钢铁生产过程二氧化碳排放量的精确计算是钢铁行业节能减排的基础。对钢铁生产流程二氧化碳排放的3种常用温室气体排放计算方法进行介绍,并基于A钢厂2014年的生产数据进行计算和分析对比。《省级温室气体清单编制指南》、《钢铁碳排放指南》两种计算方法都是基于投入产出的统计方法,两者温室气体计算结果数值相近,前者吨钢二氧化碳排放结果为2.116 t,后者吨钢二氧化碳排放结果为2.013 t ,后一种方法在计算时考虑了固碳产品的抵扣,所以结果比前种方法结果偏小。基于ISO标准的钢铁产品生命周期计算方法,计算边界从铁矿石、煤炭等原材料的采掘、洗选、运输,焦化,烧结,高炉,炼钢,轧制等直到钢铁产品的出厂,计算结果吨钢产品二氧化碳排放量为2.309 t,相比前两种方法计算结果数值较大,这是因为在计算时包含了铁矿石、煤炭等在开采、洗选、运输阶段产生的二氧化碳。
Quantitative calculation of carbon dioxide emissions during steel-making process is the basis of energy-sav-ing and emission-reduction work in the steel industry. The current work introduced three methods for the calculation of carbon emissions in which these three methods were often applied for the calculation of common greenhouse gases emis-sions. The production data of Steel Plant A in 2014 were given and analyzed by three calculation methods to compare the differences. The methods of Provincial Guidelines for Greenhouse Gas Inventories(PGGGI)and Accounting Methods and Reporting Guidelines for Greenhouse Gas Emissions in Chinese Steel Producers(AMRGGE)are on the base of In-put-Output model. Similar results were obtained by the above methods,for the calculation result of PGGGI was 2.116 t/t steel and that of AMRGGE was 2.013 t/t steel. The carbon dioxide emission by the method of AMRGGE was lower be-cause some by-products containing carbon were removed. The whole life cycle of steel product was studied by the Life Cycle Assessment(LCA)method based on the ISO standards. The calculation involved the mining,the washing and the transportation of iron ore,coal and other raw materials,and the related processes developed from the coking,the sinter-ing,the blast furnace,the steelmaking,the rolling to the finished product. The calculated carbon dioxide emission of LCA was 2.309 t/t steel which was higher than the other two methods,because a greater range system boundary which contained iron ore,coal mining and transportation were considered in this method.
参考文献
| [1] | 刘小敏.国家“十二五”规划中能源强度与碳排放强度约束指标的比较研究[J].金融评论,2012(05):58-69. |
| [2] | 张春霞;上官方钦;张寿荣;殷瑞钰.关于钢铁工业温室气体减排的探讨[J].工程研究-跨学科视野中的工程,2012(3):221-230. |
| [3] | 滕飞;冯相昭;李捷.加强温室气体管理制度建设积极应对气候变化[J].环境保护,2011(11):12-15. |
| [4] | 潘佳佳;李廉水.中国工业二氧化碳排放的影响因素分析[J].环境科学与技术,2011(4):86-92. |
| [5] | 李景云.钢铁企业节能环保形势分析及应对措施[J].中国钢铁业,2014(03):20-23. |
| [6] | 徐匡迪.转变发展方式建设低碳经济[J].上海大学学报(社会科学版),2010(04):5-16. |
| [7] | 黄导;陈丽云;张临峰;李全功;李煜.推进节能环保技术管理升级促进钢铁工业绿色转型[J].钢铁,2015(12):1-10. |
| [8] | 常阿平.碳关税壁垒对我国钢铁行业的影响及应对之策[J].对外经贸实务,2012(10):42-45. |
| [9] | 姜晓东.关于中国钢铁产能过剩的若干思考与建议[J].钢铁,2013(10):1-5. |
| [10] | 王微;林剑艺;崔胜辉;吝涛.碳足迹分析方法研究综述[J].环境科学与技术,2010(7):71-78. |
| [11] | 张玥;王让会;刘飞.钢铁生产过程碳足迹研究--以南京钢铁联合有限公司为例[J].环境科学学报,2013(4):1195-1201. |
| [12] | 董会娟;耿涌.基于投入产出分析的北京市居民消费碳足迹研究[J].资源科学,2012(3):494-501. |
| [13] | 姚亮;刘晶茹;王如松;尹科.基于多区域投入产出(MRIO)的中国区域居民消费碳足迹分析[J].环境科学学报,2013(7):2050-2058. |
| [14] | 孙建卫;陈志刚;赵荣钦;黄贤金;赖力.基于投入产出分析的中国碳排放足迹研究[J].中国人口·资源与环境,2010(5):28-34. |
| [15] | 刘韵;师华定;曾贤刚.基于全生命周期评价的电力企业碳足迹评估--以山西省吕梁市某燃煤电厂为例[J].资源科学,2011(4):653-658. |
| [16] | 高成康;陈杉;陈胜;秦威.中国典型钢铁联合企业的碳足迹分析[J].钢铁,2015(3):1-8. |
| [17] | EDGAR G. HERTWICH;GLEN P. PETERS.Carbon Footprint of Nations: A Global, Trade-Linked Analysis[J].Environmental Science & Technology: ES&T,200916(16):6414-6420. |
| [18] | Katja Schumacher;Ronald D. Sands.Where are the industrial technologies in energy-economy models? An innovative CGE approach for steel production in Germany[J].Energy economics,20074(4):799-825. |
| [19] | 侯萍;王洪涛;张浩;范辞冬;黄娜.用于组织和产品碳足迹的中国电力温室气体排放因子[J].中国环境科学,2012(6):961-967. |
| [20] | 曾才兵;刘茂伟;李敬如.邯钢Ⅱ期球团降低工序能耗的实践[J].烧结球团,2012(2):53-57. |
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