钒钛铁精矿煤基直接还原试验研究
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摘要
对印尼钒钛铁精矿和攀枝花红格钒钛铁精矿进行了直接还原对比试验研究,对比试验结果表明:印尼钒钛铁精矿造球性能远远好于攀枝花红格的钒钛铁精矿,能够满足工业生产过程的运输要求。印尼钒钛铁精矿含碳球团在还原温度1350℃,还原15 min条件下金属化率可以达到90%左右,金属化球团残碳量为6%,可以满足后续熔分的要求。经过再磨再选后,TiO_2的含量可以达到12%左右,经过直接还原-熔分后富集的熔分钛渣TiO_2的品味理论上能达到48%左右,可以作为硫酸法钛白的原料。研究表明,印尼钒钛铁精矿非常适合采用直接还原-电炉熔分工艺进行处理,其Fe,V,Ti等有益元素能够得到很好的回收利用。相比于攀枝花红格钒钛铁精矿,印尼钒钛铁精矿由于选矿工艺简单,成本低廉,比攀枝花红格钒钛铁精矿更具市场竞争力。
Comparative study on direct reduction of Indonesian sea water sandy vanadium titanium iron ore concentrate and Panzhihua Hongge vanadium and titanium iron ore concentrate was carried on. Test results show that the pellet performance of the Indonesian vanadium and titanium iron ore concentrate is much better than Panzhihua Hongge vanadium and titanium iron ore concentrate through direct reduction comparative study. Pellets of Indonesian vanadium titanium iron concentrate could meet the transport requirements of industrial production process. Metalification rate of indonesian vanadium and titanium iron ore concentrate could reach 90% and residual carbon content was 6% at a reduction temperature was 1350°C and a reduction time was 15 min, which could meet the requirements of furnace melting and separation. Theory content of molten titanium slag could reach about 48% after the direct reduction-melt fractions when the content of TiO_2 reach about 12% after regrinding and selected, which could be used as raw materials of sulfuric acid titanium dioxide. The study shows that the indonesian vanadium-titanium iron concentrate was very suitable for the direct reduction-electric furnace melting process,and its beneficial elements such as Fe, V and Ti could be well recovered. Indonesia vanadium-titanium iron concentrate has more market competitiveness compared with panzhihua hongge vanadium-titanium iron concentrate because of its simple ore dressing process and low cost.
Comparative study on direct reduction of Indonesian sea water sandy vanadium titanium iron ore concentrate and Panzhihua Hongge vanadium and titanium iron ore concentrate was carried on. Test results show that the pellet performance of the Indonesian vanadium and titanium iron ore concentrate is much better than Panzhihua Hongge vanadium and titanium iron ore concentrate through direct reduction comparative study. Pellets of Indonesian vanadium titanium iron concentrate could meet the transport requirements of industrial production process. Metalification rate of indonesian vanadium and titanium iron ore concentrate could reach 90% and residual carbon content was 6% at a reduction temperature was 1350°C and a reduction time was 15 min, which could meet the requirements of furnace melting and separation. Theory content of molten titanium slag could reach about 48% after the direct reduction-melt fractions when the content of TiO_2 reach about 12% after regrinding and selected, which could be used as raw materials of sulfuric acid titanium dioxide. The study shows that the indonesian vanadium-titanium iron concentrate was very suitable for the direct reduction-electric furnace melting process,and its beneficial elements such as Fe, V and Ti could be well recovered. Indonesia vanadium-titanium iron concentrate has more market competitiveness compared with panzhihua hongge vanadium-titanium iron concentrate because of its simple ore dressing process and low cost.
引文
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[7]钒钛磁铁矿综合利用提取研究小组.铁、钒、钛氧化物选择性还原热力学及钒钛磁铁矿的铁、钒、钛分离的试验研究[J].东北工学院学报,1975(4):27-38
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[10]HuT,Lv X W,Bai C Q,etal.Isothermal Reduction of Titanomagnetite Concentrates Containing Coal[J].International Journal of Minerals Metallurgy and Materials,2014,21(2):131-137.
[11]曹明明,张建良,邢相栋,等.钒钛磁铁矿含碳球团的还原机制[J].钢铁,2012,47(8):5-11.
[2]Fu W G,Wen Y C,Xie H E.Development of Intensified Technologies of Vanadium-Bearing Titanomagnetite Smelting[J].Journal of Iron and Steel Research International,2011,18(4):7-10.
[3]李兴华,蒲江涛.攀枝花高钛型高炉渣综合利用研究最新进展[J].钢铁钒钛,2011,32(2):10-14.
[4]曹明明,张建良,邢相栋,等.钒钛磁铁矿含碳球团直接还原研究[J].钢铁钒钛,2012,33(4):28-33.
[5]都兴红,谢斌,粪太平.钒钛磁铁矿固态还原研究[J].东北大学学报,2012,33(5);685-688.
[6]陈双印,唐巧,储满生,等.飢铁磁铁矿的煤粉还原过程[J].过程工程学报,2013,13(2):236-240.
[7]钒钛磁铁矿综合利用提取研究小组.铁、钒、钛氧化物选择性还原热力学及钒钛磁铁矿的铁、钒、钛分离的试验研究[J].东北工学院学报,1975(4):27-38
[8]何其松.钒钛磁铁矿球团的还原历程及其热力学分析[J].钢铁,1983,18(4):1-6.
[9]刘松利,白晨光,胡途.妍铁铁精矿内配碳球团髙温快速直接还原历程[J].重庆大学学报,2011,34(1):60-65.
[10]HuT,Lv X W,Bai C Q,etal.Isothermal Reduction of Titanomagnetite Concentrates Containing Coal[J].International Journal of Minerals Metallurgy and Materials,2014,21(2):131-137.
[11]曹明明,张建良,邢相栋,等.钒钛磁铁矿含碳球团的还原机制[J].钢铁,2012,47(8):5-11.
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