CN216869697U - High-automation tailing pond safety monitoring device - Google Patents

Abstract

The utility model relates to the field of safety monitoring of tailing ponds, in particular to a high-automation safety monitoring device for tailing ponds, which comprises an installation rod and an osmometer body, wherein a lifting part is arranged on the installation rod, and a clamping part is arranged on the lifting part; the clamping part comprises a supporting plate, a first slide way and a second slide way are arranged on the supporting plate, a first moving block is connected to the first slide way in a sliding mode, and a second moving block is connected to the second slide way in a sliding mode. According to the osmometer, the mounting rod, the clamping part, the lifting part and the like are added, when the osmometer body needs to be overhauled or replaced, the lifting part is controlled to drive the clamping part and the osmometer body on the clamping part to move upwards to be exposed out of the water surface, the power set is controlled to drive the movable rod to move towards the supporting plate, two adjacent clamping blocks are driven to move outwards under the action of the connecting rod, the first movable block and the second movable block, and a worker can take out the osmometer body; the osmometer body can be clamped on the clamping block again through reverse operation, and the operation is more convenient; and the structure is simple, and the practicability is better.

Description

High-automation tailing pond safety monitoring device

Technical Field

The utility model relates to the technical field of safety monitoring of tailing ponds, in particular to a high-automation safety monitoring device for tailing ponds.

Background

The tailing pond is a place which is formed by building a dam to intercept a valley opening or enclosing the ground and is used for piling metal or nonmetal mines and discharging tailings or other industrial waste residues after ore sorting. The water level monitoring device is required to monitor the water level of the tailing pond in real time so as to ensure safety.

The utility model discloses a be CN213180209U patent, a tailing storehouse water level monitoring device based on osmometer is disclosed, it includes the device main part, the device main part mainly includes the mounting bracket, one side of mounting bracket is equipped with the spout, install the lead screw in the spout, install the slider on the lead screw, the top fixed mounting of mounting bracket has the motor case, the internally mounted of motor case has the motor, the speed reducer is installed to the bottom of motor, the pivot is installed to the bottom of speed reducer, solar photovoltaic board is installed on the top of motor case, electric telescopic handle is installed to one side of mounting bracket, the suction pump is installed on the top of the opposite side of mounting bracket, the top fixed mounting of suction pump has the drinking-water pipe, and one side fixed mounting of suction pump has the raceway, the bottom fixed mounting of raceway has the fourth mounting panel, the bottom fixed mounting of fourth mounting panel has the shower head, the raceway is connected with the shower head.

Osmometer among the prior art is the snap-on usually on the device, and the clearance, the maintenance of the staff of being not convenient for, change, and the operation is comparatively loaded down with trivial details. Therefore, a highly-automatic tailing pond safety monitoring device is provided.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Aiming at the defects of the prior art, the utility model provides a high-automation tailing pond safety monitoring device, which solves the problem that osmometers in the safety monitoring device in the prior art are inconvenient to overhaul and replace.

(II) technical scheme

In order to realize the purpose, the utility model is realized by the following technical scheme: a high-automation safety monitoring device for a tailings pond comprises an installation rod and an osmometer body, wherein a lifting part is arranged on the installation rod, and a clamping part used for clamping and fixing the osmometer body is arranged on the lifting part;

the clamping part comprises a supporting plate, a first slideway and a second slideway are arranged on the supporting plate, the first slideway is connected with two first moving blocks in a sliding mode, the second slideway is connected with two second moving blocks in a sliding mode, and the rear ends of the two first moving blocks and the two second moving blocks are rotatably connected with connecting rods; the other end of the connecting rod is rotatably connected with a movable rod, and a power set for driving the movable rod to move back and forth is arranged on the supporting plate; the front ends of the two moving blocks I and the two moving blocks II are provided with clamping blocks.

Preferably, the power unit comprises a second screw rod which is connected to the moving rod through a thread, the front end of the second screw rod is rotatably connected with the rear end of the supporting plate, and a rotating handle is fixed at the rear end of the second screw rod.

Preferably, a locking nut is sleeved on the position, corresponding to the position between the rotating handle and the moving rod, of the outer wall of the screw rod.

Preferably, the front ends of the first moving block and the second moving block are both fixed with connecting sleeves, inserting rods are inserted into the connecting sleeves, the connecting sleeves and the inserting rods are locked through locking screws, and one ends of the inserting rods, which are far away from the connecting sleeves, are fixed with the corresponding clamping blocks.

Preferably, the lift portion is including seting up the spout at installation pole front end, and sliding connection has the slider in the spout, and the spout inner wall rotates and is connected with screw rod one, and the spout is stretched out on the top of screw rod one, the motor is installed on the top of installation pole, and the output of motor is fixed with the top of screw rod one, screw rod one runs through threaded connection with the slider, the front end of slider is fixed with the bracing piece, and the other end and the backup pad of bracing piece are fixed.

