Study on influence of coking with used rubber on coke microstructure

doi:10.16085/j.issn.1000-6613.2017-1616

Chemical Industry and Engineering Progress ›› 2017, Vol. 36 ›› Issue (S1): 339-345.DOI: 10.16085/j.issn.1000-6613.2017-1616

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Study on influence of coking with used rubber on coke microstructure

ZHANG Wencheng^1,2, REN Xueyan³, ZHANG Xiaoyong¹, ZHENG Mingdong¹

1. School of Chemistry and Chemical Engineering, Anhui University of Technology, Ma'anshan 243002, Anhui, China;
2. Meishan Technology Center of Baosteel Research Institute, Nanjing 210039, Jiangsu, China;
3. Manufacturing Management Department of Meishan Steel, Nanjing 210039, Jiangsu, China

Received:2017-08-02 Revised:2017-08-12 Online:2017-12-13 Published:2017-12-31

废橡胶共焦化对焦炭结构影响

张文成^1,2, 任学延³, 张小勇¹, 郑明东¹

1. 安徽工业大学化学与化工学院, 安徽马鞍山 243002;
2. 宝钢研究院梅钢技术中心, 江苏南京 210039;
3. 梅山钢铁公司制造管理部, 江苏南京 210039

通讯作者: 郑明东,教授,研究方向为煤化工。
作者简介:张文成(1997-),男,博士研究生。E-mail:618997@baosteel.com。
基金资助:
国家自然科学基金项目（U1361128）。

Abstract

Abstract: In order to study the influence of used rubber on coke quality, the pyrolysis performance of rubber powder is analyzed, the 70kg test coke oven is used to coking. The results show that the pyrolysis characteristics of used rubber is similar to coal, that provide the possibility of waste rubber instead of coal in coking. The results also show that with used rubber blending ratio increase, coke ash content decreased, sulfur content increased, coke mechanical strength of DI decreased slightly and the CSR decreased. In the range of ratio of 2%, ash decreased slightly, sulfur content increased, DI decreased, CSR increased slightly, the coke quality remained stable. The analysis shows that the specific surface area of micro-pore (<0.1μm) have the biggest change, while the middle pore (0.1-10μm) and the big pore (10μm) does not change significantly. When the ratio of used rubber was from 0 to 6%, the specific surface area of coke increased from 1.5m²/g to 3.5m²/g, that is the reason the bigger specific surface react fast and the strength of coke after reaction decreases. The analysis also shows that the stacking height of L_c decreased gradually with the increase of the ratio of used rubber. Coke mechanical strength is decrease with the degree of graphitization of coke.

Key words: used rubber, coking, coke, microstructure

摘要： 为了研究废橡胶配煤炼焦对焦炭质量的影响，本文对橡胶粉的热解性能进行分析，并利用70kg试验焦炉进行配煤炼焦试验，试验结果表明，通过对废橡胶的热解特性分析废橡胶的热解区间与配合煤相近，废橡胶的红外光谱与气煤相近，为废橡胶代替气煤配煤炼焦提供了可能。小焦炉试验表明，随着废橡胶的配煤配比增加，焦炭灰分下降，硫分有所上升，焦炭机械强度DI略有降低，焦炭反应后强度降低；在配比2%的范围内，灰分略有下降，硫分有所上升，DI略降低，CSR略提高，焦炭质量基本保持稳定。废橡胶配煤得到的焦炭微观结构分析表明，0.1~10μm的中孔和大于10μm大孔的比表面积变化不明显，而小于0.1μm的微孔比表面积变化最大。废橡胶配比从0到6%，则焦炭微孔比表面积从1.5m²/g增加到3.5m²/g。由于焦炭的二氧化碳反应性发生在表面，因此比表面积大则反应速度快，焦炭反应后强度降低。焦炭微晶结构分析表明，随着废橡胶配比的增加，堆积高度L_c逐渐降低，石墨化度逐渐降低，废橡胶的加入影响到焦炭的基质结构，石墨化度降低对于焦炭的机械强度不利。

关键词: 废橡胶, 焦化, 焦炭, 显微结构

CLC Number:

TF526

ZHANG Wencheng, REN Xueyan, ZHANG Xiaoyong, ZHENG Mingdong. Study on influence of coking with used rubber on coke microstructure[J]. Chemical Industry and Engineering Progress, 2017, 36(S1): 339-345.

