RU2806272C1 - Modular concentration bowl of centrifugal concentrator (embodiments) - Google Patents

Abstract

FIELD: enrichment of minerals.

SUBSTANCE: claimed group of inventions is related to devices intended for enrichment of minerals and can be used to separate solid particles by density. It can be used for processing gold ores and fine sands, as well as copper-nickel ores that are not amenable to magnetic separation. The modular concentration bowl of a centrifugal concentrator consists of interconnected upper and lower parts, as well as a working surface attached to them, while the upper part of the bowl has an internal frame, the working surface covers the inner surface of the upper part of the concentration bowl with the formation of protrusions and cavities between the protrusions. The flange of at least one protrusion has a configuration in which the thickness of the protrusion in cross section changes, and the inclination angle of the flange portion of at least one protrusion differs from the inclination angle of the flange portion of at least one other protrusion. According to the second embodiment of the modular concentration bowl of the centrifugal concentrator, the cross-sectional area of at least one protrusion differs from the cross-sectional area of at least one other protrusion, and the inclination angle of the shelf part of at least one protrusion differs from the inclination angle of the shelf part of at least one other protrusion.

EFFECT: increase of service life of the concentration bowl.

13 cl, 5 dwg

Description

Technical field

[0001] The claimed invention relates to devices intended for the beneficiation of minerals, and can be used to separate solid particles by density. As an example, the claimed invention can be used for processing gold ores and fine sands, as well as copper-nickel ores that are not amenable to magnetic separation.

State of the art

[0002] A known technical solution is disclosed in the patent for invention RU 2579160 C1 (IPC B03B 5/32, H02K 33/00, B04B 7/08, B04B 9/10; published 04/10/2016) “Centrifugal concentrator”, which is centrifugal concentrator of periodic action. The known device contains a cone-shaped concentration bowl. The internal frame of the concentration bowl is made monolithic and consists of a base and a side wall. The side wall of the frame contains a number of metal frame ribs. The working surface of the concentration bowl is formed by the inner surface of the concentration bowl and contains a number of protrusions formed by the frame ribs and cavities located between them.

[0003] The known device has a number of disadvantages, namely the fact that the internal frame of the concentration bowl is made monolithic, which eliminates the possibility of replacing the upper and lower parts of the concentration bowl independently of each other, and also excludes the possibility of vertical division of the concentration bowl into interchangeable vertical segments . Another disadvantage is that in the source the cross-sectional area of the protrusions is the same for all protrusions, including the width of the protrusions and the angle of inclination of the shelves of these protrusions are the same, which leads to a decrease in the wear resistance of the device elements due to the uneven distribution of the load during operation. Also, sufficient separation efficiency is not ensured, since identical protrusions do not allow taking into account the changing density and content of the separated substances during the separation process. In the claimed technical solution, the effectiveness of the device is achieved by possibly making protrusions of a complex configuration, for example, sinusoidal in shape, or by making vertical protrusions on the shelves of the protrusions, for example, in the form of a tooth.

[0004] A known technical solution is disclosed in the patent application for the invention WO 2019144179 A1 (IPC B04B 15/06, B04B 7/08, B04B 7/14; published 08/01/2019) “Bowl for a centrifugal batch concentrator”, which represents is a concentration bowl of a centrifugal concentrator. The known concentration bowl consists of at least two vertical segments that are hollow inside, each of which consists of two vertical parts. The design of the vertical segments has protrusions and cavities located between the protrusions on the inside. The cavities contain nozzles for injection of fluidizing liquid. At least one insert made of wear-resistant material is fixed on the surface of at least one protrusion. As one of the possible embodiments of the known concentration bowl, inserts made of wear-resistant material can be located inside the protrusions of the vertical segments of the concentration bowl.

[0005] The disadvantage is that in the source the cross-sectional area of the protrusions is the same for all protrusions, including the width of the protrusions and the angle of inclination of the shelves of these protrusions are the same, which leads to a decrease in the wear resistance of the device elements due to uneven load distribution during operation. Also, sufficient separation efficiency is not ensured, since identical protrusions do not allow taking into account the changing density and content of the separated substances during the separation process. In the claimed technical solution, the effectiveness of the device is achieved by possibly making protrusions of a complex configuration, for example, in the form of a sinusoidal shape or by making vertical protrusions on the shelves of the protrusions, for example, in the form of a tooth.

