泥工业中高效节能的粉磨技术[J].中国粉体技术, 2013, 19(4):65-71.
[35] 夏凌风,郭珍妮.水泥行业碳减排途径及贡献度探讨[J].中国水泥, 2022(11):14-19.
[36] 陈钦松.立磨水泥终粉磨应用实践及制成水泥质量[J].中国水泥, 2022, 242(7):81-83.
[37] 陈忆红,郭瑞广,李伟洋.基于水泥联合粉磨系统节能降耗途径的分析[J].散装水泥, 2020, 208(5):5-7.
[38] 殷昭波.水泥熟料烧成系统电耗分析探讨[J].水泥工程, 2020, 198(5):10-12.
[39] 郭君毅.水泥生产工艺节能技术探讨[J].四川水泥,2021(6):13-14.
[40] "高固气比水泥悬浮预热分解技术" 入选第四批国家重点节能技术推广[J].建材发展导向, 2012, 10(1):81.
[41] 江旭昌.浅论水泥回转窑窑型的发展[J].新世纪水泥导报, 2020, 26(1):5-17.
[42] 张宪合,张长春,刘传路.低氮燃烧脱硝技术成功改造案例分析[J].中国水泥, 2020, 216(5):79-81.
[43] Pieper C, Wirtz S, Schaefer S, et al. Numerical investigation of the impact of coating layers on RDF combustion and clinker properties in rotary cement kilns[J]. Fuel,2021, 283:118951.1-118951.14.
[44] 华俊.水泥熟料篦式冷却机的技术发展和应用研究[J].四川建材, 2022, 48(9):182-183.
[45] 钟永超,李帅波,康宇,等.第三代篦冷机整体更换为第四代中置辊破冷却机的实践[J].水泥, 2020(8):47-49.
[46] 李丹,郑伟,刘彦伟. "双碳" 背景下水泥行业发展之路[J].中国水泥, 2022,(5):82-84.
[47] 冯金生.关于水泥窑纯低温余热发电技术的探究[J].居舍, 2018(35):165.
[48] 朱刚.碳中和目标下的水泥工业低碳技术研究[J].水泥工程, 2022(4):1-4.
[49] Yan X H, Jing S H. Research on key technologies of cementintelligent control cloud platform client[J]. DEStech Transactions on Engineering and Technology Research,2018, 42(9):56-71.
[50] Guzman M P, Rubia B N, Peris P M, et al. Methodological development for the optimisation of electricity cost in cement factories:The use of artificial intelligence in process variables[J]. Electrical engineering, 2022, 3:104-119.
[51] Tan C, Yu X, Guan Y R. A technology-driven pathway to net-zero carbon emissions for China's cement industry[J]. Applied Energy, 2022, 325:119804.
[52] 付立娟,杨勇,卢静华.水泥工业碳达峰与碳中和前景分析[J].中国建材科技, 2021, 30(4):80-84.
[53] 杨晴,孙云琪,周荷雯,等.我国典型行业碳捕集利用与封存技术研究综述[J].华中科技大学学报(自然科学版), 2023, 51(01):101-110.
[54] 任勇.碳中和目标下海螺水泥减排二氧化碳的实践[J].新世纪水泥导报, 2021, 27(2):6-8.
[55] Fytlanos G, Grimstvedt A, Hanna K, et al. Corrosion and degradation in MEA based post-combustion CO2 capture[J]. International Journal of Greenhouse Gas Control,2016, 46:48-56.
[56] 孙立勋,韩力.中国水泥行业CCUS技术库的构建与分析[J].四川水泥, 2020(1):4-5.
[57] Dean C C, Dugwell D, Fennell P S. Investigation into potential synergy between power generation, cement manufacture and CO2 abatement using the calcium looping cycle[J]. Energy&Environmental Science, 2011, 4:2050-2053.
[58] 缪昌文,穆松. "双碳" 目标下水泥基材料绿色低碳路径思考与展望[J].未来城市设计与运营, 2022(2):10-16.
[59] 高旭东,范永斌,王郁涛.水泥行业 "十三五" 科技发展报告[J].中国水泥, 2021(07):28-39.
[60] 朱兵兵,郑志龙,邹兴芳.水泥企业碳减排技术路径浅析[J].水泥, 2021(10):4-5.
Options
文章导航

/

联系我们

  • 地址:北京市海淀区学院南路86号科技导报社 邮编:100081
  • 电话:010-62138113 传真:010-62138113
  • E-mail:kjdbbjb@cast.org.cn

    • 访问统计

      总访问量
      今日访问
      在线人数
    科技导报官方微信公众号
    京ICP备14028469号-1 
    版权所有 © 《科技导报》编辑部