Preferably, the cross sections of the sliding groove and the sliding block are both in a dovetail shape.

(III) advantageous effects

The embodiment of the utility model provides a high-automation tailing pond safety monitoring device, which has the following beneficial effects:

1. by adding the mounting rod, the clamping part, the lifting part and the like, when the osmometer body needs to be overhauled or replaced, the lifting part is controlled to drive the clamping part and the osmometer body on the clamping part to move upwards to expose out of the water surface, then the power unit is controlled to drive the moving rod to move towards the supporting plate, two adjacent clamping blocks are driven to move outwards under the action of the connecting rod, the moving block I and the moving block II, and a worker can take out the osmometer body; the osmometer body can be clamped on the clamping block again through reverse operation, and the operation is more convenient;

2. the lifting part is added, the motor is started, the first screw rod can be driven to rotate, the sliding block moves along the sliding groove, the supporting rod and the clamping part can be driven to move, and the structure is simple;

3. the connecting sleeve, the locking screw and the inserting rod are added, the locking screw is unscrewed, the inserting rod is taken down from the connecting sleeve, and then the corresponding clamping block can be taken down;

in conclusion, the utility model is convenient in operation, simple in structure and good in practicability.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged view of the structure A of FIG. 1 according to the present invention;

FIG. 3 is a schematic view of a portion of the present invention;

FIG. 4 is a top view of the structure of the present invention.

In the figure: 1-mounting rod, 2-chute, 3-screw rod I, 4-motor, 5-slide block, 6-support rod, 7-support plate, 8 a-slideway I, 8 b-slideway II, 9-moving block I, 10-moving block II, 11-connecting rod, 12-moving rod, 13-screw rod II, 14-locking nut, 15-rotating handle, 16-connecting sleeve, 17-locking screw, 18-inserting rod, 19-clamping block and 20-osmometer body.

Detailed Description

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

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1

As shown in fig. 1-4, a highly automated safety monitoring device for a tailings pond comprises an installation rod 1 and an osmometer body 20, wherein the installation rod 1 is provided with a lifting part, and the lifting part is provided with a clamping part for clamping and fixing the osmometer body 20; the lifting part is used for controlling the clamping part to move along the vertical direction; the clamping part can simultaneously clamp two osmometer bodies 20, so that the error caused by using one osmometer is reduced;

the clamping part comprises a supporting plate 7, a first slideway 8a and a second slideway 8b are formed in the supporting plate 7, the cross sections of the first slideway 8a and the second slideway 8b are cross-shaped, two moving blocks I9 are connected in the first slideway 8a in a sliding manner, two moving blocks II 10 are connected in the second slideway 8b in a sliding manner, and connecting rods 11 are rotatably connected at the rear ends of the two moving blocks I9 and the two moving blocks II 10; the other end of the connecting rod 11 is rotatably connected with a movable rod 12, and a power set for driving the movable rod 12 to move back and forth is arranged on the supporting plate 7; the front ends of the two first moving blocks 9 and the two second moving blocks 10 are respectively provided with a clamping block 19, and the inner ends of the clamping blocks 19 are arranged to be arc surfaces so as to be more matched with the osmometer body 20.

In conclusion, the lifting part is controlled to drive the clamping part to move upwards or downwards to a proper position, when the osmometer body 20 needs to be overhauled or replaced, the lifting part drives the clamping part and the osmometer body 20 thereon to move upwards to be exposed out of the water surface, the power set drives the movable rod 12 to move towards the supporting plate 7, the adjacent connecting rods 11 are opened, the two movable blocks I9 and the two movable blocks II 10 are far away from each other, the two adjacent clamping blocks 19 are driven to move outwards at the same time, and the osmometer body 20 can be taken out; the osmometer body 20 can be clamped on the clamping block 19 again by reverse operation, and the operation is convenient.

In this embodiment, the power set includes a second screw 13 threaded on the moving rod 12, the front end of the second screw 13 is rotatably connected with the rear end of the supporting plate 7, and a rotating handle 15 is fixed at the rear end of the second screw 13. The rotating handle 15 is rotated to drive the second screw rod 13 to rotate, so that the movable rod 12 is driven to move, and the movable rod 12 faces or deviates from the supporting plate 7.

Furthermore, a locking nut 14 is sleeved on the outer wall of the second screw rod 13 at a position corresponding to the position between the rotating handle 15 and the moving rod 12. After the clamp block 19 clamps the osmometer body 20, the lock nut 14 is rotated to make the lock nut 14 abut against the movable rod 12, thereby effectively preventing the second screw rod 13 from deflecting.

