Roasting-induced phase change and its influence on phosphorus removal through acid leaching for high-phosphorus iron ore 被引量：3

Roasting-induced phase change and its influence on phosphorus removal through acid leaching for high-phosphorus iron ore

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摘要 In the present study, roasting-induced phase change and its influence on phosphorus removal via leaching has been investigated for high-phosphorus iron ore. The findings indicate that phosphorus in the ore is associated with goethite and exists mainly in amorphous Fe3PO7 phase. The phosphorus remains in the amorphous phase after being roasted below 300℃. Grattarolaite （Fe3PO7） is found in samples roasted at 600-700℃, revealing that phosphorus phase is transformed from the amorphous form to crystalline grattarolaite during roasting. Leaching tests on synthesized pure grattarolaite reveal a low rate of phosphorus removal by sulfiaric acid leaching. When the roasting tem- perature is higher than 800℃, grattarolaite is found to react with alumina to form aluminum phosphate, and the reactivity of grattarolaite with alumina increases with increasing roasting temperature. Consequently, the rate of phosphorus removal also increases with increasing roasting temperature due to the formation of acid-soluble aluminum phosphate. In the present study, roasting-induced phase change and its influence on phosphorus removal via leaching has been investigated for high-phosphorus iron ore. The findings indicate that phosphorus in the ore is associated with goethite and exists mainly in amorphous Fe3PO7 phase. The phosphorus remains in the amorphous phase after being roasted below 300℃. Grattarolaite （Fe3PO7） is found in samples roasted at 600-700℃, revealing that phosphorus phase is transformed from the amorphous form to crystalline grattarolaite during roasting. Leaching tests on synthesized pure grattarolaite reveal a low rate of phosphorus removal by sulfiaric acid leaching. When the roasting tem- perature is higher than 800℃, grattarolaite is found to react with alumina to form aluminum phosphate, and the reactivity of grattarolaite with alumina increases with increasing roasting temperature. Consequently, the rate of phosphorus removal also increases with increasing roasting temperature due to the formation of acid-soluble aluminum phosphate.

作者 Min Yang Qing-shan Zhu Chuan-lin Fan Zhao-hui Xie Hong-zhong Li

机构地区 State Key Laboratory of Multiphase Complex Systems University of Chinese Academy of Sciences Department of Chemistry

出处《International Journal of Minerals,Metallurgy and Materials》 SCIE EI CAS CSCD 2015年第4期346-352,共7页 矿物冶金与材料学报（英文版）

基金 financially supported by the National Natural Science Foundation of China (No. 21325628)

关键词 GOETHITE phosphorus removal ROASTING LEACHING goethite phosphorus removal roasting leaching

分类号 TF046.2 [冶金工程—冶金物理化学] TF53 [冶金工程—钢铁冶金]

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International Journal of Minerals,Metallurgy and Materials

2015年第4期

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