Extraction of Nickel from Ultramafic Nickel Sulfide Concentrate by Metallic Iron Addition

Metallurgical and Materials Transactions B Pub Date : 2024-06-24 DOI:10.1007/s11663-024-03179-y

Fanmao Wang, Sam Marcuson, Manqiu Xu, Mike Walker, Mansoor Barati

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Abstract

Abundant low-grade nickel sulfide ore reserves hold potential as nickel resources but are hindered by high magnesium silicate content, limiting efficient utilization. The authors investigated the possibility of extracting nickel from a low-grade ultramafic nickel sulfide concentrate into ferronickel alloy. The nickel extraction study involved thermal upgrading and physical separation. Thermal upgrading efficiently concentrated nickel values from ultramafic concentrate into ferronickel alloy, achieving over 90 pct extraction with more than 40 pct nickel grade and a characteristic particle size of d₈₀=100 µm. The presence of magnesium silicate gangues in the concentrate adversely impacted the thermal extraction of nickel. Multiple thermal treatment variables have been studied to improve nickel extraction efficiency, including metallic iron addition rate, heating duration, temperature, additives, and atmosphere. The proposed solid-state thermal upgrading method avoided smelting of materials and generation of sulfur dioxide. Magnetic separation recovered approximately 85 pct of nickel in the thermal treatment products into a ferronickel concentrate at 20 pct nickel grade.

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通过添加金属铁从超基性硫化镍精矿中提取镍

丰富的低品位硫化镍矿储量具有作为镍资源的潜力，但由于硅酸镁含量高，限制了有效利用。作者研究了将低品位超基性硫化镍精矿中的镍提取为镍铁合金的可能性。镍提取研究包括热提升和物理分离。热提升将超基性硫化镍精矿中的镍值有效浓缩到镍铁合金中，萃取率超过 90%，镍品位超过 40%，特征粒度 d80=100 µm。精矿中硅酸镁胶粒的存在对镍的热萃取产生了不利影响。为提高镍提取效率，研究了多种热处理变量，包括金属铁添加率、加热时间、温度、添加剂和气氛。拟议的固态热提升方法避免了材料的熔炼和二氧化硫的产生。磁选回收了热处理产品中约 85%的镍，将其转化为镍品位为 20%的镍铁精矿。

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Metallurgical and Materials Transactions B

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