[0006] Another close to the claimed invention can be considered the solution disclosed in the patent for the invention US 7144360 B2 (IPC B04B 11/04; published 12/05/2006) “Centrifugal separator with a strip-shaped insert element installed in a bowl,” which is a centrifugal batch concentrator. The known device contains a cone-shaped concentration bowl. The internal frame of the concentration bowl is modular and contains a base and a side wall, the upper part of which is removable. In this case, the side wall of the inner frame of the concentration bowl, in turn, contains metal ribs that form protrusions on the working surface of the concentration bowl, and cavities for collecting products of gravitational separation of the mixture. The metal ribs of the inner frame are attached to the modular side wall of the inner frame of the concentration bowl using fasteners to form the internal support structure. The metal ribs of the inner frame of the concentration bowl, in turn, are covered with an elastic material that forms a working surface that can be replaced. Inserts made of wear-resistant material are attached to the protrusions on the working surface formed by the metal ribs of the internal frame. The cavities located between the protrusions formed by the ribs of the internal frame on the working surface of the concentration bowl are equipped with nozzles for injecting the fluidizing liquid.

[0007] The known device operates as follows. The mixture is fed into the cone-shaped concentration bowl using a source material feeder. After this, the concentration bowl is rotated. Then the fluidizing liquid is supplied through the nozzles, and the components of the mixture that have a higher density are collected in the cavities of the working surface, after which they are removed using a concentrate unloading device. Also, using a tailings removal device, light fractions obtained as a result of the gravitational separation process are removed.

[0008] The known technical solution has a number of significant disadvantages, which consist in the fact that in the source the cross-sectional area of the protrusions is the same for all protrusions, including the width of the protrusions and the angle of inclination of the shelves of these protrusions are the same, which leads to a decrease in the wear resistance of the device elements in due to uneven load distribution during operation. Also, sufficient separation efficiency is not ensured, since identical protrusions do not allow taking into account the changing density and content of the separated substances during the separation process. In the claimed technical solution, the effectiveness of the device is achieved by possibly making protrusions of a complex configuration, for example, in the form of a sinusoidal shape or by making vertical protrusions on the shelves of the protrusions, for example, in the form of a tooth.

[0009] Another solution is known (RU 2775527 C1; publ. 07/04/2022; IPC: B04B 3/00, B04B 7/08, B03B 5/28, B03B 5/32), which describes the design of a modular concentration bowl of a centrifugal concentrator, consisting of upper and lower parts connected to each other, as well as a working surface attached to them, while the upper part of the bowl has an internal frame, the working surface covers the inner surface of the upper part of the concentration bowl with the formation of protrusions and cavities between the protrusions, while, for the formation, of at least one protrusion, at least one insert is attached to the inner frame of the upper part of the bowl.

[0010] The disadvantage of this technical solution is the insufficiently high wear resistance associated with abrasive wear of the protrusions during operation of the device. In this case, wear occurs unevenly, increasing from the lower protrusions to the upper ones due to more active filling during gravitational separation of a mixture of solid particles of different densities. Another disadvantage is the insufficient quality of mixing of solid particles of the mixture, due to the shape of the protrusions and cavities in the upper part of the concentration bowl. These disadvantages are due to the fact that in the source the cross-sectional area of the protrusions is the same for all protrusions, including the width of the protrusions and the angle of inclination of the shelves of these protrusions are the same, which leads to a decrease in the wear resistance of the device elements due to the uneven distribution of the load during operation. Also, sufficient separation efficiency is not ensured, since identical protrusions do not allow taking into account the changing density and content of the separated substances during the separation process. In the claimed technical solution, the effectiveness of the device is achieved by possibly making protrusions of a complex configuration, for example, in the form of a sinusoidal shape or by making vertical protrusions on the shelves of the protrusions, for example, in the form of a tooth.

[0011] Another technical solution (RU 2775528 C1; publ. 07/04/2022; IPC: B04B 1/00) includes a modular concentration bowl consisting of interconnected upper and lower parts, as well as a working surface attached to them, wherein the upper part of the bowl includes at least two vertical segments attached to the frame of the upper part of the bowl, the vertical segments including an internal frame covered with a work surface material with the formation of projections and cavities between the projections.

[0012] A disadvantage of this technical solution is also the insufficiently high wear resistance associated with abrasive wear of the protrusions during operation of the device. In this case, wear occurs unevenly, increasing from the lower protrusions to the upper ones due to more active filling during gravitational separation of a mixture of solid particles of different densities. Another disadvantage is the insufficient quality of mixing of solid particles of the mixture, due to the shape of the protrusions and cavities in the upper part of the concentration bowl. These disadvantages are due to the fact that in the source the cross-sectional area of the protrusions is the same for all protrusions, including the width of the protrusions and the angle of inclination of the shelves of these protrusions are the same, which leads to a decrease in the wear resistance of the device elements due to the uneven distribution of the load during operation. Also, sufficient separation efficiency is not ensured, since identical protrusions do not allow taking into account the changing density and content of the separated substances during the separation process. In the claimed technical solution, the effectiveness of the device is achieved by possibly making protrusions of a complex configuration, for example, in the form of a sinusoidal shape or by making vertical protrusions on the shelves of the protrusions, for example, in the form of a tooth.

