Application of nanofiltration for the recovery of nickel glycinates from alkaline glycine-based solutions using polyamide membranes: A technical note

IF 4.8 2区 材料科学 Q1 METALLURGY & METALLURGICAL ENGINEERING
Huan Li, Elsayed A. Oraby, Jacobus J. Eksteen
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引用次数: 0

Abstract

Glycine has been intensively investigated as a “green” lixiviant for precious and base metals. Alkaline glycine solutions to extract Ni from sulfide resources has shown promising results. However, a considerable amount of Ni will be lost in the wash solutions when leaching residues are washed during solid-liquid separation of the leachates from their respective leach residues. In this context, this study explored Ni recovery from alkaline glycine-based wash solutions using a polyamide nanofiltration membrane. In the tests using synthetic single and multi-metal solutions, the membrane achieved >95% rejection of Ni in the selected ranges of glycine/Ni molar ratio (up to 5), pressure (15–30 bar), initial nickel concentration (0.5–1.5 g/L), sodium sulfate background concentration (∼30 g/L) and under the use of different pH modifiers (aqueous ammonia and caustic soda). When using a real solution, the concentrations of Ni and other major elements (Cu, S, Co, Mg, Zn) in the final retentate increased by about 5 times at 80 wt% permeate recovery, leaving <3 mg/L major elements in permeate. The permeate stream could be recycled in the washing stage, and the retentate stream could be combined with the pregnant leach solution (PLS) for metals recovery. The investigation demonstrates some of the technical optionality for nickel recovery from filter wash solutions utilising nanofiltration within the context of alkaline glycine-based leach technology and preliminarily demonstrates where it can be used in the structure of flowsheets to recover valuable base metals and reagents for recycle. However, the increased membrane resistance causing a low permeate flux should be concerned due to the considerable dissolved salts, precipitation of gypsum and the increasing feed concentration over time.

使用聚酰胺膜从碱性甘氨酸溶液中回收甘氨酸镍的纳滤应用:技术说明
甘氨酸作为贵金属和贱金属的 "绿色 "萃取剂受到了深入研究。用碱性甘氨酸溶液从硫化物资源中提取镍已经取得了可喜的成果。然而,在从各自的浸出残渣中进行固液分离时,浸出残渣会在洗涤溶液中损失大量的镍。在这种情况下,本研究探索了使用聚酰胺纳滤膜从碱性甘氨酸基洗涤溶液中回收镍的方法。在使用合成的单金属和多金属溶液进行的测试中,在选定的甘氨酸/镍摩尔比(最高 5)、压力(15-30 巴)、初始镍浓度(0.5-1.5 克/升)、硫酸钠背景浓度(∼30 克/升)范围内,以及在使用不同的 pH 值调节剂(氨水和苛性钠)的情况下,膜对镍的去除率均大于 95%。在使用真溶液时,当渗透回收率为 80% 时,最终回流液中镍和其他主要元素(铜、硫、钴、镁、锌)的浓度增加了约 5 倍,渗透液中主要元素的浓度为 <3 mg/L。渗透液可在洗涤阶段循环使用,而回流液则可与孕浸溶液(PLS)合并用于金属回收。这项调查展示了在基于碱性甘氨酸的浸出技术背景下,利用纳滤从过滤洗涤溶液中回收镍的一些技术可选性,并初步展示了在流程结构中使用纳滤回收有价值的贱金属和试剂进行再循环的可能性。然而,由于大量溶解盐、石膏沉淀和进料浓度随时间增加,膜阻力增加导致渗透通量低,这一点应引起关注。
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来源期刊
Hydrometallurgy
Hydrometallurgy 工程技术-冶金工程
CiteScore
9.50
自引率
6.40%
发文量
144
审稿时长
3.4 months
期刊介绍: Hydrometallurgy aims to compile studies on novel processes, process design, chemistry, modelling, control, economics and interfaces between unit operations, and to provide a forum for discussions on case histories and operational difficulties. Topics covered include: leaching of metal values by chemical reagents or bacterial action at ambient or elevated pressures and temperatures; separation of solids from leach liquors; removal of impurities and recovery of metal values by precipitation, ion exchange, solvent extraction, gaseous reduction, cementation, electro-winning and electro-refining; pre-treatment of ores by roasting or chemical treatments such as halogenation or reduction; recycling of reagents and treatment of effluents.
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