Technology of using rough concentrate as carrier minerals

Q2 Social Sciences

Sustainable Development of Mountain Territories Pub Date : 2023-09-30 DOI:10.21177/1998-4502-2023-15-3-568-580

Sergey Evdokimov, Karina Klykova, Iya Rubayeva, Denis Stadnik

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The main method of research is a theoretical analysis of the hydrodynamic interaction of polydisperse particles, laboratory scale flotation experiments performed on a sample of gold-bearing ores with high content of gold microdispersions using carrier minerals. Results. It is shown that the hydrodynamic resistance force acting on a solid particle from the side of unrestricted liquid flow is composed of two components. The first one is the pressure force directed along the normal to the surface of the particle, and the second one is the friction force directed along the tangent to the surface of the particle. The influence of hydrodynamic force acting on the particle from the side of liquid bounded by the wall can be accounted for by correction, in the form of the ratio of particle size to its distance to the wall, which is less than unity. Discussion. It is shown that the hydrodynamic resistance force acting on a solid particle from the side of unrestricted liquid flow is composed of two components. The first one is the pressure force directed along the normal to the surface of the particle, and the second one is the friction force directed along the tangent to the surface of the particle. The influence of hydrodynamic force acting on the particle from the side of liquid bounded by the wall can be accounted for by correction, in the form of the ratio of particle size to its distance to the wall, which is less than unity. Conclusion. In flotation with the use of carrier minerals, it is necessary to take into account the influence of a large particle – the wall – on the motion of the liquid phase and small particles. The effect of the wall on the motion of a single fine solid particle in the case of the flowing of an arbitrarily shaped particle moving parallel to the wall has been evaluated. The results obtained can also be used to assess the effect of a group of particles in a fluid, provided that the interaction between the particles can be neglected. The hydrodynamic drag force acting on a solid particle from the unrestricted fluid flow is composed of two components. The first one is the pressure force, which is directed along the normal to the surface of the particle, and the second one is the friction force, which is directed along the tangent to the surface of the particle. The effect of the hydrodynamic force acting on the particle from the side of the fluid bounded by the wall can be accounted for by a correction, in the form of the ratio of the particle size to its distance to the wall, which is less than unity. Therefore, the presence of the wall leads to an increase in the rate at which the unsteady fluid flow between the wall and the particle approaches the steady state regime and, consequently, a decrease in the magnitude of the hydrodynamic drag force acting on the particle from the side of the fluid bounded by the wall. Results of theoretical analysis and experimental studies of kinetics of thinning and breakthrough of symmetric and wetting films prove efficiency of flotation mode of particle microdispersions by introduction of carrier minerals into flotation system. It is advisable to use rough concentrate extracted from ores as a carrier material. The main flotation front in this case can be considered as an ideal displacement apparatus, in which at mixing of mineral streams the influence of the distribution of extracted particles on the flotation rate on the technological indicators of the separation process is minimal. In terms of the structure and properties of its boundary layer of water, the surface of air bubbles in water is similar to the near-surface layers of water near solid hydrophobic surfaces. Therefore, the interaction of bubble and particles during flotation is determined by the forces of hydrophobic attraction (in the case of hydrophobic particles) and hydrophilic repulsion (in the case of hydrophilic particles).The temperature dependence of these forces allows to intensify the flotation process by the effect of heat flow on the boundary layers of air bubbles. For this purpose, aeration of the pulp during flotation is carried out by a mixture of air with hot water steam. The results of flotation of gold-bearing ores according to the technological scheme with the use of rough concentrate as a carrier material and the mode of flotation with a steam-air mixture are given. Resume. The analysis of hydrodynamic interaction of polydisperse particles revealed that the presence of the wall leads to an increase in the rate of approaching the unsteady fluid flow between the wall and the particle to a steady mode and, consequently, a decrease in the value of the hydrodynamic resistance force acting on the particle from the liquid bounded by the wall. The role of identity of structure and properties of water in the boundary layers of air bubbles and in the near-surface layers of water near solid hydrophobic surfaces in flotation processes is substantiated. It was shown that the connection between the structure and properties of water in the boundary layers of water and the mechanism of flotation complex formation is that in the case of hydrophobic particles their interaction with the bubble is determined by the forces of structural hydrophobic attraction, and in the case of hydrophilic particles by the forces of structural hydrophilic repulsion. Temperature dependence of these forces makes it possible to intensify the flotation process by the effect of heat flow on water in the boundary layers of air bubbles. For this purpose, aeration of pulp is carried out by a mixture of air with hot water steam. It is shown that it is advisable to use rough concentrate extracted from ores as a carrier material. The main flotation front in this case can be considered as an ideal displacement apparatus, in which at mixing of mineral streams the influence of the distribution of extracted particles on the flotation rate on the technological indicators of the separation process is minimal. The field experiment on flotation of gold-bearing ores proved the technological efficiency of using the rough concentrate as a carrier material and the mode of flotation with a steam-air mixture. Proposals for practical application and direction of future research. The results obtained can be used in the development of technological solutions aimed at improving the performance of flotation of ores with a higher content of micro-dispersions of minerals lost with the tailings of ore dressing. 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引用次数: 0

