CN210883567U - Prevent mining vibration ore drawing machine of fluorite of jam - Google Patents

Abstract

The utility model relates to a vibration ore drawing machine technical field, in particular to a prevent blockking up fluorite mining vibration ore drawing machine, which solves the problem that the ore drawing machine still can block up after blanking because of excessive ore is drawn down in the prior art, comprising a machine body, a support and a vibration motor, wherein the support is welded at the bottom of the machine body, the upper end of the machine body is provided with a blanking hole, and the bottom wall of the machine body is provided with a plurality of groups of vibration seats driven by the vibration motor, the two sides of the inner part of the machine body are respectively provided with a first baffle and a second baffle through a fixed shaft, the side wall of the machine body is respectively provided with a first chute and a second chute, the inner parts of the first chute and the second chute are respectively provided with a first slide seat and a second slide seat in a sliding way, compared with the prior art, the utility model utilizes the interval type operation of the two groups of baffles to draw down the ore, thereby relieving the blockage condition of ore transfer.

Description

Prevent mining vibration ore drawing machine of fluorite of jam

Technical Field

The utility model relates to a vibration ore drawing machine technical field especially relates to a prevent mining vibration ore drawing machine of fluorite of jam.

Background

The ore is put down through the dead weight of the ore chute, which is a common ore conveying mode in mines, and the ore in the middle section of the upper part is put down to the middle section of the lower part by the dead weight, so that the ore conveying device has the advantages of safety, reliability, energy conservation and low operating cost. However, when the ore which is easy to agglomerate is placed downwards in the ore pass, the ore pass is often blocked, production is affected, and the phenomenon is more obvious particularly when the ore pass is used for a long distance with a small section.

In order to avoid such situations, the prior art also adopts the vibration ore drawing machine to operate, but if the downward ore is too much, the situation of blockage is still caused after the material discharging of the vibration ore drawing machine, so that a blockage-preventing vibration ore drawing machine is needed to solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that the ore still can block up after leading to the ore drawing machine unloading because of transferring the ore too much among the prior art, and the mining vibration ore drawing machine of fluorite who prevents blockking up who provides.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the anti-blocking fluorite mining vibration ore drawing machine comprises a machine body, a support and a vibration motor, wherein the support is welded at the bottom of the machine body, a feed opening is formed in the upper end of the machine body, and a plurality of groups of vibration seats driven by the vibration motor are installed on the bottom wall of the machine body;

the inside both sides of organism are provided with first baffle and second baffle respectively through the fixed axle to first spout and second spout have been seted up respectively to the lateral wall of organism, and the inside of first spout and second spout slides respectively and is provided with first slide and second slide, between first slide and the first baffle, all be connected fixedly through the gangbar between second slide and the second baffle, and one side of first slide is connected with first cylinder, and one side of second slide is connected with the second cylinder.

Preferably, the vibration motor is fixedly installed at the bottom of the vibration seat through a bolt, and the vibration seat and the bottom wall of the machine body are also fixed through a bolt.

Preferably, the first cylinder and the second cylinder are both fixed on one side of the side wall of the machine body through bolts.

Preferably, the first cylinder is fixed to a side wall of the first slide by welding, and the second cylinder is fixed to a side wall of the second slide by welding.

Preferably, the first sliding seat and the second sliding seat are both in a T-shaped structure, the convex end of the first sliding seat is arranged in the first sliding groove, and the convex end of the second sliding seat is arranged in the second sliding groove.

Compared with the prior art, the utility model discloses an at the inside two sets of baffles that set up of organism of ore drawing machine, utilize the spaced operation of two sets of baffles, come to transfer the ore of transferring in batches to this avoids too much ore unloading simultaneously, thereby alleviates the jam condition of transferring the ore.

Drawings

Fig. 1 is a schematic structural diagram of an anti-clogging fluorite mining vibration ore drawing machine provided by the utility model;

fig. 2 is the utility model provides a prevent local A schematic structure of mining vibration ore drawing machine of fluorite of jam.

In the figure: the device comprises a machine body 1, a feed opening 11, a support 2, a vibration seat 3, a vibration motor 31, a first baffle 4, a first cylinder 41, a first sliding groove 42, a first sliding seat 43, a second baffle 5, a second cylinder 51, a second sliding groove 52, a second sliding seat 53 and a linkage rod 6.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-2, an anti-clogging fluorite mining vibration ore drawing machine comprises a machine body 1, a support 2 and a vibration motor 31, wherein the support 2 is welded at the bottom of the machine body 1, a feed opening 11 is formed in the upper end of the machine body 1, a plurality of groups of vibration seats 3 driven by the vibration motor 31 are installed on the bottom wall of the machine body 1, the vibration seats 3 are used for driving the machine body 1 to vibrate to assist in ore lowering, the vibration motor 31 is fixedly installed at the bottom of the vibration seats 3 through bolts, the vibration seats 3 provide power for the vibration seats 3, the vibration seats 3 and the bottom wall of the machine body 1 are also fixedly connected through bolts, a first baffle 4 and a second baffle 5 are respectively arranged on two sides of the interior of the machine body 1 through fixed shafts, the first baffle 4 and the second baffle 5 are used for controlling ore falling, a first sliding chute 42 and a second sliding chute 52 are respectively formed in the side wall of the machine body 1, the first sliding, the second sliding chute 52 is used for facilitating the sliding of the second sliding seat 53, the first sliding seat 43 and the second sliding seat 53 are respectively arranged in the first sliding chute 42 and the second sliding chute 52 in a sliding manner, the first sliding seat 43 is used for driving the first baffle 4 to rotate and adjust through the linkage rod 6, the second sliding seat 53 is used for driving the second baffle 5 to rotate and adjust through the linkage rod 6, the first sliding seat 43 and the first baffle 4 and the second sliding seat 53 and the second baffle 5 are fixedly connected through the linkage rod 6, one side of the first sliding seat 43 is connected with the first air cylinder 41, the first air cylinder 41 is used for pushing the first sliding seat 43 to move, one side of the second sliding seat 53 is connected with the second air cylinder 51, and the second air cylinder 51 is used for pushing the second sliding seat 53 to move.

