In this thesis, equilibrium and dynamic sorption properties of weakly basic chelating adsorbents were studied to explain removal of copper, nickel from a concentrated zinc sulfate solution in a hydrometallurgical process. Silica-supported chelating composites containing either branched poly(ethyleneimine) (BPEI) or 2-(aminomethyl)pyridine (AMP) as a functional group were used. The adsorbents are commercially available from Purity Systems Inc, USA as WP-1® and CuWRAM®, respectively. The fundamental interactions between the adsorbents, sulfuric acid and metal sulfates were studied in detail and the results were used to find the best conditions for removal of copper and nickel from an authentic ZnSO4 process solution. In particular, the effect of acid concentration and temperature on the separation efficiency was considered. Both experimental and modeling aspectswere covered in all cases. Metal sorption is considerably affected by the chemical properties of the studied adsorbents and by the separation conditions. In the case of WP-1, acid affinity is so high that column separation of copper, nickel and zinc has to be done using the adsorbent in base-form. On the other hand, the basicity of CuWRAM is significantly lower and protonated adsorbent can be used. Increasing temperature decreases the basicity and the metals affinity of both adsorbents, but the uptake capacities remain practically unchanged. Moreover, increasing temperature substantially enhances intra-particle mass transport and decreases viscosities thus allowing significantly higher feed flow rates in the fixed-bed separation. The copper selectivity of both adsorbents is very high even in the presence of a 250-fold excess of zinc. However, because of the basicity of WP-1, metal precipitation is a serious problem and therefore only CuWRAM is suitable for the practical industrial application. The optimum temperature for copper removal appears to be around 60 oC and an alternative solution purification method is proposed. The Ni/Zn selectivity of both WP-1 and CuWRAM is insufficient for removal of the very small amounts of nickel present in the concentrated ZnSO4 solution.
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机译:本文研究了弱碱性螯合吸附剂的平衡和动态吸附性能,以解释湿法冶金过程中从浓硫酸锌溶液中去除铜,镍的方法。使用含有支链聚(乙烯亚胺)(BPEI)或2-(氨基甲基)吡啶(AMP)作为官能团的二氧化硅支撑的螯合复合物。吸附剂可分别从美国Purity Systems Inc.和购得。详细研究了吸附剂,硫酸和金属硫酸盐之间的基本相互作用,并将结果用于寻找从真实ZnSO4工艺溶液中去除铜和镍的最佳条件。特别地,考虑了酸浓度和温度对分离效率的影响。在所有情况下都涵盖了实验和建模方面。金属吸附受所研究吸附剂的化学性质和分离条件的影响很大。在WP-1的情况下,酸亲和力是如此之高,以致必须使用碱形式的吸附剂进行铜,镍和锌的柱分离。另一方面,CuWRAM的碱性大大降低,可以使用质子化的吸附剂。温度升高会降低两种吸附剂的碱性和金属亲和力,但吸收能力实际上保持不变。而且,升高温度实质上增强了颗粒内的质量传递并降低了粘度,因此在固定床分离中允许明显更高的进料流速。即使存在过量250倍的锌,两种吸附剂的铜选择性也非常高。但是,由于WP-1的碱性,金属沉淀是一个严重的问题,因此只有CuWRAM适合于实际的工业应用。去除铜的最佳温度似乎在60 oC左右,并提出了另一种溶液纯化方法。 WP-1和CuWRAM的Ni / Zn选择性不足以去除浓ZnSO4溶液中存在的极少量镍。
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