CN220687405U - Mining high-pressure cooperative driving device - Google Patents

Abstract

The utility model discloses an ore mining high-pressure cooperative driving device which comprises a base, wherein four support columns are symmetrically and fixedly connected to the lower side wall of the base, pulleys are mounted at the lower ends of the support columns, a support plate is symmetrically and fixedly connected to the upper side wall of the base, and mounting plates are jointly and fixedly connected to the upper side walls of the two support plates. According to the utility model, the beam plate moves downwards to enable the beam plate to be clung to the outer wall of the pipeline, the screw rod drives the moving block, the electric telescopic rod and the beam plate to move leftwards, so that the pipeline is driven to move leftwards in the moving process of the beam plate, the electric telescopic rod moves upwards when the beam plate moves leftmost, the beam plate is separated from contact with the outer wall of the pipeline, the electric telescopic rod rotates anticlockwise, the screw rod drives the moving block and the beam plate to move rightwards, the operation is repeated, the pipeline is pushed leftwards to be carried, the manual use amount is reduced, and the operation cost before mining is reduced.

Description

Mining high-pressure cooperative driving device

Technical Field

The utility model relates to the technical field of mining, in particular to a mining high-pressure cooperative driving device.

Background

Underground mining refers to the process of extracting ore from ore blocks of an underground deposit, and is realized through four steps of ore deposit exploitation, ore block mining, cutting and stoping. Underground mining methods are classified into three main types, namely, natural support mining methods, manual support mining methods and caving mining methods, according to the ground pressure management method. The underground mining system mainly comprises a production management system, a rock drilling system, a blasting system, an ore discharging system, an ore sliding system, an underground crushing system, a skip lifting system and a lifting well frame system. The main steps of underground exploitation, common methods, safety rules corresponding to different methods and the like are described in detail.

In the process of underground mining ore, groundwater resources can be continuously gushed into an ore mining area, so that an underground drainage pipeline is required to be laid in advance, and when the pipeline is laid, the operation cannot be carried out by large machinery laid by the pipeline because the space of the mining area is limited, so that the drainage pipeline is required to be manually conveyed to the drainage area, and because the length of the pipeline is longer, the weight of the pipeline is larger, a large amount of manpower resources are required for manual conveying, time and labor are wasted, and the operation cost before ore mining is increased.

Disclosure of Invention

The utility model aims to solve the problems in the background technology and provides an ore mining high-pressure cooperative driving device.

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

the utility model provides a high-pressure collaborative drive device is adopted to ore deposit, includes the base, four support columns of lower lateral wall symmetry fixedly connected with of base, every the pulley is all installed to the lower extreme of support column, the last lateral wall symmetry fixedly connected with backup pad of base, two the last lateral wall of backup pad is fixedly connected with mounting panel jointly, the last lateral wall symmetry fixedly connected with of base is located the bracing piece between two backup pads, two the equal fixedly connected with arc in top of bracing piece is located the right side the left side wall fixedly connected with motor of backup pad, the drive end fixedly connected with of motor rotates the lead screw of being connected with left side backup pad, the outer wall threaded connection of lead screw has the movable block with mounting panel lower lateral wall sliding connection, the lower lateral wall fixedly connected with electric telescopic handle of movable block, electric telescopic handle's drive end fixedly connected with beam plate.

Preferably, a plurality of first bearings are uniformly and fixedly embedded in the arc-shaped inner wall of the arc-shaped plate, and the inner wall of each first bearing is provided with a ball.

Preferably, a second bearing is fixedly embedded in the right side wall of the support plate positioned at the left side, and an inner ring of the second bearing is fixedly connected with the outer wall of the screw rod.

Preferably, a guide groove matched with the moving block is formed in the lower side wall of the mounting plate.

Preferably, the beam plate is arranged in an arc shape, and an anti-slip pad is arranged on the arc-shaped wall of the beam plate.

