RU207391U1 - Modular Concentration Bowl Centrifugal Concentrator - Google Patents

Abstract

The utility model relates to devices intended for the beneficiation of minerals and can be used to separate solid particles by density. The objective of the claimed utility model is to create a device for gravitational separation of ores with a long service life, maintainable and easy to operate. The technical result of the claimed utility model is to increase the service life of the centrifugal concentrator.

Description

Technology area

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

State of the art

Known technical solution disclosed in the patent for invention RU 2579160 C1 (IPC B03B 5/32, H02K 33/00, B04B 7/08, B04B 9/10; published 10.04.2016) "Centrifugal concentrator", which is a centrifugal concentrator of periodic actions. The known device contains a conical concentration bowl. The framework of the concentration bowl is monolithic and consists of a base and a side wall. The side wall of the frame contains a series of metal annular ribs of the frame. The working surface of the concentration bowl is formed by the inner surface of the concentration bowl and contains a number of annular protrusions formed by the annular ribs of the frame and the annular cavities located between them.

The known device has a number of disadvantages, namely, the fact that the frame of the concentration bowl is made monolithic, which excludes the possibility of replacing the upper and lower parts of the concentration bowl independently of each other. In addition, in the design of the working surface of the framework of the concentration bowl and the centrifugal concentrator as a whole, there are no wear-resistant elements, such as inserts made of wear-resistant material, which significantly reduces the service life of the concentration bowl. Also, the working surface of the concentration bowl is made of inelastic material, which significantly reduces the service life of the concentration bowl of the known device.

Known technical solution disclosed in patent application for invention WO 2019144179 A1 (IPC B04B 15/06, B04B 7/08, B04B 7/14; published 01.08.2019) "Bowl for a centrifugal concentrator of periodic action", which is a concentration bowl centrifugal concentrator. The known concentration bowl consists of vertical hollow segments, each of which consists of two vertical parts. In the structure of the segments, annular protrusions and annular cavities are made on the inner side, located between the annular protrusions. In the annular cavities, there are nozzles for injecting a fluidizing liquid. On the surface of at least one annular protrusion, at least one insert made of wear-resistant material is fixed. As one of the possible implementations of the known concentration bowl, inserts of wear-resistant material can be located inside the annular protrusions of the vertical segments of the concentration bowl.

The known invention has a number of significant disadvantages, namely, the lack of a known concentration bowl of a rigid frame with a side wall containing annular metal ribs. In addition, the inserts made of wear-resistant material are fixed on the surface of the annular protrusions of the segment, that is, on the working surface made of elastic material, which increases the risk of the insert separating from the working surface during the operation of the claimed invention due to abrasive wear of the working surface. If the inserts made of wear-resistant material are located inside the annular protrusions of the segment, the disadvantage is the lack of fastening of the insert base to the rigid frame, namely, to the annular metal rib of the frame. Accordingly, this type of construction does not provide reliable fastening of inserts made of wear-resistant material, and therefore does not provide an increase in the service life of the known invention.

As the closest analogue for the concentration bowl of a centrifugal concentrator, a well-known technical solution disclosed in the patent for invention US 7144360 B2 (IPC B04B 11/04; published 05.12.2006) "Centrifugal separator with a banded insert element installed in the bowl" was chosen, which represents is a batch-type centrifugal concentrator. The known device contains a conical concentration bowl. The 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 concentration bowl frame, in turn, contains metal annular ribs forming annular protrusions on the working surface of the concentration bowl, and annular cavities for collecting the products of the gravitational separation of the mixture. The annular metal frame ribs are attached to the modular side wall of the concentration bowl frame by fasteners forming an internal support structure. The annular metal fins are in turn covered with an elastic material forming a replaceable working surface. To the annular protrusions on the working surface formed by the annular metal ribs of the frame, inserts made of wear-resistant material are attached from the outside. The annular cavities located between the annular protrusions formed by the annular ribs of the frame on the working surface of the concentration bowl are equipped with nozzles for injecting a fluidizing liquid.

