PMC矿粒度及球团预热、焙烧工艺参数的选择

doi:10.13228/j.boyuan.issn0449-749x.20200057

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (2648 KB) HTML (0 KB)
输出: BibTeX | EndNote (RIS)

摘要为了促进PMC矿粉的高效利用,研究了PMC矿粉粒度和预热、焙烧温度对球团矿抗压强度、还原度、低温还原粉化、膨胀率、转鼓强度、孔隙率和熔滴性能的影响。结果表明,随着预热、焙烧温度的升高,改善了球团矿的抗压强度、还原度、转鼓强度和软熔滴落性能,低温还原粉化率变化幅度较小。随着焙烧温度的升高,膨胀率先升高后降低,孔隙率降低。随着预热温度的升高,1号球团矿 (PMC 0.074 mm)的膨胀率下降,2号球团矿(PMC 0.045 mm)的膨胀率小幅度升高;随预热温度的升高,两种PMC球团矿孔隙率先降低然后升高,在预热温度为950 ℃时,孔隙率最低。根据上述研究结果,通过加权灰色关联度法确定了PMC矿球团生产最佳工艺参数,粒度为0.074 mm,预热温度为925 ℃,焙烧温度为1 300 ℃。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章

关键词 ：球团矿, PMC矿粉粒度, 预热温度, 焙烧温度, 孔隙率

Abstract：In order to promote the efficient utilization of PMC ore powder, the effects of particle size, preheating, and roasting temperature of PMC ore powder on the compressive strength, reduction index, reduction degradation index, swelling rate, drum strength, porosity, and softening-melting properties of pellets were studied. The results indicate that, with the increase of preheating and roasting temperature, the compressive strength, reduction index, drum strength and softening-melting properties of pellets are improved, and the change of reduction degradation index is small; with the increase of roasting temperature, the swelling rate increases first and then decreases, and the porosity decreases; with the increase of preheating temperature, the swelling rate of No.1 pellets decreases, while the swelling rate of No.2 pellets increases slightly; with the increase of preheating temperature, the porosity of two kinds of PMC pellets first decreases and then increases, and the porosity is the lowest when preheating temperature is 950 ℃. According to the above research results, the best process parameters are determined by the weighted grey correlation method: the particle size of No.1 PMC, the preheating temperature is 925 ℃, and the roasting temperature is 1 300 ℃.

Key words： pellet particle size of PMC ore powder preheating temperature roasting temperature porosity

收稿日期: 2020-02-17

引用本文:

卢建光, 刘小杰, 吕庆. PMC矿粒度及球团预热、焙烧工艺参数的选择[J]. 钢铁, 2020, 55(10): 21-28. LU Jian-guang, LIU Xiao-jie, LÜ Qing. Selection of PMC ore size, preheating and roasting process parameters for pelletizing[J]. Iron and Steel, 2020, 55(10): 21-28.

链接本文:

http://www.chinamet.cn/Jweb_gt/CN/10.13228/j.boyuan.issn0449-749x.20200057 或 http://www.chinamet.cn/Jweb_gt/CN/Y2020/V55/I10/21

[1] LÜ W, SUN Z Q, SU Z J. Life cycle energy consumption and greenhouse gas emissions of iron pelletizing process in China, a case study[J]. Journal of Cleaner Production, 2019,233: 1314.
[2] 王新东,李建新,胡启晨. 基于高炉炉料结构优化的源头减排技术及应用[J]. 钢铁,2019,54(12):104. (WANG Xin-dong, LI Jian-xin, HU Qi-chen. Application practice of source and process sulfur-nitate reduction technology based on optimization of blast furnace charge structure[J]. Iron and Steel, 2019, 54(12): 104.)
[3] 余正伟,向爱平,刘山平,等. 低铁高硅赤铁精矿对氧化球团性能的影响[J]. 中国冶金,2020,30(6):8.(YU Zheng-wei, XIANG Ai-ping, LIU San-ping et al. Effect of low iron and high silicon hematite concentrate ratio on properties of oxidized pellets[J]. China Metallurgy, 2020, 30(6): 8.)
[4] 王维兴. 高炉炼铁精料技术的内涵[J]. 世界金属导报,2014-09-23(B02).(WANG Wei-xing. The connotation of blast furnace ironmaking concentrate technology[J]. World Metal Guide, 2014-09-23(B02).)
[5] 杨天钧. 坚持精料方针提高高炉操作水平[J]. 世界金属导报,2014-07-01 (B08).(YANG Tian-Jun. Adhere to the policy of fine charging and improve the operation level of blast furnace[J]. World Metal Guide, 2014-07-01 (B08).)
[6] 王维兴. 提高高炉炉料中球团矿配比、促进节能减排[J]. 冶金管理,2018(9):53.(WANG Wei-xing. Increase the proportion of pellets in blast furnace burden, promote energy saving and emission reduction[J]. Metallurgical Management, 2018(9): 53.)
[7] 张淑会,薛向欣,刘然,等. 尾矿综合利用现状及其展望[J]. 矿冶工程,2005(3):44.(ZHANG Shu-hui, XUE Xiang-xin, LIU Ran, et al. Current situation and prospect of the comprehensive utilization of mining tailings[J]. Mining and Metallurgical Engineering, 2005(3):44.)
[8] 陈树军,刘凯,王小艾,等. 高炉使用含PMC矿炉料的配矿结构研究[J]. 材料与冶金学报,2016,15(3):159.(CHEN Shu-jun, LIU Kai, WANG Xiao-ai, et al. Study on the blast furnace burden structure containing PMC ore[J]. Journal of Materials and Metallurgy, 2016, 15(3): 159.)
[9] 田野,吕庆,刘小杰,等. PMC精矿粉细磨粒度对球团质量的影响[J]. 矿冶工程,2017,37(1):85.(TIAN Ye, LÜ Qing, LIU Xiao-jie, et al. Effect of grinding fineness of PMC on qualities of pellets[J]. Mining and Metallurgical Engineerig, 2017, 37(1): 85.)
[10] 陈树军,刘凯,吕庆. 不同配比下PMC矿粉和司家营矿粉造球工艺试验研究[J]. 材料科学与工艺,2016,24(6):85.(CHEN Shu-jun, LIU Kai, LÜ Qing. Experimental study on the pelletizing with PMC and sijiaying ore mineral powder under different ratio[J]. Materials Science and Technology, 2016, 24(6): 85.)
[11] 吕庆,田野,刘小杰,等. PMC精矿配加司家营矿粉球团焙烧机理[J]. 钢铁,2016,51(8):17.(LÜ Qing, TIAN Ye, LIU Xiao-jie, et al. Roasting mechanism of pellet made from PMC and Sijiayig[J]. Iron and Steel, 2016, 51(8):17.)
[12] 吕庆,田野,刘小杰,等. 添加不同配比的铜尾矿PMC应用于球团制备的研究[J]. 矿产综合利用,2018(2):86.(LÜ Qing, TIAN Ye, LIU Xiao-jie, et al. Study on producing pellets with different ratio of PMC[J]. Multipurpose Utilization of Mineral Resources, 2018(2): 86.)
[13] 胡志清,潘建,朱德庆,等. 铁精矿原料特性及其对成球性能的影响[J]. 烧结球团,2013,38(4):42. (HU Zhi-qing, PAN Jian, ZHU De-qing, et al. Raw material characteristics of iron ore concentrate and its influence on balling performance[J]. Sintering and Pelletizing, 2013,38(4): 42.)