RU138664U1 - Spiral Classifier Lining - Google Patents

Abstract

1. The lining of the spiral classifier, containing pads made of elastomeric material fixed to the spiral by means of a detachable connection, characterized in that the pads are reinforced with wear-resistant elements made of a material with higher wear resistance than the material of the pads, and located in the area adjacent to the outer working surface each lining and to its outer edge in the radial direction from the axis of the spiral. 2. Lining according to claim 1, characterized in that the reinforcing wear-resistant elements are made in the form of basalt plates. The lining according to claim 1, characterized in that the reinforcing wear-resistant elements are made in the form of composite rods based on a polyurethane or epoxy binder reinforced with basalt or fiberglass, and oriented in the body of the linings in the radial and circumferential directions. Lining according to claim 1, characterized in that the reinforcing wear-resistant elements are made in the form of at least one layer of basalt fabric located in the outer layer of the linings and on their outer edge. The lining according to claim 1, characterized in that each pad is made of rubber. The lining according to claim 1, characterized in that the reinforcing wear-resistant elements are fixed in the lining by means of adhesive bonding or during the vulcanization of the lining. The lining according to claim 1, characterized in that each pad is mounted on a spiral by means of a bolted connection.

Description

The utility model relates to apparatuses intended for separation by size of the crushed material in the aquatic environment for the enrichment of non-ferrous and ferrous metals and other minerals, and can be used in mining plants of the mining industry.

The spiral classifier, as a rule, contains an inclined working chamber (trough), in which one or two drive shafts with tape spirals fixed to them, made along a helical line (spiral screws), are placed. Smaller particles of the separated material (ore) are separated together with water in the lower part of the trough, and larger ones, precipitated to the bottom; transported by spirals and unloaded in its upper part. Since the processed materials are for the most part abrasive, and often chemically aggressive, the main organ of the classifier is the spiral auger, in the process of work it is subjected to intensive wear, which reduces its life.

In engineering, it has long been known and widely used to protect auger apparatuses by welding or otherwise attaching a spiral of overlays made of highly alloyed wear-resistant steel to an abrasive wear [1]. This technique allows you to extend the life of the screw, but leads to a significant increase in the mass of the apparatus and its cost.

A spiral classifier is also known, the spiral of which is covered over its entire length by a lining made of elastomeric material in the form of overlays fixed to spirals reinforced with an inner cord layer [2].

The installation of a lining of elastomeric material also protects the spiral, while having significantly lower mass and cost, however, this lining also wears out and needs to be replaced periodically.

The closest analogue of the claimed utility model from among those known in the prior art is a lining of a spiral classifier, containing lining of an elastomeric material fixed to the spiral by detachable connection with inserts that strengthen them with a spiral and with a variable thickness along the height of each lining [3]. Inserts increase the strength and reliability of fastening linings to spirals, and increasing the thickness of linings in the zone of their most abrasive wear increases the life of the lining (reducing the frequency of its replacement), however, increasing the thickness of the lining cannot be large and this can not be achieved by significantly increasing the life of the lining .

The problem the utility model aims to solve is to increase the lining life, and the technical result that can be achieved by its implementation is to increase the wear resistance of the lining.

To solve this problem and achieve the indicated technical result in the lining of a spiral classifier containing linings of elastomeric material detachably mounted on spirals, it is proposed to reinforce the linings with wear-resistant elements with higher wear resistance than the wear resistance of the linings and arrange these reinforcing elements in each liner in the adjacent zone to the outer, working surface of the lining and its outer edge in the radial direction from the axis of the spiral.

The reinforcing elements can be made in the form of basalt plates fixed either on the outer surface of each lining in its peripheral part adjacent to the outer edge of the lining, or inside the lining parallel to its outer surface with the exit of one of the ends of the plate to the outer edge of the lining.

The reinforcing elements can also be made in the form of composite rods based on a polyurethane or epoxy binder reinforced with basalt or fiberglass, and oriented in the body of the lining in the radial and circumferential directions.

The reinforcing elements can also be made in the form of basalt fabric located in the outer layer of the linings.

Each pad can be made of rubber, and its reinforcing elements are fixed in it by means of adhesive bonding or during its vulcanization.

Pads can be mounted on spirals using bolted connections.

