摘要
对Sb_2S_3-ZnO-C低温焙烧体系进行了热力学分析,首先分析了Sb-S-O和Sb-Zn-S-O系的优势区图,表明硫化锑直接转化为金属锑是可行的,且随着温度升高,Sb和ZnS的共存稳定区对氧分压和硫分压的要求降低;计算了在500~1 000℃下体系中各反应的标准吉布斯自由能变(ΔG~θ),表明Sb_2S_3与ZnO交互反应极易首先进行,而后发生Sb_2O_3直接还原;对Sb_2O_3和ZnO的还原平衡CO含量计算表明,Sb_2O_3较ZnO易还原。高低品位两种硫化锑精矿的焙烧试验证实了热力学分析的准确性,锑生成率和固硫率分别达90%以上和89%左右,并有进一步提高的空间。
A thermodynamic analysis was conducted for the low-temperature roasting of Sb2S3-ZnO-C system. The analysis of predominance area of Sb-S-O and Sb-Zn-S-O systems in the diagram indicated that it was feasible for Sb2S3 to be directly converted into Sb. And the oxygen partial pressure and sulfer partial pressure for the coexistence of Sb and ZnS was decreased with the temperature rising. The calculation of the Gibbs free energy change(ΔGθ) of the possible reactions in the system at the temperature of 500~1 000 ℃ showed that the interaction between Sb2S3 and ZnO was liable to be occurred firstly, followed by the reduction of Sb2O3 to Sb. The calculation of CO content for equilibrium of reduction of Sb2O3 and ZnO indicated that Sb2O3 was prone to reduction as compared to ZnO. The roasting tests with both high-and low-grade antimony sulfide concentrate verified the accuracy of thermodynamic analysis, showing the yielding rate and sulfur-fixing rate of antimony were over 90% and around 89%, respectively, which could still be further improved.
作者
欧阳臻
陈艺锋
唐朝波
陈永明
胡宇杰
叶龙刚
OUYANG Zhen;CHEN Yi-feng;TANG Chao-bo;CHEN Yong-ming;HU Yu-jie;YE Long-gang(College of Metallurgy and Material Engineering, Hunan University of Technology, Zhuzhou 412007, Hunan, China;School of Metallurgy and Environment, Central South University, Changsha 410083, Hunan, China)
出处
《矿冶工程》
CAS
CSCD
北大核心
2019年第1期72-75,78,共5页
Mining and Metallurgical Engineering
基金
国家自然科学基金(51604105)
湖南省教育厅项目(16C0463)
关键词
辉锑矿
锑冶炼
热力学计算
固硫焙烧
平衡模拟
stibnite
antimony smelting
thermodynamic calculation
sulfur-fixing roasting
equilibrium simulation
