RU194666U1 - INSTALLATION FOR TREATMENT OF GEOLOGICAL EXPLORATION SAMPLES OF DIAMOND-CONTAINING ORES - Google Patents

Abstract

The installation for processing geological prospecting samples of diamond ores refers to equipment for the processing of prospecting geological prospecting samples using the gravity concentration method according to the density and particle size characteristics of the material and includes a section type hydroclassifier in the form of a sequentially descending cascade mounted on the frame with a decrease in the level of working fluid mixture in each of them relative to each other classification chambers equipped with means for supplying the source material, systems hydraulic agitation and removal of separation products. Means of supplying the source material is made in the form of a receiving funnel, the hydraulic agitation system is designed to supply an upward flow of water and includes pressure tubes, manometers and ball valves, and the means for removing the separation products are made in the form of ball valves for unloading the concentrate and overflow troughs for moving materials along the cascade of classification chambers, with ball valves located in the lower part, and overflow troughs in the upper part of each chamber. The installation allows the processing of small exploration samples with constant monitoring by the operator, while providing the ability to quickly and accurately control the separation parameters. In addition, all units of the installation allow you to quickly and efficiently carry out its maintenance, eliminating the possibility of "infection" of the sample material previously processed, which increases the reliability of the results of processing samples. 1 s.p. f-ly, 1 ill.

Description

The utility model relates to equipment for processing bulk exploration samples using the gravitational enrichment method for density and particle size characteristics of the material.

Currently, the processing of schlich exploration samples is carried out manually with washing on the "Siberian" tray. This processing method is time-consuming due to the involvement of manual labor and ineffective due to the low extraction of a valuable component in obtaining the required volume of concentrate.

The equipment for the laboratory process for processing bulk geological exploration samples is made by various companies, such as ZAO Itomak [http://www.itomak.ru/news-equipments.php], JSC Tula NIGP [http: //tulanigp.rosgeo .com / ru / napravleniya-rabot /], etc.

However, this equipment does not provide the basic requirements for the processing of surface exploration samples of diamond-containing raw materials, such as:

1. ensuring high extraction of valuable components of indicator minerals of kimberlite with a relatively low yield of material in concentrate due to the similarity of their characteristics in density and particle size distribution with waste rock;

2. the possibility of a complete cleaning of the working elements of the equipment in order to exclude mixing ("infection") of samples;

3. The total time spent on the process of processing samples and cleaning the working elements of equipment with the mechanized method should not exceed the time spent on the process of processing samples manually using the “Siberian tray”.

A known installation for processing exploration samples [RU patent for utility model No. 27505, patent holder Open Joint Stock Company "Irgiredmet" (RU), IPC V03B 1/00, priority 23.11.2000, publ. 02/10/2003 Bull. No. 4], which includes a screen-disintegrator and an enrichment apparatus — a concentration table, a receiving hopper with water installed under the screen-disintegrator, a sand pump connected to a receiving hopper, and two hydrocyclones connected to each other, the first being connected by a pipeline to a sand pump and the second is equipped with a drain pipe with blades mounted rotatably inside it.

The disadvantage of the method of separation of prospecting exploration samples in this installation is to obtain an increased yield of waste material into concentrate when processed on a concentration table. With optimal settings of the concentration table, the yield of material in the concentrate from the initial sample can be (according to the practical test of the concentration table) more than 50%, which entails additional costs during further processing. Mechanical adjustment of the concentration table does not allow for a “fine” separation of the material into concentrate upon receipt of the required extraction.

In this regard, it is preferable to use the method of enrichment of the hydraulic classification based on gravitational separation in ascending water flows according to the density and particle size characteristics of the material.

The closest technical solution that implements this process is the installation of hydroclassification of granular materials [patent RU for utility model No. 20261, patent holder of CJSC Centrtehnomemetall (RU), IPC V03V 5/62, priority 21.06.2000, publ. 10/27/2001 Bull. No. 30], including a hydraulic screen with nozzles for inputting the initial slurry, drainage of gravel and discharge of the working slurry into a hydroclassifier, consisting of several sections, each of which is made of a classification chamber with inclined plate packages orthogonally installed in it and equipped with pipes for entering the working slurry and flushing feed water, the release of the condensed product classification through the thickener and the withdrawal of clarified pulp. The hydraulic screen and hydroclassifier sections are mounted on the frame sequentially in the form of a descending cascade with a decrease in the level of the working slurry in each of them relative to each other, the discharge pipe of the working hydraulic slurry of the hydraulic screen is connected to the input pipe of the working hydraulic slurry of the first section, the output pipes of the clarified pulp of each previous section are connected by channels branch pipes for entering the working slurry of each subsequent section, and pipes for supplying washing water of each section are made in the form of collectors connected to mounted on the frame accumulator.