Also, inserts made of wear-resistant material within the framework of the implementation of the known invention can be fixed between the annular ribs of the frame in the annular cavities.

The known device works as follows. The mixture is fed into the cone-shaped concentration bowl by means of a feed device. The concentration bowl is then allowed to rotate. Then, the fluidizing liquid is fed through the nozzles, and the components of the mixture, which have a higher density, are collected in the annular cavities of the working surface, after which they are removed using the concentrate unloading device. Also, with the help of a tailings removal device, light fractions obtained as a result of the gravity separation process are removed.

The known technical solution has a number of significant disadvantages, which consist in the fact that inserts made of wear-resistant material are placed over the working surface of the concentration bowl and fixed on it with glue. This significantly reduces the service life of the concentration bowl, as there is no reliable attachment of the inserts made of wear-resistant material. Accordingly, during operation, the working surface is destroyed in the area of contact with inserts made of wear-resistant material and their subsequent separation from the working surface of the concentration bowl.

If the inserts of wear-resistant material are fixed between the annular ribs of the frame in the annular cavities, then the inserts of the wear-resistant material are designed to prevent abrasive wear of the annular cavities during the operation of the known device, and not the annular protrusions on the working surface. In turn, such a feature does not allow extending the service life of the known concentration bowl, since it is the annular protrusions of the working surface that are subject to maximum wear during operation.

Brief description of the utility model

The objective of the claimed utility model is to create a device for gravitational separation of ores with a long service life, maintainable and easy to operate.

The technical result of the claimed utility model is to increase the service life of the centrifugal concentrator.

The claimed technical result in relation to the elements of the device is achieved as follows.

A modular concentration bowl is proposed, consisting of interconnected upper 11 and lower 12 parts, as well as an elastic working surface attached to them. In this case, the upper 11 part of the bowl includes a frame with annular ribs. The working surface covers the inner surface of the upper part of the concentration bowl with the formation of annular protrusions in the region of annular ribs, and cavities between annular protrusions. At the same time, inserts made of wear-resistant material are fixed on the annular ribs of the upper part of the bowl. The inserts are seated using a solid filled epoxy compound to form the surface of the protrusion.

As part of the implementation of the claimed utility model, an insert made of wear-resistant material can be made of a solid annular shape in plan. At the same time, an insert made of wear-resistant material can be attached to the annular rib using a connecting layer.

An annular rib with an insert made of wear-resistant material can be additionally provided with a shell, and the insert made of wear-resistant material can be attached to the shell using a connecting layer.

The upper part 11 and the lower part 12 of the concentration bowl can be independently replaceable with respect to each other.

The annular cavities of the inventive modular concentration bowl can be equipped with nozzles.

The proposed modular concentrating bowl is reliable and has a long service life. Anchoring the inserts with a solid filled epoxy compound, complemented by a bonding layer and a shell, also provides additional device reliability and durability of the concentrating bowl.

Description of drawings

The essence of the utility model is illustrated by drawings, where FIG. 1 shows a schematic diagram of the upper part of the concentration bowl, the end surface 1 of the annular rib 2 of the frame 3 of which is equipped with an insert 4 made of wear-resistant material, fixed with an epoxy compound with a solid filler 6, side view. FIG. 2 shows the area A, illustrating the relative position of the annular protrusion 7, the end surface 1 of the annular rib 2 of the frame 3 and the insert 4 made of wear-resistant material, fixed with an epoxy compound with a solid-state filler 6, side view. Figure 3 shows the area A, illustrating the relative position of the annular protrusion 7, the end surface 1 of the annular rib 2 of the frame 3 and the insert 4 made of wear-resistant material, fixed with an epoxy compound with a solid filling 6 and a retaining shell 5, side view. Figure 4 shows a schematic diagram of the inventive centrifugal concentrator, side view.

The features of the utility model are disclosed in the following description and the accompanying images explaining the utility model. In addition, well-known elements of the utility model will not be described in detail or will be omitted so as not to overload the description of the present utility model in detail.