Compared with the prior art, the mining high-pressure cooperative driving device has the advantages that:

the method comprises the steps of arranging arc plates, round balls, a motor, a screw rod, a moving block, an electric telescopic rod and a beam plate, arranging a pipeline on the two arc plates, starting the electric telescopic rod, driving the beam plate to move downwards by the driving end of the electric telescopic rod so that the beam plate is clung to the outer wall of the pipeline, starting the motor again, driving the screw rod to rotate clockwise by the driving end of the motor so that the screw rod drives the moving block, the electric telescopic rod and the beam plate to move leftwards, driving the pipeline to move leftwards by the beam plate in the moving process, enabling the beam plate to move leftwards until the beam plate moves leftwards, enabling the beam plate to be separated from contact with the outer wall of the pipeline, enabling the screw rod to drive the moving block and the beam plate to move rightwards by the anticlockwise rotation of the motor, repeating the operations, further realizing leftward pushing and carrying of the pipeline, reducing the manual use amount and further reducing the operation cost before mining;

in summary, the utility model makes the beam plate cling to the outer wall of the pipeline by downwards moving the beam plate, the screw rod drives the moving block, the electric telescopic rod and the beam plate to move leftwards, and then drives the pipeline to move leftwards by the beam plate moving process, the electric telescopic rod moves upwards when the beam plate moves leftmost, so that the beam plate is separated from contact with the outer wall of the pipeline, and the electric telescopic rod rotates anticlockwise, so that the screw rod drives the moving block and the beam plate to move rightwards, and the operation is repeated, thereby realizing leftward pushing and carrying of the pipeline, reducing the manual use amount and further reducing the operation cost before mining.

Drawings

Fig. 1 is a schematic structural diagram of an mining high-pressure cooperative driving device provided by the utility model;

fig. 2 is a perspective view of a joint among an arc plate, a bearing one and a ball in the mining high-pressure cooperative driving device.

In the figure: 1 base, 2 support column, 3 pulleys, 4 support plates, 5 mounting plates, 6 support rods, 7 arc plates, 8 bearing I, 9 balls, 10 motors, 11 screw rods, 12 moving blocks, 13 electric telescopic rods and 14 binding plates.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1-2, a mining high-pressure collaborative driving device comprises a base 1, wherein four support columns 2 are symmetrically and fixedly connected to the lower side wall of the base 1, pulleys 3 are installed at the lower end of each support column 2, support plates 4 are symmetrically and fixedly connected to the upper side wall of the base 1, mounting plates 5 are fixedly connected to the upper side walls of the two support plates 4 together, support rods 6 positioned between the two support plates 4 are symmetrically and fixedly connected to the upper side wall of the base 1, arc plates 7 are fixedly connected to the top ends of the two support rods 6, a plurality of first bearings 8 are uniformly and fixedly embedded in the arc inner walls of the arc plates 7, round balls 9 are installed on the inner walls of each first bearing 8, the first bearings 8 and the round balls 9 are matched for use, so that the original sliding friction is converted into rolling friction in the moving process of a pipeline, the pipeline is smoother, a motor 10 is fixedly connected to the left side wall of the support plate 4 positioned on the right side, a lead screw 11 rotatably connected with the driving end of the motor 10, a second bearing is fixedly embedded in the right side wall of the support plate 4 positioned on the left side, a second bearing is fixedly connected with an outer wall 11 of the lead screw, and the outer wall 11 of the second bearing is fixedly connected with the lower side wall 12 of the lead screw is connected with the lower side wall 12 of the lead screw;

