Study of the colloidal-chemical and depressing characteristics of a micro- and nanosized depressant based on magnetite

IF 4.9 2区工程技术 Q1 ENGINEERING, CHEMICAL

Minerals Engineering Pub Date : 2025-05-10 DOI:10.1016/j.mineng.2025.109358

Nessipbay Tussupbayev, Dulatbek Turysbekov, Sabira Narbekova, Larissa Semushkina, Nazira Samenova

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Abstract

In this paper, magnetite was proposed as a flotation depressant for the selective separation of chalcopyrite from galena. Micro- and nanosized magnetite particles were synthesized via the chemical co-precipitation method using divalent iron and iron(III) chloride. The chemical composition, surface properties, and morphology of the synthesized magnetite were investigated using Fourier-transform infrared spectroscopy and scanning electron microscopy techniques. The adsorption properties of the surface groups of magnetite on mineral surfaces were examined by measuring the contact angle, including the electrokinetic potential. The ζ-potential measurements indicated that the micro- and nanosized magnetite particles exhibit a selective and strong depressing effect on the flotation of galena, while having a negligible impact on the flotation of chalcopyrite. The contact angle with the galena surface decreased from 94.52° to 42.70° under optimal conditions. A possible model for the adsorption of magnetite particles at the water–solid interface of the two minerals was proposed.

The article demonstrates that micro- and nano-sized magnetite particles can potentially serve as an effective, non-toxic depressant for the flotation separation of Cu–Pb bulk concentrates from polymetallic sulfide ores containing galena. When using known paramagnetic oxide materials in the form of plates, spirals, or with particle sizes above 100 µm, the separation of copper–lead concentrate into individual fractions occurs within a narrow pH range of 5.6–5.8, without requiring iron sulfate or sodium sulfite. However, to broaden the effective pH range and increase the specific surface area of the paramagnetic material, powder-form magnetite with particle sizes of 5–20 µm was employed. As a result, the separation of copper–lead concentrate occurred more distinctly at a pH range of 5.5–6.5, with a dosage of 1–1.5 kg/t of concentrate.

In our case, the use of micro- and nanosized magnetite enabled effective separation of copper–lead concentrate within a broader pH range of 5.5–7.5 and at a significantly lower reagent consumption. At an optimal dosage of 15 g/t of the proposed micro- and nanosized magnetite depressant for galena, a copper concentrate with a copper grade of 28.6 % and a recovery of 71.5 % was obtained, and a lead concentrate with a lead grade of 45.3 % and a recovery of 85.3 % was achieved. The content of lead in the copper concentrate and copper in the lead concentrate did not exceed 5 %.

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基于磁铁矿的微纳米缓蚀剂的胶体化学和抑制特性研究

本文提出用磁铁矿作为浮选抑制剂选择性分离黄铜矿和方铅矿。以二价铁和氯化铁为原料，采用化学共沉淀法合成了微、纳米级磁铁矿颗粒。利用傅里叶变换红外光谱和扫描电镜技术对合成磁铁矿的化学成分、表面性质和形貌进行了研究。通过测量接触角和电动势，考察了磁铁矿表面基团在矿物表面的吸附性能。微纳米级磁铁矿颗粒对方铅矿的浮选具有选择性和较强的抑制作用，而对黄铜矿的浮选影响可以忽略不计。在最佳条件下，与方铅矿表面的接触角由94.52°减小到42.70°。提出了两种矿物在水固界面吸附磁铁矿颗粒的可能模型。研究表明，微纳米级磁铁矿颗粒可作为一种有效的、无毒的抑制剂，在含方铅矿的多金属硫化矿石中浮选分离铜铅散装精矿。当使用已知的板状、螺旋状或粒径大于100 μ m的顺磁性氧化物材料时，铜铅精矿在5.6-5.8的狭窄pH范围内分离成单个馏分，不需要硫酸铁或亚硫酸钠。然而，为了扩大有效pH范围，增加顺磁性材料的比表面积，采用粒度为5-20µm的粉状磁铁矿。结果表明，在pH值为5.5 ~ 6.5、投加量为1 ~ 1.5 kg/t时，铜铅精矿的分离效果更为明显。在我们的研究中，使用微型和纳米级磁铁矿可以在更宽的pH范围（5.5-7.5）和更低的试剂消耗下有效地分离铜铅精矿。在最佳投加量为15 g/t的微纳磁铁矿方铅矿抑制剂条件下，可获得铜品位为28.6%、铜回收率为71.5%的铜精矿和铅品位为45.3%、铅回收率为85.3%的铅精矿。铜精矿中铅和铅精矿中铜的含量均不超过5%。

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来源期刊

Minerals Engineering 工程技术-工程：化工

CiteScore

8.70

自引率

18.80%

发文量

519

审稿时长

81 days

期刊介绍： The purpose of the journal is to provide for the rapid publication of topical papers featuring the latest developments in the allied fields of mineral processing and extractive metallurgy. Its wide ranging coverage of research and practical (operating) topics includes physical separation methods, such as comminution, flotation concentration and dewatering, chemical methods such as bio-, hydro-, and electro-metallurgy, analytical techniques, process control, simulation and instrumentation, and mineralogical aspects of processing. Environmental issues, particularly those pertaining to sustainable development, will also be strongly covered.