However, this device, as well as other existing serial models of hydraulic classifiers of different models, is large in design and can be used in processing plants for processing large volumes of material, while a single exploration sample has only 3 kilograms. In addition, the use of such equipment does not allow for on-line monitoring and adjustment of separation parameters at the required volumes of material for processing.

The main technical result that is achieved by using the claimed utility model is the ability to accurately and quickly control the parameters of the separation process, which allows to increase the extraction of valuable components - indicators of kimberlite minerals for further research.

The claimed technical result is achieved by using an installation for processing exploration samples, including a section type hydroclassifier in the form of a sequentially descending cascade mounted on the frame with a decrease in the level of the working slurry in each of them classification chambers equipped with feed material, hydraulic agitation and exhaust system separation products. The feed material supply means is made in the form of a receiving funnel, the hydraulic agitation system includes pressure tubes, manometers and ball valves, and the separation products removal means are made in the form of ball valves for unloading concentrate and overflow troughs for moving materials along the cascade of classification chambers, while ball valves are located at the bottom, and overflow troughs are at the top of each chamber. It is possible to perform classification chambers of cylindrical shape, as well as their manufacture from optically transparent material.

A utility model is illustrated in FIG. 1, which shows a general view of an installation for processing exploration samples.

The installation for processing exploration samples of diamond-bearing ores includes a frame 1 on which are installed in the form of a descending cascade with a decrease in the level of the working fluid mixture in each of them with respect to each other classification chambers of square or round cross section with conical bases 2, 3, 4; means for supplying ascending water flows in the form of a hydraulic agitation system 5, which provides the creation of ascending water flows and includes pressure pipes 6 connecting to an external water supply line, pressure gauges 7, ball valves 8. A receiving funnel 9 is installed in the upper part of chamber 2. 2, 3, 4 are connected in the upper part by gutters for unloading the material 10; in the lower part, each chamber is equipped with ball valves for unloading concentrates 11. The design of the working chambers made of transparent organic glass provides a visual observation of the process of classifying the material into working chambers to determine settings and operational control of the separation process.

Installation works as follows. Before the classifier starts, ascending water flows are adjusted with ball valves 8 of the hydraulic agitation system 5 according to the pressure determined by manometers 7 in the classification chambers 2, 3, 4. Based on the work carried out to determine the most optimal material separation mode, the ascending water flow settings are defined as follows: camera 2-0.1 bar; chamber 3-0.2 bar; chamber 4-0.2 bar. After adjusting the ascending flows, a set of water levels is made in each chamber to the gutters 10, after which a material of a prospecting geological exploration sample is supplied to the receiving funnel 9 (size class -2 + 0.5 mm after ore preparation processes - crushing, disintegration). The material is supplied evenly with a small amount of water to accompany. Light and small material due to the ascending water flows through the drain chute 10 into the subsequent chamber 3 or 4, denser and larger material passes through the configured ascending water flows and settles at the bottom of the classification chambers 2, 3, 4. Each subsequent chamber of the classifier is a control . The discharge of the third chamber 4 is a waste product (tailings). The processing of samples occurs until the separation of the material in the classification chambers 2, 3, 4 ceases, which is determined by visual observation. After the separation of the material is completed, the upstream water supply is shut off by shutting off the ball valves 8. As a result of the sample processing, valuable products (concentrates) are formed in the conical parts of each chamber, which are lowered through the ball valves 11 and sent for drying for further analysis.

During the supply of material, it is classified according to chambers 2, 3, 4 under the influence of water flows adjusted by ball valves 5 in each chamber. The process is controlled by visual observation through the walls of the working chambers 2, 3, 4, made of transparent organic glass. Depending on the requirements for the main indicators during separation (extraction and output of valuable components) by changing the pressure in the agitation system 5, the required upward flow is created to separate the material.

It is possible to organize a closed water circulation, which allows the installation to be used in a limited space in the field. The installation allows the processing of low-volume exploration samples with constant monitoring by the operator, providing quick and accurate control of any upstream settings to separate the material according to density and particle size characteristics. In addition, all units of the installation allow you to quickly and efficiently carry out its maintenance, eliminating the possibility of "infection" of the sample material previously processed, which increases the reliability of the results of processing samples.

Claims (2)

1. Installation for processing geological prospecting samples of diamond-bearing ores, including a section type hydroclassifier in the form of a sequentially descending cascade mounted on the frame with a decrease in the level of the working slurry in each of them classification chambers equipped with feed material, hydraulic agitation systems and separation products removal systems characterized in that the means of supplying the source material is made in the form of a receiving funnel, the hydraulic agitation system includes it includes pressure tubes, manometers and ball valves, the means for removing the separation products are made in the form of ball valves for unloading the concentrate and overflow troughs for moving materials along the cascade of classification chambers, with ball valves located at the bottom and overflow troughs at the top of each chamber, classification chambers are made of optically transparent material. 2. Installation according to claim 1, characterized in that the classification chambers are cylindrical in shape.

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