The wear of an overlay made of an elastomeric material, like a spiral blade, is uneven and depends on the speed of movement of its parts relative to the processed abrasive medium. First of all, it manifests itself on its front surface - located in front in the direction of rotation of the screw spiral and most of all manifests itself in the region of the outer edge (in the radial direction), because here the highest peripheral speed takes place. Therefore, the installation in these areas of reinforcing wear-resistant elements in the form of basalt plates, basalt-plastic rods and basalt fabric not only increases the strength characteristics of the plates, but also significantly reduces their abrasive wear, which allows to achieve a longer service life of the classifier, while retaining such positive factors, as a reduction in noise and vibration during the operation of the classifier, and the minimum time for dismantling and installation of the lining.

Examples of some possible implementations of the utility model are presented in the accompanying drawings.

In FIG. 1 schematically shows a longitudinal section of a spiral classifier.

In FIG. 2 shows a fragment I of a spiral with a lining reinforced with basalt plates.

In FIG. 3 is a cross section Α-A in FIG. 2.

In FIG. 4 shows another embodiment of reinforcing the lining with a basalt plate.

In FIG. 5 shows a variant with the installation of plates on both sides of the spiral reinforced with basalt-plastic rods and basalt fabric.

In FIG. 6 is a section BB in FIG. 5.

In FIG. 1 is a schematic diagram of a spiral classifier containing a spiral 3 mounted in a working chamber 1 on a shaft 2 with a drive for its rotation 4, and in FIG. 2 shows a fragment I of a spiral 3 with lining linings 5 fixed on it, made of an elastomeric material, for example, rubber with reinforcing elements of a material with higher wear resistance, located in the area of the front (working) surface 6 of each lining 5 or directly on it and near outer edge 7 of the lining 5.

In the embodiment of FIG. 2, 3 embodiment, the reinforcing elements are made in the form of plates 8 of basalt.

Each pad 5 is mounted on a spiral 3 by a detachable connection, for example, by a bolt 9.

In FIG. 4 shows the possible placement of a basalt plate 8 inside the lining 5 material near its front surface 6 with the exit of one of its ends to the outer edge 7. The basalt plates 8 can be obtained by stone casting.

In FIG. 5 and 6 show an embodiment of the lining 5 with reinforcing elements in the form of composite rods 10, each of which is based on a polyurethane or epoxy binder reinforced with basalt or fiberglass.

Reinforcing rods 10 are located in the area adjacent to the outer surface of the plates 5, and are oriented in the radial and circumferential directions. The rods 10 can be molded, for example, by pultrusion [4].

The same drawings show the installation of plates 5 on both sides of the spiral 3, as well as the implementation of the reinforcing elements in the form of basalt fabric 11, fixed in the outer layer and on the outer edge 7 of the plates 5.

The reinforcing elements 8, 10, 11 are fixed in the plates 5 by means of an adhesive joint or during the vulcanization of the plates 5.

The utility model can be implemented using well-known materials, using well-known technologies, using well-known equipment and can increase the life of the spiral classifier without replacing its lining.

Information sources:

[one]. RU, F.O. Spivakovsky, “Conveyor Installations”, part 4, ONTI, Kharkov, 1935, pp. 24-25.

[2]. RU, No. 2164173, B03B 5/52, 1999.

[3]. RU, No. 70158, B03B 5/52, 2007, (prototype)

[four]. RU, No. 2133670, B29C 55/30, 1996.

[5]. RU, No. 2285566, B03B 5/52, 2004.

[6]. RU, No. 1551550, B28C 5/12, 1988.

[7]. US No. 8235583, B01F 7/16, 2012

Claims (7)

1. The lining of the spiral classifier, containing pads made of elastomeric material fixed to the spiral by means of a detachable connection, characterized in that the pads are reinforced with wear-resistant elements made of a material with higher wear resistance than that of the pads, and located in the area adjacent to the outer working surface each lining and to its outer edge in the radial direction from the axis of the spiral. 2. The lining according to claim 1, characterized in that the reinforcing wear-resistant elements are made in the form of basalt plates. 3. Lining according to claim 1, characterized in that the reinforcing wear-resistant elements are made in the form of composite rods based on a polyurethane or epoxy binder reinforced with basalt or fiberglass and oriented in the body of the linings in the radial and circumferential directions. 4. Lining according to claim 1, characterized in that the reinforcing wear-resistant elements are made in the form of at least one layer of basalt fabric located in the outer layer of the linings and on their outer edge. 5. Lining according to claim 1, characterized in that each pad is made of rubber. 6. Lining according to claim 1, characterized in that the reinforcing wear-resistant elements are fixed in the lining by means of adhesive bonding or in the process of vulcanization of the lining. 7. The lining according to claim 1, characterized in that each pad is mounted on a spiral by means of a bolted connection.

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