[0013] The disadvantage of all the mentioned solutions is the insufficiently high efficiency and wear resistance caused by abrasive wear that is uneven in the height of the protrusions during operation of the device, caused by the process of gravitational separation. Another disadvantage is the insufficient quality of mixing of solid particles of the mixture, which is associated with the geometry of the profile of the concentration bowl and the protrusions themselves.

The essence of the invention

[0014] The objective of the present invention is to create a device for gravitational separation of ores with a long service life and efficiency, due, among other things, to improved mixing of solid particles of the mixture.

[0015] This problem is solved by achieving the technical result of the claimed invention, which consists in increasing the separation efficiency, including due to the service life of the concentration bowl and its maintainability.

[0016] The main component that is subject to maximum abrasion during operation of a centrifugal concentrator is its concentration bowl. In the claimed invention, the concentration bowl is made modular. The concentration bowl consists of two interconnected parts: the upper part of the concentration bowl and the lower part of the concentration bowl, as well as the working surface attached to them. In this case, the upper part of the bowl has an internal frame, the working surface covers the inner surface of the upper part of the concentration bowl with the formation of protrusions and cavities between the protrusions. Moreover, the angle of inclination of the part of the shelf of at least one protrusion differs from the angle of inclination of the part of the shelf of at least one other protrusion. The internal frame serves to stiffen the upper part of the bowl, thereby increasing the service life due to its strength. That surface of the bowl that directly interacts with the mixture of solid particles and ensures the separation process due to the presence of protrusions and cavities during the rotation of the bowl is called working. In this case, the upper and lower parts can be made replaceable, independently of each other. This design of the concentration cone ensures ease of use of the claimed invention, efficiency, and also increases the service life of the centrifugal concentrator, the functional element of which is the claimed modular concentration bowl. Another possible embodiment of the bowl, which helps to improve maintainability, is to make the upper part of the bowl from segments that support independent replacement.

[0017] Increased separation efficiency is ensured by making the upper part of the protrusions part of one of the variants in such a way that the shelf of at least one protrusion has a complex configuration. By complex configuration we mean such a geometry of the protrusion that in its longitudinal section the protrusion has a deviation from the horizontal axis passing through the center of the segment limited by the highest and lowest points of the shelf. For example, in the case of making both shelves of a sinusoidal shape while maintaining the thickness of the protrusions in the cross section. Also included in the concept of a complex configuration is a change in the thickness of the protrusion in the cross section, including in a limited area. Such a change in thickness can be due to either the sinusoidal shape of one shelf, or two shelves with a mirror-symmetrical sinusoidal design relative to each other, or the implementation of more strict structural elements, for example, vertical protrusions. The concept of a complex configuration does not include a protrusion, which in cross section has a constant thickness, and the horizontal axis runs strictly in the center of the protrusion along its entire length. The complex configuration of the shelves of the protrusions contributes to the emergence of additional turbulence of solid particles inside the cavities between the protrusions, which improves the quality of the particle separation process due to their additional mixing, due to the presence of flat sections of the curve of the specified shape. This ensures increased efficiency of mixing the mixture of solid particles, and therefore their separation. Additionally, an option is implemented in which the angle of inclination of the shelf part of at least one protrusion differs from the angle of inclination of the shelf part of at least one other protrusion. Making the protrusions of exactly this shape, including those divided into a horizontal part and an inclined part, ensures an increase in the working life of the protrusions compared to similar elements of the same shape by increasing their thickness in both longitudinal and cross sections, which prevents rapid abrasive wear of the mentioned parts bowls and thereby increases separation efficiency. In a possible embodiment of the projections, the angles of inclination of the shelves of each projection are different from each other. This further increases the service life of the bowl and the efficiency of separation due to the increase in the working life of each protrusion, taking into account the load placed on it during operation. In addition to the implementation of the protrusions presented above, it can be additionally organized to reduce the angles of inclination of the parts of the shelves of the protrusion from the upper protrusion to the lower one, thereby increasing the separation efficiency and ensuring an increase in service life by preventing rapid abrasive wear of parts, which increases from the upper protrusion to the lower one. An additional improvement in the technical result is ensured by ensuring that the angles of inclination of the parts of the shelves of each of the protrusions are different, i.e. it is possible to realize a gradual increase in the life of the protrusions as the solid particles of the mixture move and, consequently, increase the wear of parts. Another version of the modular concentration bowl of a centrifugal concentrator is designed in such a way that the width of the shelf of at least one protrusion differs from the width of the shelf of at least one other protrusion. Increasing the service life of the bowl and separation efficiency in this case is achieved by increasing the working life of the protrusions compared to similar elements of the same shape by increasing their width, which prevents rapid abrasive wear of the mentioned bowl parts. It is also possible to technically implement a bowl in which the width of the flanges of each protrusion increases from the upper to the lower protrusion, thereby increasing the separation efficiency and service life by preventing rapid abrasive wear of parts, which increases from the upper to the lower protrusion. Increased wear resistance can also be achieved by making at least one protrusion from a wear-resistant material. Further improvements in wear resistance can also be achieved by using a filled epoxy compound for the running surface forming the ridges. In one of the technical implementations of the bowl, in order to increase the maintainability and service life of the device, at least one of the protrusions can be replaced independently of the other protrusions.

