RU8687U1 - BUCKET ELEVATOR EXECUTIVE BODY - Google Patents

Abstract

1. The executive body of the bucket elevator, including two traction plate-bush chains containing chain plates, axles and bushings, and buckets installed between the chains, characterized in that each bucket is equipped with pulling and supporting eyes, pivotally mounted on the axles. 2. The body according to claim 1, characterized in that the opposite bushings of the chains are planted on a single axis. 3. The body according to claim 1, characterized in that the holes of the supporting eyes exceed the diameter of the axis by the total value of the error of the step of the chain plates and the tolerance on the center distance between the hinges of the pulling and supporting eyes. The body according to claim 1, characterized in that the bushings with the plates of the chains are connected by interference fit. The body according to claims 1, 2 and 4, characterized in that rollers are mounted on the bushings of the chains.

Description

BUCKET ELEVATOR EXECUTIVE BODY

The utility model relates to material handling machines and can be used in the coal industry, metal industry, building materials industry, etc.

Bucket elevators are known, where the traction (executive) element is a tape or chain (one or two). Chains are most often used plate-sleeve, sleeve-roller and sleeve-roller. Buckets in such executive bodies are attached to chains using angles or shaped links on bolts or rivets (Bucket, shelf and cradle elevators. - A.O. Spivakovsky, V.K. Dyachkov Transport | 1 steering machines, M., Mechanical Engineering, 1968 ., p. 343-344).

The disadvantage of such elevators is their low durability and frequent repair work due to the destruction of welds in the design of the elevator body. ; d:

The closest to the proposed technical Ш й ен й ю is the executive body of the dewatering elevators of the EOS type. The executive body (see the prototype diagram) of such elevators consists of two traction plate-sleeve chains, plates 7 of which are rigidly connected by welding to the side walls 1 of the bucket located between the branches of the chains. Each segment of the executive body consists of four buckets, equipped with only one common axis 5, connecting in pairs the opposite bushings of the chain joints. At the ends of the hinge axes there are stops 6 interacting with retaining plates 8 welded to the outer plates of the chains 3. The bushings of 9 chains are fixed against rotation by the prismatic chains

MKI 6 in 65 G 17/16 17/56

connection with two faces 10 without interference (Elevators dewatering type EOS-damn. EOS B12.01.OOOSB, Karaganda, machine-building plant named after Parkhomenko, 1983) - prototype.

Such an executive body of a bucket elevator is used at high productivity, a significant lifting height, for transporting heavy lumpy materials.

However, it has a low durability due to the destruction of the welds of the buckets to the plates of the chains and the welds of the ladles themselves, as well as the breaking and rupture of the plates of the chains in the area of their prismatic connection with the bushings. In addition, there is wear on the elevator rails and the side fans of the chain plates, which are supported by the rails:

- during operation, the hinges of the chains wear. elevator drive sprockets and non-uniform extraction of chains, which leads to mutual cyclic displacement of the plates opposite) chains with tough || “buckets pinned to them. The error of the pitch of the chain links (the pitch of the chain plates) also has a large offset value. As a result of this, buckets and welded joints undergo cyclic deformation of both the buckets themselves and UleeV S fastening the buckets to the chain plates;

-connection of the chain bushings with the chain plates with M prismatic hinges with two flats without interference leads to mutual displacement of the bushes relative to the chain plates within the guaranteed gap of the prismatic joint when the chains pass through the drive sprocket of the bucket elevator. This causes the prismatic joint (attachment) to break and leads to wedging of the hole of the chain plate by the sleeve, resulting in the chain breaking; chains and also increases the load on the elevator drive.

The task to which the utility model is directed. zakl: - lies in creating a reliable bucket elevator.

The technical result that can be achieved by using this utility model will increase the durability of the bucket elevator executive body.

The technical result is achieved by the fact that in the executive body of the bucket elevator, which includes two traction plate-sleeve chains consisting of chain plates, axles and bushings, and buckets installed between the chain branches, the latter are equipped with pairs of pulling and supporting eyes, pivotally mounted on the axles of the chains.

Moreover, to increase the manufacturability of the design, all opposite hinge axes are made uniform.

The holes of the supporting eyes are made large (pretending) the total value of the error of the step of the plates of the chains and the tolerance on the center distance between the hinges of the pulling and supporting eyes. Bushings with chain plates are connected by interference fit.

5 To avoid friction of the chain plates on the bushings of the chain elevator, the chain bushings are equipped with rollers.

The essence of the utility model lies in the constructive implementation of the places of attachment of buckets to the plates of the chains of the executive body of the bucket elevator.

The supply of buckets with pulling and supporting pairs of eyes pivotally attached to the axles of the chains provides the most favorable power scheme for loading the buckets only with a useful joint on the weight of the transported cargo, allows them to self-mount along the axis on which the pulling eyes of the bucket are fixed and completely eliminates the additional loading of the welds of the ladles with mutual offset plate chains. In addition, it compensates for the rapidity of the step of the plates (links) of the chains and does not require

3.

high precision manufacturing of buckets. As a result of the foregoing, the durability of the executive body of the bucket elevator increases.

