泡沫分离循环温度状态的基本原理

IF 0.2 Q4 FORESTRY Lesnoy Zhurnal-Forestry Journal Pub Date : 2023-04-25 DOI:10.21440/0536-1028-2023-2-21-31
E. Kovalenko
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引用次数: 0

摘要

研究目的是确定含金刚石金伯利岩浆液制备和泡沫分离的最佳温度制度,以确保在高选择性的过程中最大限度地回收钻石。研究方法包括电子探针x射线光谱分析,红外分光光度法,以及收集剂滴在钻石或矿物上的接触角的测量。对泡沫分离装置进行了工艺研究。研究的结果。结果表明,当泡沫分离循环的原料加热到80-85℃时,金刚石的亲水性涂层被有效地纯化,从而恢复了金刚石的自然可浮性。通过接触角测量,确定了原料药剂调理操作的温度范围为30 ~ 40℃。结果表明,在此温度范围内,钻石的防水性达到最大,而金伯利岩矿物的防水性没有显著增加。室内实验表明,在调质操作中,含浮选药剂的原料温度保持在30 ~ 38℃时,泡沫分离效果最好。采用F-5船用燃料油作为基础捕收剂,并与柴油馏分和马乔比斯基油混合浮选,确定了泡沫分离过程的最佳温度为14 ~ 24℃。经过数据分析,提出并测试了一个温度体系,其中包括泡沫分离原料在浆液去除和浮选试剂调理操作之前加热至85°C,以及随后在泡沫分离原料调理(30°C)和泡沫分离过程本身(18°C)操作中积累的热量的使用。该技术的前景。在试验台上对泡沫分离过程所选择的温度范围进行的测试结果表明,使用现有和潜在的捕收剂,包括F-5船用燃料油及其化合物,有可能使钻石在精矿中的回收率提高2.3-4.5%。已开发的制度被推荐用于阿尔罗莎加工厂泡沫分离循环的商业开发。
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Rationale for the temperature regime of the foam separation cycle
The research objective is to determine the optimal temperature regimes for slurry preparation and foam separation of diamond-bearing kimberlites to ensure maximum diamond recovery under high selectivity of the process. Methods of research include the electron probe X-ray spectral analysis, IR spectrophotometry, and measurement of the contact angles of a collecting agent drop on diamonds or minerals. Technological studies were carried out on the setup for foam separation. Research results. It was shown that when the feedstock of the foam separation cycle is heated to a temperature of 80–85 °C the diamonds are effectively purified from hydrophilic coatings, which leads to the restoration of their natural floatability. Through contact angles measurement, the temperature range of 30–40 °C was determined in the feedstock reagent conditioning operation. It is shown that the maximum water repellence of diamonds is achieved in this temperature range without a significant increase in the kimberlite minerals water repellence. Laboratory experiments have shown that the best foam separation results are achieved when in the conditioning operation the feedstock with flotation reagents is maintained at a temperature of 30–38 °C. The flotation studies using F-5 bunker fuel oil as base collecting agent, as well as its compounds with diesel fraction and Machchobinsky oil, determined the optimal temperature of 14–24 °C directly in the process of foam separation. After data analysis, a temperature regime was proposed and tested, which includes the foam separation feedstock heating before the operation of slurry removal and conditioning with flotation reagents up to 85 °C and the subsequent use of accumulated heat in the operations of foam separation feedstock conditioning (30 °C) with reagents and the foam separation process itself (18 °C). The prospects of the technology. The test results of the selected temperature regime for the foam separation process on a test bench show the possibility of increasing the diamonds recovery into the concentrate by 2.3–4.5% when using applied and potential collecting agents, including F-5 bunker fuel oil and compounds based on it. The developed regime is recommended for commercial development in the foam separation cycle at Alrosa processing plants.
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