In this embodiment, lift portion is including offering in spout 2 of the 1 front end of installation pole, sliding connection has slider 5 in 2 spouts, and 2 inner walls of spout rotate and be connected with screw rod 3, spout 2 is stretched out on the top of screw rod 3, motor 4 is installed on the top of installation pole 1, motor 4's output is fixed with screw rod 3's top, screw rod 3 runs through threaded connection with slider 5, the front end of slider 5 is fixed with bracing piece 6, the other end and the backup pad 7 of bracing piece 6 are fixed. Starting the motor 4, driving the screw rod one 3 fixed with the output end of the motor 4 to rotate, and then driving the sliding block 5 to move along the sliding groove 2, thereby driving the supporting rod 6 and the clamping part to move.

Specifically, the cross sections of the sliding chute 2 and the sliding block 5 are both in a dovetail shape.

Example 2

On the basis of the embodiment 1, the front ends of the first moving block 9 and the second moving block 10 are both fixed with a connecting sleeve 16, an inserting rod 18 is inserted into the connecting sleeve 16, the connecting sleeve 16 and the inserting rod 18 are locked through a locking screw 17, and one end of the inserting rod 18, which is far away from the connecting sleeve 16, is fixed with a corresponding clamping block 19. The locking screw 17 is unscrewed, the inserted rod 18 and the clamping blocks 19 on the inserted rod can be taken out, and the clamping blocks 19 with different sizes can be replaced, so that the osmometer body 18 with different sizes can be conveniently clamped in an adaptive mode, and the practicability is good.

All kinds of parts used in this application file are standard parts, can purchase from the market, and the specific connected mode of each part all adopts conventional means such as ripe bolt, rivet and welding among the prior art, and machinery, part and electrical equipment all adopt conventional model among the prior art.

The embodiments of the present invention are disclosed as the preferred embodiments, but not limited thereto, and those skilled in the art can easily understand the spirit of the present invention and make various extensions and changes without departing from the spirit of the present invention.

Claims (6)

1. The utility model provides a high automatic tailing storehouse safety monitoring device, includes installation pole (1) and osmometer body (20), its characterized in that: the mounting rod (1) is provided with a lifting part, and the lifting part is provided with a clamping part for clamping and fixing the osmometer body (20);

the clamping part comprises a supporting plate (7), a first slideway (8a) and a second slideway (8b) are formed in the supporting plate (7), two first moving blocks (9) are connected in the first slideway (8a) in a sliding mode, two second moving blocks (10) are connected in the second slideway (8b) in a sliding mode, and connecting rods (11) are rotatably connected to the rear ends of the two first moving blocks (9) and the two second moving blocks (10); the other end of the connecting rod (11) is rotatably connected with a movable rod (12), and a power set for driving the movable rod (12) to move back and forth is arranged on the supporting plate (7); the front ends of the two moving blocks I (9) and the two moving blocks II (10) are respectively provided with a clamping block (19).

2. The highly automated tailing pond safety monitoring device of claim 1, wherein: the power unit comprises a second screw rod (13) which penetrates through the moving rod (12) in threaded connection, the front end of the second screw rod (13) is rotatably connected with the rear end of the supporting plate (7), and a rotating handle (15) is fixed at the rear end of the second screw rod (13).

3. The highly automated tailing pond safety monitoring device of claim 2, characterized in that: and a locking nut (14) is sleeved on the outer wall of the second screw rod (13) at a position corresponding to the position between the rotating handle (15) and the moving rod (12).

4. The highly automated tailing pond safety monitoring device of claim 2, characterized in that: the front ends of the first moving block (9) and the second moving block (10) are respectively fixed with a connecting sleeve (16), an inserting rod (18) is inserted in the connecting sleeve (16), the connecting sleeve (16) and the inserting rod (18) are locked through a locking screw (17), and one end, deviating from the connecting sleeve (16), of the inserting rod (18) is fixed with the corresponding clamping block (19).

5. The highly automated tailing pond safety monitoring device of claim 1, wherein: the lift portion is including offering spout (2) at installation pole (1) front end, and sliding connection has slider (5) in spout (2), and spout (2) inner wall rotates and is connected with screw rod (3), and spout (2) are stretched out on the top of screw rod (3), motor (4) are installed on the top of installation pole (1), and the output of motor (4) is fixed with the top of screw rod (3), screw rod (3) and slider (5) run through threaded connection, the front end of slider (5) is fixed with bracing piece (6), and the other end and backup pad (7) of bracing piece (6) are fixed.

6. The highly automated tailing pond safety monitoring device of claim 5, wherein: the cross sections of the sliding chute (2) and the sliding block (5) are both in a dovetail shape.

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