Abstract

Introduction. The work is aimed at the development and justification of flotation technology of microdispersions of minerals, including gold. At traditional approach to a problem of effective extraction of particles which size does not exceed 10-30 microns, formation of flotation complex is investigated using the apparatus of thermodynamics. Such approach is rational for solving technological problems, when the completeness of collective extraction of all solids present in the aqueous phase is a necessary and sufficient condition. At flotation of ores the requirement of completeness of extraction of valuable components is supplemented by a condition of selective separation of minerals. Materials and methods. The main method of research is a theoretical analysis of the hydrodynamic interaction of polydisperse particles, laboratory scale flotation experiments performed on a sample of gold-bearing ores with high content of gold microdispersions using carrier minerals. Results. It is shown that the hydrodynamic resistance force acting on a solid particle from the side of unrestricted liquid flow is composed of two components. The first one is the pressure force directed along the normal to the surface of the particle, and the second one is the friction force directed along the tangent to the surface of the particle. The influence of hydrodynamic force acting on the particle from the side of liquid bounded by the wall can be accounted for by correction, in the form of the ratio of particle size to its distance to the wall, which is less than unity. Discussion. It is shown that the hydrodynamic resistance force acting on a solid particle from the side of unrestricted liquid flow is composed of two components. The first one is the pressure force directed along the normal to the surface of the particle, and the second one is the friction force directed along the tangent to the surface of the particle. The influence of hydrodynamic force acting on the particle from the side of liquid bounded by the wall can be accounted for by correction, in the form of the ratio of particle size to its distance to the wall, which is less than unity. Conclusion. In flotation with the use of carrier minerals, it is necessary to take into account the influence of a large particle – the wall – on the motion of the liquid phase and small particles. The effect of the wall on the motion of a single fine solid particle in the case of the flowing of an arbitrarily shaped particle moving parallel to the wall has been evaluated. The results obtained can also be used to assess the effect of a group of particles in a fluid, provided that the interaction between the particles can be neglected. The hydrodynamic drag force acting on a solid particle from the unrestricted fluid flow is composed of two components. The first one is the pressure force, which is directed along the normal to the surface of the particle, and the second one is the friction force, which is directed along the tangent to the surface of the particle. The effect of the hydrodynamic force acting on the particle from the side of the fluid bounded by the wall can be accounted for by a correction, in the form of the ratio of the particle size to its distance to the wall, which is less than unity. Therefore, the presence of the wall leads to an increase in the rate at which the unsteady fluid flow between the wall and the particle approaches the steady state regime and, consequently, a decrease in the magnitude of the hydrodynamic drag force acting on the particle from the side of the fluid bounded by the wall. Results of theoretical analysis and experimental studies of kinetics of thinning and breakthrough of symmetric and wetting films prove efficiency of flotation mode of particle microdispersions by introduction of carrier minerals into flotation system. It is advisable to use rough concentrate extracted from ores as a carrier material. The main flotation front in this case can be considered as an ideal displacement apparatus, in which at mixing of mineral streams the influence of the distribution of extracted particles on the flotation rate on the technological indicators of the separation process is minimal. In terms of the structure and properties of its boundary layer of water, the surface of air bubbles in water is similar to the near-surface layers of water near solid hydrophobic surfaces. Therefore, the interaction of bubble and particles during flotation is determined by the forces of hydrophobic attraction (in the case of hydrophobic particles) and hydrophilic repulsion (in the case of hydrophilic particles).The temperature dependence of these forces allows to intensify the flotation process by the effect of heat flow on the boundary layers of air bubbles. For this purpose, aeration of the pulp during flotation is carried out by a mixture of air with hot water steam. The results of flotation of gold-bearing ores according to the technological scheme with the use of rough concentrate as a carrier material and the mode of flotation with a steam-air mixture are given. Resume. The analysis of hydrodynamic interaction of polydisperse particles revealed that the presence of the wall leads to an increase in the rate of approaching the unsteady fluid flow between the wall and the particle to a steady mode and, consequently, a decrease in the value of the hydrodynamic resistance force acting on the particle from the liquid bounded by the wall. The role of identity of structure and properties of water in the boundary layers of air bubbles and in the near-surface layers of water near solid hydrophobic surfaces in flotation processes is substantiated. It was shown that the connection between the structure and properties of water in the boundary layers of water and the mechanism of flotation complex formation is that in the case of hydrophobic particles their interaction with the bubble is determined by the forces of structural hydrophobic attraction, and in the case of hydrophilic particles by the forces of structural hydrophilic repulsion. Temperature dependence of these forces makes it possible to intensify the flotation process by the effect of heat flow on water in the boundary layers of air bubbles. For this purpose, aeration of pulp is carried out by a mixture of air with hot water steam. It is shown that it is advisable to use rough concentrate extracted from ores as a carrier material. The main flotation front in this case can be considered as an ideal displacement apparatus, in which at mixing of mineral streams the influence of the distribution of extracted particles on the flotation rate on the technological indicators of the separation process is minimal. The field experiment on flotation of gold-bearing ores proved the technological efficiency of using the rough concentrate as a carrier material and the mode of flotation with a steam-air mixture. Proposals for practical application and direction of future research. The results obtained can be used in the development of technological solutions aimed at improving the performance of flotation of ores with a higher content of micro-dispersions of minerals lost with the tailings of ore dressing. Technical and economic evaluation of the efficiency of flotation technology with carrier minerals may be one of the directions of further research.

