包钢6号高炉中钾、钠的平衡与控制
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摘要
针对包钢高炉碱金属循环富集严重、影响高炉顺行和生铁质量这一现状,通过测定包钢炼铁厂6号高炉入炉原燃料及产出项的碱金属含量,并结合取样期间高炉实际生产数据,对6号高炉做了碱金属的分布计算。研究表明,包钢6号高炉中的碱负荷为4.888kg/t,其中有69.29%的碱金属由烧结矿带入;支出项中,炉渣带走的碱金属量最多,占到总支出量的83.41%。为降低碱金属对高炉生产造成的危害,结合包钢6号高炉实际情况,给出了降低碱金属危害的措施。
According to the serious circulation and enrichment of alkali metals in Baotou Steel,which influenced the smooth operation of BF and the quality of pig iron,the equilibrium distribution of alkali metals in No.6 BF of Baotou Steel was calculated by measuring the alkali metals content in the raw fuel and output of No.6 BF,and combining with the actual production data of BF during sampling period.The results showed that the alkali load in No.6 BF of Baotou Steel was 4.888 kg/t,of which 69.29%alkali metals were brought in by the sinter.Among the expenditure items,most of the alkali metals were taken away by slag,accounting for 83.41% of the total expenditure.In order to reduce the damage caused by alkali metal to BF production,the measures to reduce the harm of alkali metals in combination with the actual situation of No.6 blast furnace of Baotou Steel were put forward.
According to the serious circulation and enrichment of alkali metals in Baotou Steel,which influenced the smooth operation of BF and the quality of pig iron,the equilibrium distribution of alkali metals in No.6 BF of Baotou Steel was calculated by measuring the alkali metals content in the raw fuel and output of No.6 BF,and combining with the actual production data of BF during sampling period.The results showed that the alkali load in No.6 BF of Baotou Steel was 4.888 kg/t,of which 69.29%alkali metals were brought in by the sinter.Among the expenditure items,most of the alkali metals were taken away by slag,accounting for 83.41% of the total expenditure.In order to reduce the damage caused by alkali metal to BF production,the measures to reduce the harm of alkali metals in combination with the actual situation of No.6 blast furnace of Baotou Steel were put forward.
引文
[1]吕青青,杜屏,周俊兰.高炉块状带焦炭劣化机理[J].钢铁,2016,51(1):13.
[2]郑朋超,张建良,刘征建,等.碱金属对焦炭热性能的影响[J].中国冶金,2017,27(5):19.
[3]张伟,王再义,张立国,等.高炉中碱金属和锌的循环及危害控制[J].鞍钢技术,2016(6):9.
[4]孙立铎,黄晓煜,杜续恩.高炉炉缸破损的原因与控制[J].钢铁,2015,50(6):1.
[5]王庆祥,尹坚.湘钢1号高炉碱金属行为[J].中国冶金,2005,15(2):18.
[6]彭其春,陈永金,陈本强,等.湘钢3号和4号高炉碱金属的分布与平衡[J].钢铁研究,2007,35(6):5.
[7]梁南山.涟钢高炉有害元素的分布与控制[J].中国冶金,2014,24(6):27.
[8]杨振和.南钢高炉碱金属分析[J].江苏科技,2002,30(6):9.
[9]范晓慧,何向宁,甘敏,等.烧结过程中碱金属的脱除及在颗粒物中的富集行为[J].中南大学学报:自然科学版,2017,48(11):2843.
[10]涂威,田仕友,王晓斌.内蒙某铁矿石脱除碱金属研究[J].酒钢科技,2014(1):1.
[11]张士敏.高炉内碱金属的平衡[J].钢铁研究学报,1982(1):9.
[12]王艺慈,那树人,陈春元,等.提高包钢高炉渣排碱能力的试验研究[J].包头钢铁学院学报,2001,20(2):104.
[13]伍世辉,刘三林,李鲜明.韶钢6号高炉碱金属的危害及其控制[J].南方金属,2009(1):38.
[2]郑朋超,张建良,刘征建,等.碱金属对焦炭热性能的影响[J].中国冶金,2017,27(5):19.
[3]张伟,王再义,张立国,等.高炉中碱金属和锌的循环及危害控制[J].鞍钢技术,2016(6):9.
[4]孙立铎,黄晓煜,杜续恩.高炉炉缸破损的原因与控制[J].钢铁,2015,50(6):1.
[5]王庆祥,尹坚.湘钢1号高炉碱金属行为[J].中国冶金,2005,15(2):18.
[6]彭其春,陈永金,陈本强,等.湘钢3号和4号高炉碱金属的分布与平衡[J].钢铁研究,2007,35(6):5.
[7]梁南山.涟钢高炉有害元素的分布与控制[J].中国冶金,2014,24(6):27.
[8]杨振和.南钢高炉碱金属分析[J].江苏科技,2002,30(6):9.
[9]范晓慧,何向宁,甘敏,等.烧结过程中碱金属的脱除及在颗粒物中的富集行为[J].中南大学学报:自然科学版,2017,48(11):2843.
[10]涂威,田仕友,王晓斌.内蒙某铁矿石脱除碱金属研究[J].酒钢科技,2014(1):1.
[11]张士敏.高炉内碱金属的平衡[J].钢铁研究学报,1982(1):9.
[12]王艺慈,那树人,陈春元,等.提高包钢高炉渣排碱能力的试验研究[J].包头钢铁学院学报,2001,20(2):104.
[13]伍世辉,刘三林,李鲜明.韶钢6号高炉碱金属的危害及其控制[J].南方金属,2009(1):38.
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