Detailed description of the utility model

The main component subject to maximum abrasion during the operation of a centrifugal concentrator is its concentration bowl. In the claimed utility model, the concentration bowl is modular. The concentrating bowl consists of two parts: the upper 11 part of the concentrating bowl and the lower 12 part of the concentrating bowl. In this case, the upper 11 part of the concentration bowl and the lower part of the concentration bowl are made with the possibility of replacement, independently of each other. This design of the concentration cone ensures the ease of use of the claimed utility model, and also increases the service life of the centrifugal concentrator, the functional element of which is the claimed modular concentration bowl.

The side wall of the framework 3 of the concentration bowl is made in such a way that the angle of inclination of the side wall of the framework 3 of the concentration bowl is from 0 ° to 90 ° inclusive to the horizontal surface. Thus, if the angle of inclination of the side wall of the framework 3 of the concentration bowl is not less than 15 °, but less than 90 ° to the horizontal surface, then in the longitudinal section the concentration bowl has essentially the shape of a truncated cone with its wide part facing upwards, which ensures the reliability and simplicity of the claimed device. Thus, in this case, the concentration bowl can be made in a conical shape.

If the angle of inclination of the side wall of the frame 3 of the concentration bowl is 90 °, then in the longitudinal section the concentration bowl has a substantially cylindrical shape. Thus, in this case, the concentration bowl can be made in a cylindrical shape, which ensures the reliability of the utility model.

The side wall of the frame 3 of the upper 11 part of the concentration bowl comprises annular ribs 2 of the frame 3 arranged horizontally, as shown in FIG. 1. The horizontal arrangement of the annular ribs 2 provides an increase in the service life of the centrifugal concentrator by preventing wear of the frame during separation.

If the angle of inclination of the side wall of the frame 3 of the concentration bowl is at least 15 °, but less than 90 ° to the horizontal surface, the annular ribs 2 of the frame 3 in the design of the claimed utility model can be made of different diameters and can be arranged in such a way that the diameter of the annular the ribs 2 of the frame 3, attached to the side wall of the frame 3 of the upper 11 part of the concentration bowl, can increase in the direction from bottom to top, with the formation of a conical shape of the inventive concentration bowl.

If the angle of inclination of the side wall of the frame 3 of the concentration bowl is 90 °, the annular ribs 2 of the frame 3 in the design of the claimed utility model can be made of the same diameter.

Any known high-strength metal, for example, steel of the corresponding grades, composite material with a suitable set of properties or polymers with a suitable set of properties, which is necessary to ensure the reliability of the claimed device, increase its service life ... The annular ribs 2 of the frame 3 can be attached to the side wall of the frame 3 in any known manner. As an example, the annular ribs 2 of the frame 3 can be attached to the side wall of the frame 3 by means of a screw connection, welded connection, glued to the side wall of the frame 3, soldered to the side wall of the frame 3, or connected to it according to the “tongue-and-groove” principle with using appropriate additional fasteners (not shown in the drawings). Also, the annular ribs 2 of the frame 3 and the frame 3 can be made in the form of a single structural element, that is, the annular ribs 2 are made monolithic with the frame 3.

Each annular rib 2 of the frame 3 on the side of the free volume inside the inventive concentration bowl forms an annular protrusion 7 on the working surface, as shown in FIG. 1. When connecting several annular ribs 2 of the frame 3 with the formation of the side wall of the frame 3 of the upper 11 part of the concentration bowl, between the annular protrusions 7 formed on the working surface by the annular ribs 2 of the frame 3, there are annular cavities 8, which ensures the reliability of the claimed device. In the design of the claimed utility model, the annular ribs 2 of the frame 3 can be made wedge-shaped or rectangular in cross-section. In turn, the angle of inclination of the side faces of the annular ribs 2 of the frame 3 can range from 0 ° to 45 °. In turn, the annular cavities 8 located between the annular protrusions 7 can have a V-shape in cross-section, as shown in FIG. 1. Also, the annular cavities 8 located between the annular protrusions 7 can have a trapezoidal or U-shaped cross-section. In addition, the annular cavities 8 are equipped with nozzles (not shown in the drawings) for injecting a fluidizing liquid. The described design options for the annular cavities 8 within the implementation of the claimed utility model ensure its reliability.

