Beneficiation of Iron Oxides from Cupola Furnace Slags for Arsenic Removal from Mine Tailings Decant Water

B. Koomson, J. Koomson, E. Asiam
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引用次数: 2

Abstract

Large volumes of ferrous metallurgical slags (FMS) are generated annually as waste materials from metal extraction, purification, casting and alloying processes worldwide. Some attempts have been made to use bulk FMS in metal precipitation and concrete works but little success has been achieved because of unstable precipitates and volume expansion of concrete structures. As a result, significant quantities of FMS are still disposed in landfills. This disposal leads to land conflicts and poor environmental practices. The present study focuses on the characterization and separation of iron oxide from selected bulk FMS (Cupola Furnace Slag - CFS) obtained from Ghana into constituent components for use as engineering materials. Quantitative X-ray diffractometry was used to determine the mineralogy of CFS. Iron oxide morphology and spot composition in the CFS were determined using scanning electron microscopy, combined with energy dispersive spectroscopy. The inductively coupled plasma-optical emission spectrometry was used to ascertain the chemical composition of CFS after acid digestion. Wet low intensity magnetic separation technique was employed for beneficiating iron oxides from the CFS. It is shown that the CFS is amorphous and consist of ferrous and non-ferrous material. Results of the investigation confirmed that ferrous materials in the slags can be separated using magnetic separation technique. The study further confirmed that fine grinding (- 75 µm) liberates the magnetic portions of the slag efficiently, and as such, they can be recovered using a low magnetic field. The recovery was 99.04 % and the concentrates obtained from the beneficiation process consist primarily of pigeonite, quartz, magnetite and jacobsite.  The beneficiated concentrates have the capacity to adsorb arsenic from mine effluent. This study has demonstrated that, slags can be utilized as secondary resources rather than a waste.
冲天炉炉渣中氧化铁的选矿除砷研究
在世界范围内,每年都有大量的铁冶金渣(FMS)作为金属提取、提纯、铸造和合金化过程中的废料产生。在金属沉淀和混凝土工程中已经进行了一些尝试,但由于沉淀不稳定和混凝土结构的体积膨胀,取得的成功很少。因此,仍有相当数量的FMS被弃置于堆填区。这种处置导致了土地冲突和恶劣的环境做法。本研究的重点是表征和分离氧化铁从选定的大块FMS(冲天炉炉渣- CFS)从加纳获得作为工程材料的组成成分。定量x射线衍射法测定了CFS的矿物学。利用扫描电子显微镜结合能量色散光谱测定了CFS中氧化铁的形态和光斑组成。采用电感耦合等离子体发射光谱法测定酸消化后CFS的化学成分。采用湿式弱磁选技术对CFS中的氧化铁进行了选矿。结果表明,CFS为非晶态,由铁和有色两种材料组成。研究结果表明,采用磁选技术可以分离出矿渣中的含铁物质。该研究进一步证实,细磨(- 75 μ m)可以有效地释放渣中的磁性部分,因此可以使用低磁场回收。选矿回收率为99.04%,精矿主要由鸽铁矿、石英、磁铁矿和雅克布铁矿组成。该选矿精矿具有吸附矿山废水中砷的能力。该研究表明,矿渣可以作为二次资源而不是废弃物加以利用。
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