[0018] Another version of the modular concentration bowl of a centrifugal concentrator contains interconnected upper and lower parts, as well as a working surface attached to them, wherein the upper part of the bowl has an internal frame, the working surface covers the inner surface of the upper part of the concentration bowl with the formation of protrusions and cavities between the protrusions, wherein the shelf of at least one protrusion has at least one vertical protrusion, for example, in the form of a tooth. This technical implementation also promotes additional mixing of particles, since the vertical protrusions act as barriers to the free movement of particles within a given cavity, which leads to their forced mixing within the portion of the cavity limited by the vertical protrusions or protrusion. This has a positive effect on particle separation due to additional turbulence of the mixture. Particular forms of implementation of this option are also indicated above.

[0019] Another version of the modular concentration bowl of a centrifugal concentrator contains interconnected upper and lower parts, as well as a working surface attached to them, wherein the upper part of the bowl has an internal frame, the working surface covers the inner surface of the upper part of the concentration bowl with the formation of protrusions and cavities between the protrusions, wherein the cross-sectional area of at least one protrusion differs from the cross-sectional area of at least one other protrusion. Moreover, the angle of inclination of the part of the shelf of at least one protrusion differs from the angle of inclination of the part of the shelf of at least one other protrusion. In this case, increasing the efficiency and service life of the bowl is achieved, among other things, by increasing the width of the shelf and/or the thickness of at least one protrusion due to the difference in the cross-sectional area, which prevents rapid abrasive wear of the mentioned parts of the bowl and ensures an increase in the working life of the protrusions compared to similar elements of the same shape.

Description of drawings

[0020] The subject matter of this application is described point by point and clearly stated in the claims. The above-mentioned objects, features and advantages of the invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, in which:

[0021] In FIG. Figure 1 shows a block diagram of a modular concentration bowl of a centrifugal concentrator with a complex configuration in the form of sinusoidal protrusions.

[0022] In FIG. Figure 2 shows a block diagram of a modular concentration bowl of a centrifugal concentrator with a complex configuration in the form of vertical protrusions on the shelves.

[0023] In FIG. Figure 3 shows a block diagram of a modular concentration bowl of a centrifugal concentrator with a variable area of protrusions in cross section by changing the thickness of the protrusions and the width of the protrusion flanges.

[0024] In FIG. Figure 4 shows a structural diagram of a modular concentration bowl of a centrifugal concentrator with a variable area of protrusions in cross section by changing the thickness of the protrusions due to different inclination angles of parts of the protrusion shelves.

[0025] In FIG. Figure 5 shows a block diagram of a modular concentration bowl of a centrifugal concentrator with a variable area of protrusions in cross section by changing the width of the protrusion flanges.

[0026] These drawings are illustrated by the following positions: The upper part of the concentration bowl – 1; Working surface of the bowl – 2; Protrusions – 3; Cavities – 4; Ledge shelf – 5; Horizontal section of the protrusion flange – 6; Inclined section of the protrusion flange – 7; Vertical projection – 8.

Detailed Description of the Invention

[0027] The following detailed description of the invention sets forth numerous implementation details designed to provide a clear understanding of the present invention. However, it will be apparent to one skilled in the art how the present invention can be used with or without these implementation details. In other cases, well-known methods, procedures and components are not described in detail so as not to unduly obscure the features of the present invention.

[0028] In addition, from the above discussion it is clear that the invention is not limited to the above implementation. Numerous possible modifications, alterations, variations and substitutions, while retaining the spirit and form of the present invention, will be apparent to those skilled in the art.