The first cylinder 41 and the second cylinder 51 are fixed on one side of the side wall of the machine body 1 through bolts, the first cylinder 41 and the side wall of the first slide seat 43 are fixed through welding, the second cylinder 51 and the side wall of the second slide seat 53 are also fixed through welding, the first slide seat 43 and the second slide seat 53 are both in a T-shaped structure, the convex end of the first slide seat 43 is arranged in the first slide groove 42, and the convex end of the second slide seat 53 is arranged in the second slide groove 52.

In this embodiment, ore falls into the machine body 1 from the feed opening 11 and slides along the inner wall of the machine body 1, at the same time, the first cylinder 41 is started to pull the first slide carriage 43 to a position close to the first slide carriage 43 along the first chute 42, so that the first slide carriage 43 pulls the first baffle 4 to rotate through the linkage rod 6 (i.e. the bottom of the first baffle 4 rotates to the upper right), the ore falls, after 5 seconds, the first cylinder 41 resets to push the first slide carriage 43 along the first chute 42 in a direction away from the first slide carriage 43, so that the first slide carriage 43 drives the first baffle 4 to reset through the linkage rod 6 (i.e. the bottom of the first baffle 4 rotates to the lower left), when the first cylinder 41 resets, the first cylinder 41 pauses, and the second cylinder 51 is started at the same time, the second slide carriage 53 works to a position close to the second slide carriage 52 along the second chute 52, so that the second slide carriage 53 pulls the second baffle 5 to rotate through the linkage rod 6 (i.e. the bottom of the second baffle 5 rotates to the upper, thereby make the ore that originally was located between first baffle 4 and the second baffle 5 fall, after 5 seconds, second cylinder 51 resets, promote second slide 53 along second spout 52 to the direction of keeping away from its self, thereby make second slide 53 drive second baffle 5 through gangbar 6 and reset (being that the bottom of second baffle 5 is to the below rotation of left side), after second cylinder 51 resets, second cylinder 51 pauses, and simultaneously, first cylinder 41 restarts again, and the circulation is reciprocal, thereby make the ore that falls down from feed opening 11 fall from the lowest end of organism 1 in batches, close the machine casing after the end.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (5)

1. The anti-blocking fluorite mining vibration ore drawing machine comprises a machine body (1), a support (2) and a vibration motor (31), wherein the support (2) is welded at the bottom of the machine body (1), a feed opening (11) is formed in the upper end of the machine body (1), and a plurality of groups of vibration seats (3) driven by the vibration motor (31) are installed on the bottom wall of the machine body (1);

the novel gas turbine engine is characterized in that a first baffle (4) and a second baffle (5) are arranged on two sides of the interior of the engine body (1) through fixing shafts respectively, a first sliding groove (42) and a second sliding groove (52) are formed in the side wall of the engine body (1) respectively, a first sliding seat (43) and a second sliding seat (53) are arranged in the first sliding groove (42) and the second sliding groove (52) respectively in a sliding mode, the first sliding seat (43) is arranged between the first sliding seat (43) and the first baffle (4), the second sliding seat (53) is fixedly connected with the second baffle (5) through a linkage rod (6), a first cylinder (41) is connected to one side of the first sliding seat (43), and a second cylinder (51) is connected to one side of the second sliding seat (53).

2. An anti-clogging fluorite mining vibratory ore drawing machine according to claim 1, characterized in that said vibrating motor (31) is fixedly mounted at the bottom of said vibrating seat (3) by means of bolts, and the vibrating seat (3) is also fixed with the bottom wall of the machine body (1) by means of bolts.

3. An anti-clogging fluorite mining vibratory miner according to claim 1 wherein the first cylinder (41) and the second cylinder (51) are bolted to one side of the side wall of the machine body (1).

4. An anti-clogging fluorite mining vibratory miner according to claim 1 wherein the first cylinder (41) is secured to the side walls of the first slide (43) by welding and the second cylinder (51) is secured to the side walls of the second slide (53) by welding.

5. An anti-clogging fluorite mining vibratory miner according to claim 1 wherein the first slide (43) and the second slide (53) are each of a "T" configuration with the convex end of the first slide (43) disposed in the first chute (42) and the convex end of the second slide (53) disposed in the second chute (52).

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