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使用粗精矿作为载体矿物的技术

简介。这项工作旨在开发和论证包括金在内的矿物微分散浮选技术。在有效萃取粒度不超过 10-30 微米的颗粒的传统方法中，使用热力学装置对浮选复合体的形成进行了研究。这种方法对于解决技术问题是合理的，因为水相中存在的所有固体的完全集体萃取是一个必要和充分的条件。在矿石浮选过程中，矿物的选择性分离条件补充了完整提取有价值成分的要求。材料和方法。研究的主要方法是对多分散颗粒的流体动力学相互作用进行理论分析，并利用载体矿物对含金量高的微分散金矿石样本进行实验室规模的浮选实验。结果显示实验表明，从液体流动不受限制的一侧作用在固体颗粒上的流体阻力由两部分组成。第一部分是沿颗粒表面法线方向的压力，第二部分是沿颗粒表面切线方向的摩擦力。流体动力的影响来自于以壁为界的液体一侧，可以通过校正的形式来考虑，校正的形式是颗粒大小与其到壁的距离之比小于 1。讨论。研究表明，从液体流动不受限制的一侧作用在固体颗粒上的流体动力阻力由两部分组成。第一部分是沿颗粒表面法线方向的压力，第二部分是沿颗粒表面切线方向的摩擦力。可以通过校正的方式来考虑从被壁包围的液体一侧作用在颗粒上的流体动力的影响，校正的形式是颗粒大小与其到壁的距离之比小于 1。结论在使用载体矿物进行浮选时，有必要考虑大颗粒--壁--对液相和小颗粒运动的影响。我们评估了在任意形状的颗粒平行于壁流动的情况下，壁对单个细小固体颗粒运动的影响。所得结果也可用于评估流体中颗粒群的影响，前提是颗粒之间的相互作用可以忽略不计。在不受限制的流体流动中，作用在固体颗粒上的流体动力阻力由两部分组成。第一部分是沿颗粒表面法线方向的压力，第二部分是沿颗粒表面切线方向的摩擦力。流体动力作用在颗粒上的影响来自以壁为界的流体一侧，可以通过修正来解释，修正的形式是颗粒大小与其到壁的距离之比小于 1。因此，壁面的存在会导致壁面和颗粒之间的非稳态流体流动接近稳态的速率增加，从而导致从壁面边界流体一侧作用在颗粒上的流体动力阻力减小。对称膜和润湿膜变薄和突破动力学的理论分析和实验研究结果证明，通过在浮选系统中引入载体矿物，颗粒微分散浮选模式的效率很高。最好使用从矿石中提取的粗精矿作为载体材料。在这种情况下，主要浮选前沿可被视为理想的置换装置，在矿物流混合时，提取颗粒的分布对浮选速率的影响对分离过程的技术指标的影响最小。就水的边界层的结构和性质而言，水中气泡的表面与固体疏水表面附近的水的近表面层相似。因此，气泡和颗粒在浮选过程中的相互作用是由疏水吸引力（对于疏水颗粒）和亲水排斥力（对于亲水颗粒）决定的。为此，在浮选过程中通过空气与热水蒸汽的混合物对矿浆进行曝气。

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来源期刊

Sustainable Development of Mountain Territories Social Sciences-Sociology and Political Science

CiteScore

2.40

自引率

0.00%

发文量

期刊介绍： International scientific journal "Sustainable development of mountain territories" covers fundamental and applied regional, national and international research and provides a platform to publish original full papers and related reviews in the following areas: engineering science and Earth science in the field of sustainable development of mountain territories. Main objectives of international scientific journal "Sustainable development of mountain territories" are: raising the level of professional scientific workers, teachers of higher educational institutions and scientific organizations; presentation of research results in the field of sustainable development of mountain areas on the technical aspects and Earth sciences, informing readers about the results of Russian and international scientific forums; improved review and editing of the articles submitted for publication; ensuring wide dissemination for the published articles in the international academic environment; encouraging dissemination and indexing of scientific works in various foreign key citation databases.