[0029] In FIG. Figure 1 shows a block diagram of one of the embodiments of the modular concentration bowl of a centrifugal concentrator. The concentration bowl consists of two interconnected parts: the upper part of the concentration bowl 1 and the lower part of the concentration bowl, as well as the working surface 2 attached to them. In this case, the upper part of the bowl 1 has an internal frame (not shown), the working surface 2 covers the inner surface the upper part of the concentration bowl 1 with the formation of protrusions 3 and cavities 4 between the protrusions 3. The internal frame serves to impart rigidity to the upper part of the bowl, thereby increasing the service life due to its strength. Its design can follow the geometry of the uppermost part of the bowl 1, and also have ribs placed under the protrusions 3 to give greater rigidity to the structure. As a material for making the ribs of the internal frame of the upper part 1 of the concentration bowl, any known high-strength metal can be used, for example, steel of the appropriate grades, a composite material with a suitable set of properties, or polymers with a suitable set of properties, which is necessary to ensure the effectiveness of the inventive device, increase its service life, as well as ensuring its maintainability. Other parameters, including the geometry of the frame itself, are known from the prior art. The working surface 2 directly interacts with the mixture of solid particles and ensures the separation process due to the presence of protrusions 3 and cavities 4 during rotation of the bowl. In this case, the upper 1 and lower parts of the bowl are made replaceable, independently of each other. This design of the concentration cone ensures ease of use of the claimed invention, and also increases the service life of the centrifugal concentrator, the functional element of which is the claimed modular concentration bowl. An increase in service life is ensured by the possibility of replacing, for example, due to wear of parts, one of the parts of the device without the participation of the other, which allows the bowl to be used for a long period. Another option for making the bowl, which helps to increase maintainability and service life, is to make the upper part of the bowl 1 from segments that support independent replacement. In this case, the upper part 1 can be divided into at least 2 vertical segments attached to the outer frame of the bowl, or by other means.

[0030] The protrusions 3 in the structure of the claimed invention may have a V-shaped cross-section, a U-shaped shape or a trapezoidal shape, or another with the formation of cavities 4 between them.

[0031] Increasing the service life and efficiency of the concentration bowl is ensured by making projections 3 in one of the variants of the upper part 1 in such a way that the shelf 5 of at least one projection 3 has a complex configuration, for example, in the form of a sinusoidal shape, as shown in Fig. 1 . This geometry of the shelves 5 of the protrusions 3 contributes to the occurrence of additional turbulence of the mixture of solid particles inside the cavities 4 between the protrusions 3, which improves the quality of the particle separation process due to their additional mixing, due to the presence of periodic smooth changes in the width of the cavities 4, in which the mixture is mixed during operation of the device solid particles. This ensures increased efficiency of mixing the mixture of solid particles, and therefore their separation.

[0032] Additionally, an option is implemented in which the angle of inclination of the shelf 5 of at least one protrusion 3 differs from the angle of inclination of the part of the shelf 5 of at least one other protrusion 3. Changing the angle of inclination of the shelf 5 of the protrusion leads to a change in the thickness of the protrusion 3, in particular, a decrease in the angle of inclination leads to an increase in the thickness of the protrusion 3. Structurally, the protrusion 3 is divided into two parts: horizontal 6 and inclined 7. Making the protrusions 3 of this particular shape ensures an increase in the working life of the protrusions 3 compared to similar elements of the same shape by increasing their thickness, which prevents rapid abrasive wear of the mentioned bowl parts, and together with the ability to replace segments, significantly increases the service life of the bowl. In this case, the difference in the angles of inclination of parts of the shelves 5 can be selected in such a way that the volume of the cavities 4 does not change relative to the original geometry of the protrusions, as shown, for example, in Fig. 4 . In this case, the separation efficiency will not deteriorate. In this case, it is enough to thicken, that is, change the angle of part of the shelf 5, only one protrusion 3, for example, the lower one, which will already help to increase the service life of the device and the efficiency of separation, since in a given design the lower part bears more load during the separation process solid particles, including at the initial stage. Thus, uniform wear of the protrusions 3 is achieved depending on the impact exerted on them and increased separation efficiency. In a possible embodiment of the projections, the angles of inclination of the parts of the shelf 5 of each projection 3 are different from each other. This further increases the service life of the bowl due to the increase in the working life of each protrusion 3. Thus, it is possible to ensure the optimal thickness of an individual protrusion 3, taking into account the composition of solid particles, rotation speed, various impurities in the mixture, etc. For example, it is possible to gradually increase the angles of the parts of the upper shelves 5, in the central part there is a gradual decrease, and in the lower part the thickness increases again.

