Separation of pentlandite from serpentine using the selective magnetic coating-magnetic separation technology
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摘要: 針對鎳黃鐵礦和蛇紋石浮選難分離,提出采用磁罩蓋法進行磁分離.結果表明,控制一定的礦漿物化條件,隨著磁種磁鐵礦的添加,鎳黃鐵礦的磁選回收率隨之升高,而蛇紋石的回收率基本保持很低,可實現兩者的良好分離.人工混合礦分離結果表明,磁種質量分數為5%時,獲得的精礦Ni品位為19.89%,回收率為92.46%,MgO質量分數為4.72%;X射線衍射和掃描電鏡分析結果顯示磁鐵礦在鎳黃鐵礦表面產生了罩蓋,在蛇紋石表面未產生明顯的罩蓋;Zeta電位測試和DLVO理論計算結果表明,添加六偏磷酸鈉后,蛇紋石表面電性由正變負,而對鎳黃鐵礦和磁鐵礦表面電性未產生顯著影響,從而使磁鐵礦與蛇紋石間的相互作用變為排斥,而與鎳黃鐵礦之間仍為吸引,因而磁鐵礦選擇性罩蓋在鎳黃鐵礦表面,增強其磁性,實現與蛇紋石的磁分離.Abstract: Magnetic coating magnetic separation method was proposed to separate pentlandite from serpentine, which is difficult to separate them using flotation. Results show that under certain physical and chemical conditions of slurry, the pentlandite recovery increases with the amounts of magnetite increasing, while the recovery of serpentine remains at a low level, indicating that their separation could be realized. The separation results of the artificial mixtures show that with addition of 5% magnetite, a concentrate of 19.89% Ni with a recovery of 92.46% and MgO mass content of 4.72% are obtained. The results of X-ray diffraction (XRD) and scanning electron microscopy (SEM) demonstrate that quantities of magnetite particles adhere to the pentlandite surfaces whereas the surface of serpentine is not clearly coated by the magnetite. The Zeta potential analyses and DLVO calculations suggest that with the addition of sodium hexametaphosphate (SHMP), the Zeta potential of serpentine reverses from positive to negative while those of pentlandite and magnetite are not affected significantly. Thus, it made the interaction of magnetite-serpentine become repulsion while that of magnetite-pentlandite remain attraction. Consequently, magnetite particles selectively adhere to the surface of pentlandite and enhance its magnetism, resulting in the magnetic separation of pentlandite from serpentine.
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Key words:
- pentlandite /
- serpentine /
- magnetite /
- selective magnetic coating /
- magnetic separation
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參考文獻
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