The holes of the supporting eyes are larger than the diameter of the hinge axis by the sum of the error of the pitch of the chain links (DT) and the tolerance on the center-to-center distances between the hinges of the pulling and supporting eyes (L A) reduces the load on them due to the free self-installation of buckets relative to the axis of the hinges, thereby to increase the durability of the executive body in general

The connection of the opposite (opposite) bushings of the chains in a single axis ensures a stable position of the buckets between the branches of the chains. The cyclic displacement of the plates of the opposite chains during the operation of the actuator causes elastic bending of the axes and does not lead to their destruction, which also further increases the durability of the elevator actuator. :

The connection of the sleeve with the chain plates due to the interference fit provides reliable fixation of the position of the sleeve relative to the chain plates when they pass through the drive, elevator sprocket, blocks the effort trying to turn the sleeve relative to the chain plates. This leads to a decrease in wear (breaking) of the joints of the executive body. And the round holes of such a connection can reduce the error of the step of the plates (links) of the chains, which, when they are paired in the actuator, also increases its durability.

The presence of rollers on the bushings of the chains reduces the wear of the elevator rails, chain plates, the load on the elevator drive by reducing the friction force of the actuator on the elevator rails.

The utility model is illustrated by drawings, where:

in FIG. 1 shows an executive bucket

elevator in longitudinal section;

in FIG. 2 - the same salue, view A from FIG. one;

cha fig, 3 - top view of KOBLia;

in FIG. 4 - section b - b of FIG. one;

in FIG. 5 - connection of the sleeve with the chain plate.

The Executive body of the bucket elevator contains two traction plate-sleeve chains 1 and buckets installed between them 6. The plate-sleeve chains 1 consist of external 2 and internal 3 plates and a hinge formed by an axis 4 and a sleeve 5. Each of the buckets is equipped with a pair of pulling 7 and a pair of supporting 8 eyes with holes a and b, respectively. Moreover, the hole b for the cylindrical hinge (to hell, not shown) in the supporting eyes 8 is made larger than the diameter of the axis 4 by a value c exceeding the sum of the error of the step of the plates (links) of the chain (DT) and the tolerance for the center distance between the hinges of the pulling and supporting eyes (YES), i.e. about LT + YES (Fig. 3, 4), where

T is the nominal step size of the chain plates;

A is the nominal distance between the holes of the pulling and supporting eyes;

(T ± AT) - chain plate pitch;

(A ± YES) is the distance between the holes of a pulling and b supporting eyes.

Rollers 9 are mounted on bushes 5, and stops 10 are welded at the ends of axles 4, which define the transverse dimension of the actuator. The stops 10 relative to the outer plates 2 of the chain are rigidly fixed by the locking strips 11 (Fig. 4).

The utility model is as follows.

The actuator is driven by a bucket elevator drive (to hell, not shown). Rotating, the drive sprocket of the drive interacts with its faces with the plates 2, 3 of chain 1. Pulling

the force from these plates is transmitted to the subsequent ones through the axles 4 and bushings 5. Both branches of the chains 1 synchronously come in translational motion relative to the elevator guides (to hell, not shown) The actuator is moved along the guides using rollers 9 rotating relative to the bushings 5.

The axis 4 act on the cylindrical holes of the pulling eyes 7 (Fig. 3) and drive the buckets 6.

On the other hand, buckets 6 are fixed from tipping over the chains 1 due to the interaction of the holes 6 of the supporting eyes 8 with the axles 4. The cylindrical hinges of the supporting eyes are mounted on the axles 4 with a clearance of c. This is ensured by the fact that the hole b supporting pro11 in 8 is made obviously larger than the sum of A T and YES.

Powered by the circuit 1 feed buckets 6 to the boot window of the elevator with coal. Buckets 6 so filled in this way move simultaneously with the traction plate-sleeve chains 1 to the discharge window of the elevator. The load from the weight of the load In the buckets 6 through the lifting eyes 7 and bushings 5 is transmitted on the axis 4 and, due to the clearance from the buckets, freely self-install on the axles 4. When the outer 2 and inner 3 plates of chains 1 pass through the drive elevator asterisk, they rotate, and rotation of the axles 4 and the buckets 6 relative to this drive sprocket, which leads to the mutual rotation of the bushings 5 relative to the axes 4. The resulting frictional moment between the axles 4 and the bushings 5, tending to rotate the latter relative to the internal plates 3 interacting with them 1 it is blocked due to their mutual interference fit. The rotation of the axes 4 relative to the outer plates 2 is blocked due to the interaction of the stops 10 and the locking bars 11, rigidly fixed to the plates 2. As a result, the wear of the joints of the actuator is reduced. As each of the buckets rotates around the drive sprocket of the elevator, self-pouring of the load (coal; into the unloading window of the elevator occurs.

In the case of the use of the executive body for dewatering the transported material in the buckets 6, through holes 12 are made through which water flows out during the lifting of the buckets. For better dewatering of the material, the buckets are equipped with drainage

sheets 13, which exclude sprinkling on lower located buckets.

Claims (5)

1. The executive body of the bucket elevator, including two traction plate-sleeve chains containing plate chains, axles and bushings, and buckets installed between the chains, characterized in that each of the buckets is equipped with pulling and supporting eyes that are pivotally mounted on the axles.  2. The body according to claim 1, characterized in that the opposite bushings of the chains are planted on a single axis.  3. The body according to claim 1, characterized in that the holes of the supporting eyes exceed the diameter of the axis by the total value of the error of the pitch of the chain plates and the tolerance on the center distance between the hinges of the pulling and supporting eyes.  4. The body according to claim 1, characterized in that the bushings with the plates of the chains are connected by interference fit. 5. The body according to claims 1, 2 and 4, characterized in that rollers are mounted on the bushings of the chains.