[0033] In addition to the implementation of the protrusions 3 presented above, it can be additionally organized to reduce the angles of inclination of the parts of the shelf 5 of the protrusion 3 from the upper protrusion to the lower one, thereby increasing the separation efficiency and ensuring an increase in service life by preventing rapid abrasive wear of parts, increasing from the upper protrusion to the bottom. The proposed implementation takes into account the operating principle of the concentration bowl, in which the main load from the mixture of solid particles during separation falls on the protrusions 3 located closer to the bottom of the bowl. This is due to the movement of particles of the supplied mixture under the influence of gravity. Consequently, making the lower protrusions 3 with a greater thickness relative to the upper ones is advisable and leads to an increase in the service life of the bowl. Efficiency is increased due to improved mixing of particles, due to their longer stay in the lower cavities 4 due to the longer life of the protrusions 3. An additional improvement in the technical result is ensured by ensuring that the angles of the inclination parts of the shelves 5 of each of the protrusions 3 are different, as shown in Fig. 4 , i.e. it is possible to realize a gradual increase in the resource of the protrusions 3 as the solid particles of the mixture move and, consequently, increase the wear of parts. In this case, the uniform thickening of the protrusions 3, caused by the mismatch of the angles, leads to their uniform wear, allowing the upper part of the bowl 1 to be replaced without excessive loss of material from the entire protrusions 3, thereby increasing maintainability and efficiency for the reasons described above.

[0034] Another particular version of the modular concentration bowl of a centrifugal concentrator is designed in such a way that the width of the shelf 5 of at least one protrusion 3 differs from the width of the shelf 5 of at least one other protrusion 3. An increase in the service life of the bowl and separation efficiency in this case is achieved by increasing the working life of the protrusions 3 compared to similar elements of the same shape by increasing the width of their shelves, which prevents rapid abrasive wear of the mentioned bowl parts, and together with the possibility of replacing segments, significantly increases the service life of the bowl. In this case, the widening of the protrusions 3 can be selected in such a way that the volume of the cavities 4 does not change relative to the original geometry of the protrusions shown in Fig. 5 . In this case, the separation efficiency will not deteriorate.

[0035] In a possible private embodiment of the projections 3, the width of the shelf 5 of each projection 3 increases from the upper to the lower projection. This further increases the service life of the bowl due to the increase in the working life of each protrusion 3. It is also possible to technically implement a bowl in which the width of the shelves 5 of each protrusion 3 increases from the upper to the lower protrusion, as shown in FIG. 5 , thereby ensuring increased separation efficiency and service life by preventing rapid abrasive wear of parts, increasing from the upper protrusion to the lower one. The proposed implementation takes into account the operating principle of the concentration bowl, in which the main load from the mixture of solid particles during separation falls on the protrusions 3 located closer to the bottom of the bowl. This is due to the movement of particles of the supplied mixture under the influence of gravity. Consequently, making the lower projections 3 with a larger width of the shelves relative to the upper ones is advisable and leads to an increase in the service life of the bowl. Efficiency is increased due to improved mixing of particles, due to their longer stay in the lower cavities 4 due to the longer life of the protrusions 3.

[0036] Increasing wear resistance, and therefore service life, can also be achieved by making at least one protrusion 3 from a wear-resistant material. The material can be any known elastic material, wear-resistant material, or a combination thereof. As an example of an elastic material when making the protrusion 3, polyurethane, silicone, polyethylene, thermoplastic elastomer, rubber, rubber and their derivatives, including polyurethane, silicone, polyethylene, thermoplastic elastomer, rubber or rubber, as well as any other similar known materials, can be used. as well as any combinations thereof. As the wear-resistant material, any known ceramics, aluminum oxide, zirconium oxide, titanium nitride, industrial diamond, composite materials, or any other similar material, or any combination thereof, can be used. Also, as a wear-resistant material when making the projections 3, materials containing metal carbides, for example, tungsten carbide, or non-metal carbides, for example, silicon carbide or any other known metal carbides or non-metal carbides, as well as any combination thereof, can be used. Also, high-chromium steels or high-manganese steels can be used as wear-resistant materials. In addition, an epoxy compound with a filler can be used as a wear-resistant material when making the projections 3, which can be used, for example, any known ceramics, aluminum oxide, zirconium oxide, titanium nitride, as well as metal and non-metal carbides, for example, silicon carbide or tungsten carbide, or technical diamond.

[0037] An additional increase in wear resistance can also be achieved by using an epoxy compound with a filler for the working surface 2, forming the protrusions 3 and the cavities 4. The filler can be, for example, any known ceramics, aluminum oxide, zirconium oxide, titanium nitride, as well as metal and non-metal carbides, such as silicon carbide or tungsten carbide, or industrial diamond. The mentioned materials provide an increase in the service life of the device due to their strength and other technical characteristics. Moreover, if the material of the working surface 2 is made elastic, the working surface can be made entirely of one elastic material. In addition, the material made elastic and used to form the cavities 4 and the material made elastic and used to form at least one protrusion 3 can be made different from each other.