the guide way matched with the movable block 12 is formed in the lower side wall of the mounting plate 5, the electric telescopic rod 13 is fixedly connected to the lower side wall of the movable block 12, the beam plate 14 is fixedly connected to the driving end of the electric telescopic rod 13, the beam plate 14 is in an arc-shaped arrangement, an anti-slip pad is mounted on the arc-shaped wall of the beam plate 14, friction force between the beam plate 14 and the outer wall of a pipeline is increased due to the arrangement of the anti-slip pad, the pipeline is better pushed to move, the pipeline is placed on the two arc-shaped plates 7, the electric telescopic rod 13 is started, the driving end of the electric telescopic rod 13 drives the beam plate 14 to move downwards, the beam plate 14 is tightly attached to the outer wall of the pipeline, the motor 10 is started again, the driving end of the motor 10 drives the screw rod 11 to rotate clockwise, the screw rod 11 drives the movable block 12, the electric telescopic rod 13 and the beam plate 14 to move leftwards, the pipeline is driven to move leftwards through the beam plate 14, the leftwards end of the beam plate 14 is driven to move, the beam plate 14 is enabled to be separated from being in contact with the outer wall of the pipeline to rotate anticlockwise, the screw rod 11 drives the moving block 12 and the beam plate 14 to move rightwards, and then the operation is repeated, and labor cost of the ore is reduced.

Further, the above-described fixed connection is to be understood in a broad sense, unless explicitly stated and defined otherwise, as being, for example, welded, glued, or integrally formed, as is well known to those skilled in the art.

The principle of operation of the present utility model will now be described as follows:

when the electric telescopic device is used, a pipeline is placed on the two arc plates 7, the electric telescopic rod 13 is started, the driving end of the electric telescopic rod 13 drives the beam plate 14 to move downwards, the beam plate 14 is tightly attached to the outer wall of the pipeline, the motor 10 is started again, the driving end of the motor 10 drives the screw rod 11 to rotate clockwise, the screw rod 11 drives the moving block 12, the electric telescopic rod 13 and the beam plate 14 to move leftwards, the pipeline is driven to move leftwards through the beam plate 14 in the moving process, the beam plate 14 is prevented from contacting the outer wall of the pipeline after the leftmost end of the beam plate 14 moves, the electric telescopic rod 13 moves upwards, the beam plate 14 is prevented from contacting the outer wall of the pipeline, the motor 10 rotates anticlockwise, the screw rod 11 drives the moving block 12 and the beam plate 14 to move rightwards, and the operation is repeated, so that the pipeline is pushed leftwards, the manual usage amount is reduced, and the operation cost before mining is reduced.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (5)

1. The utility model provides a high-pressure collaborative drive device is adopted to ore deposit, includes base (1), its characterized in that, four support column (2) of lower lateral wall symmetry fixedly connected with of base (1), every pulley (3) are all installed to the lower extreme of support column (2), the last lateral wall symmetry fixedly connected with backup pad (4) of base (1), two the last lateral wall joint fixedly connected with mounting panel (5) of backup pad (4), the last lateral wall symmetry fixedly connected with of base (1) is located bracing piece (6) between two backup pads (4), two equal fixedly connected with arc (7) in top of bracing piece (6), be located the right side the left side wall fixedly connected with motor (10) of backup pad (4), the drive end fixedly connected with and left backup pad (4) swivelling joint's lead screw (11), the outer wall threaded connection of lead screw (11) has movable block (12) with lateral wall sliding connection under mounting panel (5), the lower lateral wall fixedly connected with electric pole (13) of movable block (12), the flexible board (14) of drive end (13) are restrainted.

2. The mining high-pressure cooperative driving device according to claim 1, wherein a plurality of first bearings (8) are uniformly and fixedly embedded in the arc-shaped inner wall of the arc-shaped plate (7), and round balls (9) are arranged on the inner wall of each first bearing (8).

3. The mining high-pressure cooperative driving device according to claim 1, wherein a second bearing is fixedly embedded in the right side wall of the supporting plate (4) positioned on the left side, and an inner ring of the second bearing is fixedly connected with the outer wall of the screw rod (11).

4. The mining high-pressure cooperative driving device according to claim 1, wherein a guide groove matched with the moving block (12) is formed in the lower side wall of the mounting plate (5).

5. The mining high-pressure cooperative driving device according to claim 1, wherein the beam plate (14) is arranged in an arc shape, and an anti-slip pad is arranged on an arc-shaped wall of the beam plate (14).