Energy recovery and abatement potential of CO_2 emissions for an integrated iron and steel making enterprise 被引量：2

Energy recovery and abatement potential of CO_2 emissions for an integrated iron and steel making enterprise

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摘要 The typical features for an integrated iron & steelmaking industry are high energy consumption and CO2 emission.The traditional BF-BOF process in an integrated Iron and steelmaking enterprise produces a large amount of residual heat and energy,which has great potential for recovery and abatement potential of CO2 emissions.In this paper,for an integrated Iron & steelmaking enterprise of 10 million tons per year in capacity,the residual heat and energy recovery analysis was conducted.It is indicateded that the residual heat and energy can be recovered as electric power by using present advanced process technology.By means of the distributed power generation,the residual heat and energy can be recovered,with a power generation capacity of 419.5 kWh per ton steel product.Accordingly,the abatement potential of CO2 emissions for an integrated iron & steel making enterprise was also evaluated,which indicated that about 398.5 kg CO2 could be reduced per ton steel product. The typical features for an integrated iron & steelmaking industry are high energy consumption and CO2 emission.The traditional BF-BOF process in an integrated Iron and steelmaking enterprise produces a large amount of residual heat and energy,which has great potential for recovery and abatement potential of CO2 emissions.In this paper,for an integrated Iron & steelmaking enterprise of 10 million tons per year in capacity,the residual heat and energy recovery analysis was conducted.It is indicateded that the residual heat and energy can be recovered as electric power by using present advanced process technology.By means of the distributed power generation,the residual heat and energy can be recovered,with a power generation capacity of 419.5 kWh per ton steel product.Accordingly,the abatement potential of CO2 emissions for an integrated iron & steel making enterprise was also evaluated,which indicated that about 398.5 kg CO2 could be reduced per ton steel product.

作者 LI HongFu1,2,BAO WeiJun3,LI HuiQuan3 & CANG DaQiang1 1 Ecology and Recycling Metallurgy Laboratory,Ministry of Education,School of Metallurgical and Ecological Engineering,University of Science and Technology Beijing,Beijing 10083,China 2 Jinan iron & Steel Group Ltd.,Jinan 250101,China 3 National Engineering Laboratory for Clean Production Technology of Hydrometallurgy,Institute of Process Engineering,Chinese Academy of Sciences,Beijing 100190,China

出处《Science China(Technological Sciences)》 SCIE EI CAS 2010年第1期129-133,共5页 中国科学（技术科学英文版）

基金 supported by the National Basic Research Program of China ("973" Project) (Grant No.2007613507) the Intellectual Innovative Program of The Chinese Academy of Sciences (Grant No.KGCX-YW-323-1) the National "Eleventh Five" important science and technology supporting program (Grant No.2006BA02A14)

关键词 Iron and STEELMAKING ENTERPRISE RESIDUAL heat and energy recovery distributed power generation ABATEMENT POTENTIAL of CO2 emission Iron and Steelmaking enterprise residual heat and energy recovery distributed power generation abatement potential of CO2 emission

分类号 TK019 [动力工程及工程热物理]

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