[0038] In one of the technical implementations of the bowl, in order to increase the maintainability and service life of the device, at least one of the protrusions 3 can be replaced independently of the other protrusions. This can be realized, for example, by using the ribs of the internal frame, into which inserts are placed, securing the projections 3 to the working surface 2 using a threaded connection or by means of locking projections and grooves or otherwise. In this case, the inserts can be removed and the tabs removed and replaced.

[0039] Increasing the efficiency of mixing a mixture of solid particles, and therefore their separation, can be achieved by making the shelf 5 of the protrusions 3 of a complex configuration, for example, in the form of a sinusoidal shape, as shown in Fig. 1 . This form of shelves 5 is characterized by the presence of periodic smooth changes in the width of the cavities 4, in which during operation of the device the mixture of solid particles is mixed. This geometry of the shelves 5 of the projections 3 contributes to the occurrence of additional turbulence of the liquid with particles inside the cavities 4 between the projections 3, which improves the quality of the particle separation process.

[0040] In FIG. Figure 2 shows a block diagram of another embodiment of a modular concentration bowl of a centrifugal concentrator with a complex protrusion configuration. Another version of the modular concentration bowl of a centrifugal concentrator contains upper 1 and lower parts connected to each other, as well as a working surface 2 attached to them, while the upper part of the bowl 1 has an internal frame, the working surface 2 covers the inner surface of the upper part of the concentration bowl 1 with the formation of protrusions 3 and cavities 4 between the protrusions 3, wherein the shelf of at least one protrusion has a complex configuration, for example, in the form of a vertical protrusion 8, for example, in the shape of a tooth. This technical implementation also promotes additional mixing of particles, since the vertical protrusions 8 act as barriers to the free movement of particles within a given cavity 4, which leads to their forced mixing within the area of the cavity 4 limited by the vertical protrusion or vertical protrusions. This has a positive effect on particle separation due to additional turbulence of the mixture. Making even one vertical protrusion 8 on one of the cavities 4, located, for example, closer to the bottom of the bowl, helps to increase the efficiency of separation, since in a given design the lower part bears more load during the separation of solid particles, associated with their more dense placement at the bottom under the influence of gravity.

[0041] In FIG. Figure 3 shows a block diagram of another embodiment of a modular concentration bowl of a centrifugal concentrator. Another version of the modular concentration bowl of a centrifugal concentrator contains upper 1 and lower parts connected to each other, as well as a working surface 2 attached to them, while the upper part of the bowl 1 has an internal frame, the working surface 2 covers the inner surface of the upper part of the concentration bowl 1 to form projections 3 and cavities 4 between projections 3, wherein the cross-sectional area of at least one projection differs from the cross-sectional area of at least one other projection. Moreover, the angle of inclination of the part of the shelf of at least one protrusion differs from the angle of inclination of the part of the shelf of at least one other protrusion. The difference in cross-sectional area leads to a difference in the geometric shape of the protrusions 3. This makes it possible to take into account the uneven distribution of the load on the protrusions 3, associated with the operating principle of the concentration bowl and the method of feeding and separating the mixture of solid particles. Increasing the efficiency and service life of the bowl in this case can be achieved by changing the area of the protrusions 3 in cross section, in particular, by increasing the width of the shelf 5 and the thickness of at least one protrusion 3, which prevents rapid abrasive wear of the mentioned parts of the bowl and provides increased working life of the protrusions in comparison with similar elements of the same shape. The cross-sectional area mismatch of the protrusions 3 can also be implemented in the same way as shown in FIG. 4 and Fig. 5 , i.e. due to changes in the width of the shelves 5 and the thickness of the projections 3, described above. Increasing the efficiency of mixing a mixture of solid particles, and therefore their separation, can also be achieved by making at least one shelf 5 protrusions 3 of a sinusoidal shape, justified above.