张文成, 任学延, 张小勇, 郑明东. 废橡胶共焦化对焦炭结构影响[J]. 化工进展, 2017, 36(S1): 339-345.

References

[1] 张兆红,杜爱华. 废橡胶热裂解的应用研究进展[J]. 中国资源综合利用,2011,29(3):36-38. ZHANG Z H, DU A H. Progress in application of pyrolysis of waste rubber[J]. Resources Comprehensive Utilization,2011,29(3):36-38.
[2] 胡彪, 张晓雨, 赵新,等. 废旧橡胶制品资源化利用研究进展[J]. 材料导报, 2014, 28(3):75-79.HU B, ZHANG X Y, ZHAO X, et al. Research progress on resource utilization of waste rubber products[J]. Materials Review, 2014, 28(3):75-79.
[3] 杨嘉谟, 周四平. 废旧橡胶轮胎的催化裂解[J]. 化工进展, 2000, 19(1):71-78. YANG J M, ZHOU S P. Catalytic cracking of waste tires[J]. Chemical Industry and Engineering Progress, 2000, 19(1):71-78.
[4] ROY C, DARMSTADT H, BENALLAL B, et al. Characterization of naphtha and carbon black obtained by vacuum pyrolysis of polyisoprene rubber[J]. Fuel Processing Technology, 1997, 50(1):87-103.
[5] ANI F N, NOR N S M. Microwave induced fast pyrolysis of scrap rubber tires[C]//Aip Conference. American Institute of Physics, 2012:834-841.
[6] 胡利芬, 钟亚军. 橡胶催化热解动力学分析[J]. 化工进展, 2008, 27(6):925-927. HU L F, ZHONG Y J. Kinetic analysis of catalytic thermal decomposition of rubber[J]. Chemical Industry and Engineering Progress, 2008, 27(6):925-927.
[7] 蒋家羚, 刘小龙, 刘宝庆. 废轮胎热裂解设备开发[J]. 化工进展, 2002, 21(9):681-684. JIANG J L, LIU X L, LIU B Q. Development of a pyrolysis plants for used tires[J]. Chemical Industry and Engineering Progress, 2002, 21(9):681-684.
[8] 刘霞, 廖洪强, 张振国,等. 利用废橡胶提高冶金焦化产物质量的研究[J]. 钢铁, 2006, 41(6):17-21. LIU X, LIAO H Q, ZHANG Z G, et al. Study on improving quality of coke co-coked with addition of waste tire[J]. Iron & Steel, 2006, 41(6):17-21.
[9] 刘霞, 邓德敏, 廖洪强,等. 废轮胎与煤共焦化焦油分析[J]. 化工进展, 2010, 29(8):1571-1575. LIU X, DENG D M, LIAO H Q, et al. Analysis of tar from co-coking of coal with waste tyre[J]. Chemical Industry and Engineering Progress, 2010, 29(8):1571-1575.
[10] 周仕学, 刘振学, 张桂英. 强粘结性煤与有机废弃物共热解的研究[J]. 煤炭转化, 2001, 24(3):70-73. ZHOU S X, LIU Z X,ZHANG G Y. Study on co-pyrolosis of strongly caking coal with solid organic waste[J]. Coal Conversion, 2001,24(3):70-73.
[11] 武明华. 煤和废橡胶粉的共热解研究[D]. 大连:大连理工大学, 2007. WU M H. Co-pyrolysis of coal and waste rubber powder[D]. Dalian:Dalian University of Technology, 2007.

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Study on influence of coking with used rubber on coke microstructure

废橡胶共焦化对焦炭结构影响

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