In the claimed utility model, on the end surface 1 of the annular rib 2 of the frame 3 from the side of the free volume inside the inventive concentration bowl, an insert 4 made of wear-resistant material is fixed, as shown in FIG. 1-3. This makes it possible to increase the service life of the claimed utility model by increasing the service life of the annular protrusions 7 of the concentration bowl, as well as to ensure the reliability of the claimed utility model. In this case, the fixation of the inserts 4 is carried out by means of an epoxy compound with a solid filler 6, which forms the surface of the annular protrusion 5. As part of the implementation of the claimed utility model, in the cross section of the insert 4 made of wear-resistant material can be made wedge-shaped. In turn, the angle of inclination of the side faces of the inserts 4 made of wear-resistant material can be from 0 ° to 45 °. In addition, the inserts 4 made of wear-resistant material can be rectangular in cross-section.

As part of the implementation of the claimed utility model, inserts 4 made of wear-resistant material can be implemented in any shape in terms of plan. As an example, the inserts 4 made of wear-resistant material can be made in the form of a monolithic ring. Thus, in this embodiment, the inserts 4 made of wear-resistant material can be made annular in longitudinal section. This embodiment of inserts 4 made of wear-resistant material within the implementation of the claimed utility model ensures the reliability of the claimed utility model and increases its service life.

As another example of the implementation of the claimed utility model, the inserts 4 made of wear-resistant material can be made in the form of a set of elements of inserts 4 made of wear-resistant material of various shapes in plan. In this case, the inserts 4 made of wear-resistant material can be made in the form of a set of elements of inserts 4 made of wear-resistant material of rectangular shape in plan, and hence in longitudinal section. Also, the inserts 4 made of wear-resistant material can be made in the form of a set of elements of inserts 4 made of wear-resistant material of a segmented shape in the plan, and therefore in the longitudinal section. Also, as an example, inserts 4 made of wear-resistant material can be made in the form of a set of insert elements 4 made of wear-resistant material of polygonal shape in plan, and hence in longitudinal section. Moreover, each set of elements of inserts 4 made of wear-resistant material can contain from two or more elements of inserts 4 made of wear-resistant material, which makes it easy to replace elements of inserts 4 made of wear-resistant material, worn out during operation, and therefore, to increase the service life of the claimed utility model and reliability of the device. The described options for the implementation of inserts 4 made of wear-resistant material, having any of the listed forms in the plan, provide an increase in the service life of the claimed utility model, the reliability of the device.

In the case of inserts 4 made of wear-resistant material in the form of a set of elements of inserts 4 made of wear-resistant material of polygonal or segmental shape in plan, the elements of inserts 4 made of wear-resistant material can be fixed on the end surface 1 of the annular ribs 2 of the frame 3 or on the retaining shell 5 from the base side 9 inserts 4 made of wear-resistant material with the formation of a gap between two adjacent elements of inserts 4 made of wear-resistant material, which ensures the reliability of the claimed utility model, increasing its service life.

As an example, the insert members 4 of wear-resistant material can be attached to the end surface 1 of the annular ribs 2 of the frame 3 on the side of the base 9 of the insert 4 using a solid-filled epoxy compound 6, as shown in FIG. 2. Figure 3 also shows the use of an epoxy compound with a solid-state filler 6 for attaching the inserts 4 to the end surface 1 of the annular ribs 2 of the frame 3 using the retaining shell 5. In this case, aluminum ceramics, zirconium ceramics, can be used as a solid-state filler, silicon carbide, metal carbides (e.g. tungsten carbide), etc. This method of fixing the insert 4 ensures a long service life and its reliability.

Any material resistant to abrasion can be used as a wear-resistant material for making inserts 4. In this case, it is desirable to use materials that are resistant to abrasion, with a relatively low density. As an example of such a material, any known ceramic, aluminum oxide, zirconium oxide, titanium nitride, industrial diamond, composite materials, or any other similar material can be used. Also, 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, can be used as a wear-resistant material for making the inserts 4. Also, high-chromium steels or high-manganese steels can be used as wear-resistant material for making inserts 4. The choice of the listed materials as a wear-resistant material when making inserts 4 of wear-resistant material provide an increase in the service life of the centrifugal concentrator and the reliability of the proposed device.