[0042] In the presented best-of-breed implementation, the modular concentrating bowl of a centrifugal concentrator operates as follows. The starting material is fed into the concentration bowl. As a source material, gold-bearing sand from placer deposits, finely dispersed material from weathering crusts located in the oxidation zones of copper-molybdenum-porphyry deposits, fine sand, as well as material from copper-nickel ores can be used. In general, any mixture of solid particles having different densities can be used as a material. Then the modular concentration bowl is set in motion. At the same time, a fluidizing liquid is supplied to the concentration bowl through nozzles for injecting a fluidizing liquid located in the cavities 4 of the upper part 1 of the concentration bowl. In this case, any Newtonian liquid, for example, water, can be used as a fluidizing liquid. As a result, during the rotation of the concentration bowl under the action of centrifugal force, the source material is divided into components by density, with heavier solid particles accumulating in cavities 4. The fluidizing liquid supplied through the nozzles ensures the creation of a fluidized layer during operation of the centrifugal concentrator near the working surface 2 inside cavities 4, limited by shelves of complex configuration, for example, in the form of a sinusoidal shape or with vertical protrusions, which facilitates the process of separating the source material into components during gravitational separation and provides additional mixing of particles. Additional forced mixing is realized due to the presence of periodic smooth changes in the width of the cavities 4 or due to the presence of the formation of sections limited by vertical protrusions 8 in the cavities 4. Due to the movement of the mixture of solid particles in sections of the cavities 4 that are heterogeneous in geometric shape, they are forced to swirl, promoting separation by mass mixture particles. In this case, the main load on the concentration bowl falls on the protrusions 3 located closer to its bottom. Due to the implementation of the lower protrusions, which provide a greater working resource, in the form of a discrepancy between the angles of the inclination parts of the shelves 5 of the protrusions 3, which increases their thickness, for example, with an increase from the upper protrusions to the lower ones, or increasing the width of their shelves, or other discrepancy between the cross-sectional areas 3 protrusions, the wear resistance of the device increases. After separation, the rotation of the concentration bowl is stopped and heavy solid particles accumulated in cavities 4 are removed from the concentration bowl. Also, the remaining mass of waste material is removed separately from the concentration bowl.

[0043] Thus, the mentioned elements directly affect the technical result, which consists in increasing the service life of the concentration bowl, including due to its maintainability and separation efficiency.

[0044] These application materials provide a preferred disclosure of the implementation of the claimed technical solution, which should not be used as limiting other, private embodiments of its implementation that do not go beyond the scope of the requested scope of legal protection and are obvious to specialists in the relevant field of technology.

Claims (17)

1. Modular concentration bowl of a centrifugal concentrator, consisting of interconnected upper and lower parts, as well as a working surface attached to them, the upper part of the bowl has an internal frame, the working surface covers the inner surface of the upper part of the concentration bowl with the formation of protrusions and cavities between the protrusions, wherein the shelf of at least one protrusion has a configuration in which the thickness of the protrusion in the cross section changes, and the angle of inclination of the part of the shelf of at least one protrusion differs from the angle tilting part of the shelf of at least one other protrusion. 2. Modular concentration bowl of a centrifugal concentrator, consisting of interconnected upper and lower parts, as well as a working surface attached to them, the upper part of the bowl has an internal frame, the working surface covers the inner surface of the upper part of the concentration bowl with the formation of protrusions and cavities between the protrusions, wherein the cross-sectional area of at least one protrusion differs from the cross-sectional area of at least one other protrusion, and the angle of inclination of the part of the shelf of at least one the protrusion differs from the angle of inclination of the shelf part of at least one other protrusion. 3. Modular concentration bowl according to paragraphs. 1, 2, characterized in that the shelf of at least one protrusion is made of a sinusoidal shape. 4. Modular concentration bowl according to paragraphs. 1, 2, characterized in that the shelf has at least one vertical protrusion. 5. Modular concentration bowl according to paragraphs. 1, 2, characterized in that the angles of inclination of the parts of the shelves of each protrusion are different from each other. 6. Modular concentration bowl according to claim 5, characterized in that the angles of inclination of parts of the shelves of the protrusions decrease from the upper protrusion to the lower protrusion. 7. Modular concentration bowl according to paragraphs. 1, 2, characterized in that the width of the flange of at least one protrusion differs from the width of the flange of at least one other protrusion. 8. Modular concentration bowl according to claim 7, characterized in that the width of the shelves of each protrusion increases from the upper protrusion to the lower protrusion. 9. Modular concentration bowl according to paragraphs. 1, 2, characterized in that at least one protrusion is made of wear-resistant material. 10. Modular concentration bowl according to paragraphs. 1, 2, characterized in that the working surface forming the protrusions includes an epoxy compound with filler. 11. Modular concentration bowl according to paragraphs. 1, 2, characterized in that at least one protrusion of the upper part of the concentration bowl is designed to be independently replaceable. 12. Modular concentration bowl according to paragraphs. 1, 2, characterized in that the upper part and lower part of the concentration bowl are designed to be independently replaceable. 13. Modular concentration bowl according to paragraphs. 1, 2, characterized in that the upper part of the bowl is made of segments with the possibility of their independent replacement.