The inserts 4 made of wear-resistant material can be fixed on the annular ribs 2 of the frame 3 in any known manner. As an example, the inserts 4 made of wear-resistant material can be attached to the end surface 1 of the annular ribs 2 of the frame 3 by means of a screw connection, can be attached by spraying ceramic to the end surface 1 of the annular ribs 2 of the frame 3, or attached in any other known manner. In this case, the inserts 4 made of wear-resistant material are fixed on the annular ribs 2 of the frame 3 from the side of the base 9 of each insert 7 made of wear-resistant material, which ensures reliable fastening of the inserts 4 made of wear-resistant material on the end surface 1 of the annular ribs 2 of the frame 3, and, accordingly, makes it possible to increase the service life of the claimed utility model and ensure its reliability.

As part of the implementation of the claimed utility model, the insert 4 made of wear-resistant material can be attached to the end surface 1 of the annular rib 2 of the frame 3 as follows. To improve the fixation of the insert 4 made of wear-resistant material, the end surface 1 of the annular rib 2 of the frame 3 can be additionally provided with a retaining shell 5, as shown in FIG. 1 and 3. In turn, the inner surface of the holding shell 5 may be provided with a tie layer 10 for attaching an insert 4 of wear-resistant material to the surface of the holding shell 5, as shown in FIG. 1. A layer of any joint material can be used as the connecting layer 10, including an epoxy compound 6 which can be used later to form the surfaces of the projection 7. As an example of such a connecting layer 10, a layer of glue or a layer of solder can be used, and also a layer of polyurethane, silicone, polyethylene, thermoplastic elastomer, rubber and their derivatives or any other similar known materials. Each holding shell 5 can be fixed to the end surface 1 of the annular rib 2 of the frame 3 in any known manner. As an example, each retaining shell 5 can be fixed to the end surface 1 of the annular rib 2 of the frame 3 by means of a welded joint, screw connection, glue, soldered or attached in any other known manner. The supply of the end surface 1 of the annular rib 2 of the frame 3 with the retaining shell 5 ensures reliable fastening of each insert 4 made of wear-resistant material on the end surface 1 of the annular rib 2 of the frame 3, and, accordingly, makes it possible to increase the service life of the claimed utility model and ensure its reliability. At the same time, supplying the inner surface of the retaining shell 5 with a connecting layer 10 also ensures the reliability of the claimed device and increases its service life.

In turn, in order to improve the fixation of the inserts 4 made of wear-resistant material, the holding shells 5 can be made U-shaped in cross-section. This cross-sectional shape of the retaining shells 5 ensures reliable attachment of the inserts 4 made of wear-resistant material to the retaining shell 5, and, accordingly, increases the service life of the claimed utility model and its reliability.

In one of the possible embodiments of the claimed utility model, the insert 4 made of wear-resistant material is fixed on the end surface 1 of the annular rib 2 of the frame 3, closest to the border of the lower 12 part of the concentration bowl, as shown in FIG. 1. This variant of the design of the claimed utility model can significantly increase the service life of the claimed utility model and its reliability, since it is in this area that the greatest abrasive wear of the concentration bowl occurs.

As one of the possible options for the implementation of the modular concentration bowl, inserts 4 made of wear-resistant material can be fixed on the end surfaces 1 of all the annular ribs 2 of the frame 3. This design option of the claimed utility model can significantly increase its service life, as well as the reliability of the claimed device.

The inner surface of the upper 11 part of the inventive concentration bowl is covered with an elastic material to form the working surface of the concentration bowl. In turn, the angle of inclination of the working surface made of elastic material is from 15 ° to 90 ° to the horizontal surface. In this case, the working surface is made in such a way that the insert 4 made of wear-resistant material is additionally fixed with epoxy compound 6 with a solid-state filler on both sides. This arrangement of inserts 4 made of wear-resistant material leads to additional fixation of inserts 4 made of wear-resistant material. This design makes it possible to significantly increase the service life of the modular concentrating bowl and its reliability due to the reliable fixation of inserts 4 made of wear-resistant material.

As an example, one insert 4 made of wear-resistant material can be fixed with an epoxy compound 6 with a solid-state filler by fixing two side edges of the inserts 4 made of wear-resistant material. This design makes it possible to significantly increase the service life of the modular concentrating bowl and its reliability due to the reliable fixation of inserts 4 made of wear-resistant material.

In addition, as part of the implementation of the claimed utility model, the entire surface of the inserts 4 made of wear-resistant material can be coated with an epoxy compound 6 with a solid filler. Thus, the insert 4 made of wear-resistant material can be additionally fixed on three sides in cross-section using a solid-filled epoxy compound 6, as shown in FIG. 3. This design also makes it possible to significantly increase the service life of the modular concentration bowl and its reliability due to the reliable fixation of inserts 4 made of wear-resistant material.

In addition, part of the surface of the inserts 4 made of wear-resistant material can be located above the level of the working surface. As an example, the surface of the insert 4 made of wear-resistant material and facing towards the free volume of the inventive concentration bowl can be made protruding from the level of the working surface. Such a constructive solution provides an increase in the service life of the inventive concentration bowl and its reliability.

In addition, in the body of the working surface in the region of the annular cavities 8, nozzles of nozzles (not shown in the drawings) for injecting a fluidizing liquid are also located. As part of the implementation of the claimed utility model, the nozzles (not shown in the drawings) for injection of the fluidizing liquid can be made in the form of round holes, which ensures the reliability of the claimed device.

Any known elastic material can be used as an elastic material for making the working surface of the concentration bowl. As an example of such a material, there can be used polyurethane, silicone, polyethylene, thermoplastic elastomer, rubber and their derivatives, as well as any other similar known materials. This choice of elastic material for making the working surface of the concentration bowl within the implementation of the claimed utility model provides an increase in the service life of the centrifugal concentrator, the reliability of the claimed device.

Thus, the inventive concentration bowl has an internal frame, which makes it easy to replace the upper 11 part and the lower 12 part of the concentration bowl independently from each other, as well as from other elements of the centrifugal concentrator, which significantly increases the ease of use of the claimed utility model.

The inner surface of the lower 12 part of the concentration bowl is also covered with an elastic material to form a working surface, which ensures the reliability of the claimed utility model and an increase in its service life.

The inventive modular concentration bowl, consisting of an upper 11 part and a lower 12 part, is located in a centrifugal concentrator. In this case, the upper 11 part of the concentration bowl and the lower 12 part of the concentration bowl are made with the possibility of replacement, independently of each other, which ensures the reliability of the claimed utility model, an increase in its service life.

Claims (10)

1. Modular concentration bowl, consisting of an interconnected upper and lower parts, as well as an attached working surface made of elastic material, while the upper part of the bowl includes a frame with annular ribs, the working surface covers the inner surface of the upper part of the concentration bowl with the formation of protrusions in the area of annular ribs, and cavities between the protrusions, at the same time, inserts made of wear-resistant material using an epoxy compound with a solid-state filler are fixed on the annular ribs of the upper part of the bowl. 2. The modular concentration bowl according to claim 1, characterized in that the inserts of wear-resistant material are made of annular shape in plan. 3. The modular concentrating bowl of claim 1, wherein the wear resistant material inserts are attached to the annular rib by a tie layer. 4. Modular concentration bowl according to claim 1, characterized in that the annular ribs with an insert made of wear-resistant material are additionally provided with a shell. 5. The modular concentrating bowl of claim 4, wherein the inserts of wear-resistant material are attached to the shell with a tie layer. 6. Modular concentration bowl according to claim 1, characterized in that the inserts of wear-resistant material are made protruding from the level of the working surface. 7. Modular concentration bowl according to claim 1, characterized in that the annular cavities are provided with nozzles.

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