CN216896648U - Digital monitoring system for tailing pond - Google Patents

Abstract

The utility model relates to the technical field of tailing pond monitoring, in particular to a tailing pond digital monitoring system which comprises a sliding rail, a movable rod, a mounting plate and a camera mounting seat. The base is arranged on the sliding rail, the vertical rod is vertically arranged on the base, and the ultrasonic side seam instrument is arranged on the vertical rod. The movable rod slides and is arranged inside the vertical rod, a motor is arranged in the vertical rod, and the motor drives the movable rod to be connected. The mounting panel sets up on the movable rod, sets up the mounting groove on the mounting panel, and the board is dialled to the interior sliding setting of mounting panel, dials and sets up the bolt on the board, and the bolt inserts in the mounting groove and rather than sliding connection. Set up the spring in the mounting panel, the other end of spring is connected with the one end of dialling the board and keeping away from the bolt. One side of the camera mounting seat close to the mounting plate is provided with a clamping block, and the clamping block is inserted into the mounting groove. The clamping block is provided with a pin hole, the bolt is inserted into the pin hole and is in sliding connection with the pin hole, and the bottom of the camera mounting seat is provided with a camera. The utility model can automatically monitor the cracks of the dam and is convenient to disassemble and assemble.

Description

Digital monitoring system for tailing pond

Technical Field

The utility model relates to the technical field of tailing pond monitoring, in particular to a digital monitoring system for a tailing pond.

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 tailings pond is an artificial debris flow danger source with high potential energy, dam break danger exists, and major accidents are easily caused once the tailings pond is lost. The monitoring camera generally needs to be erected during the safety monitoring of a tailing pond, the existing video monitoring mostly adopts a fixed support to install a monitor, the performance of active movement is lacked, the installation point position of dam crack monitoring in a safety monitoring system is fixed, full-coverage scanning monitoring can not be carried out on a dam in an all-round mode, and meanwhile, the existing device is very troublesome in replacement and maintenance of monitoring equipment.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a tailing pond digital monitoring system aiming at the problems in the background technology.

The technical scheme of the utility model is as follows: a digital monitoring system for a tailing pond comprises a slide rail, a movable rod, a mounting plate and a camera mounting seat. The base is arranged on the sliding rail, the vertical rod is arranged on the base, the transverse rod is arranged on the vertical rod, and the ultrasonic side seam instrument is arranged below the transverse rod. The movable rod slides and is arranged in the vertical rod, the motor is arranged in the vertical rod, the output end of the motor is provided with a lead screw, and the top end of the lead screw is inserted into the movable rod and is in threaded connection with the movable rod. The mounting panel sets up on the movable rod, sets up the mounting groove on the mounting panel, and the board is dialled to the interior sliding setting of mounting panel, dials the board and goes up the level and set up the bolt, and the bolt inserts in the mounting groove and rather than sliding connection. The spring is arranged in the mounting plate, and the other end of the spring is connected with one end, far away from the bolt, of the shifting plate. The camera mounting seat is arranged on the mounting plate, one side of the camera mounting seat close to the mounting plate is provided with a fixture block, and the fixture block is inserted into the mounting groove and is in sliding connection with the mounting groove. The fixture block is provided with a pin hole, the bolt is inserted into the pin hole and is in sliding connection with the pin hole, and the bottom of the camera mounting seat is provided with a camera.

Preferably, the slide rail is an I-shaped slide rail, and a sliding groove is formed in the slide rail. The bottom symmetry of base sets up two sets of gyro wheels, and the gyro wheel is located I-shaped slide rail both sides recess respectively and rather than upper surface rolling contact, and the bottom of base sets up the drive wheel, and the drive wheel is located the inside of spout and rather than lower surface rolling contact.

Preferably, the control box is arranged on the vertical rod, the antenna is arranged on the control box, and the antenna is a telescopic antenna.

Preferably, the inside of montant sets up the threading pipe, and the threading pipe includes two parts of inner tube and outer tube, and the inner tube cover is established at the outer intraduct and rather than sliding connection, and the inner tube setting is in the montant, and the outer tube setting is in the movable rod. The side of the movable rod is provided with a threading hole, and the threading pipe is communicated with the threading hole.

Preferably, a sliding rod is arranged in the vertical rod, the sliding rod is parallel to the screw rod, and the sliding rod is connected with the movable rod in a sliding mode.

Preferably, a storage battery pack is further included. The side of movable rod sets up the telescopic bracket, and the output of telescopic bracket sets up photovoltaic power generation board, photovoltaic power generation board and storage battery electric connection, storage battery and each electrical part electric connection.

Preferably, a climate instrument is arranged at the top end of the movable rod.

Preferably, a signal transceiver is arranged in the control box.

Compared with the prior art, the utility model has the following beneficial technical effects:

by arranging the slide rail and arranging the driving wheel at the bottom of the base, the base moves along the slide rail under the rotation of the driving wheel, so that the ultrasonic side seam instrument on the vertical rod can perform full-coverage scanning on the whole dam, and workers can obtain accurate dam crack information; through the lifting structure provided with the movable rod, the movable rod is driven by the motor to ascend or descend, so that a worker can conveniently install or replace the camera; the camera mounting seat and the camera can be fixed by arranging the bolt and arranging the fixture block with the pin hole on the camera mounting seat, clamping the camera mounting seat into the mounting groove and then inserting the bolt into the pin hole, so that the camera mounting seat and the camera can be conveniently fixed without any auxiliary tool; meanwhile, the system has a climate monitoring function, and can feed back data obtained in real time to the master control room in a wireless transmission mode.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a connection structure of a vertical rod and a movable rod;

FIG. 3 is a block diagram of the base;

fig. 4 is a structural view of the camera mounting base and the camera.

Reference numerals: 1. a slide rail; 2. a chute; 3. a base; 4. a roller; 5. a drive wheel; 6. a vertical rod; 7. a cross bar; 8. ultrasonic side seam instrument; 9. a control box; 10. an antenna; 11. a movable rod; 12. a motor; 13. a screw rod; 14. a threading tube; 15. a slide bar; 16. threading holes; 17. mounting a plate; 18. mounting grooves; 19. dialing a plate; 20. a bolt; 21. a spring; 22. a camera mounting base; 23. a clamping block; 24. a pin hole; 25. a camera; 26. a photovoltaic power generation panel; 27. a climate instrument.

Detailed Description

Example one

As shown in fig. 1 to 4, the digital monitoring system for the tailings pond provided by the utility model comprises a slide rail 1, a movable rod 11, a mounting plate 17 and a camera mounting seat 22. Set up base 3 on the slide rail 1, the vertical montant 6 that sets up on the base 3 sets up horizontal pole 7 on the montant 6, and the below of horizontal pole 7 sets up ultrasonic wave side seam appearance 8. The movable rod 11 is arranged inside the vertical rod 6 in a sliding mode, the motor 12 is arranged in the vertical rod 6, the output end of the motor 12 is provided with a screw rod 13, and the top end of the screw rod 13 is inserted into the movable rod 11 and is in threaded connection with the movable rod. The mounting panel 17 sets up on movable rod 11, sets up mounting groove 18 on the mounting panel 17, and the setting is dialled in the sliding in mounting panel 17 board 19, dials the board 19 and goes up the level and set up bolt 20, and bolt 20 inserts in the mounting groove 18 and rather than sliding connection. A spring 21 is arranged in the mounting plate 17, and the other end of the spring 21 is connected with one end of the shifting plate 19 far away from the bolt 20. The camera mounting seat 22 is arranged on the mounting plate 17, one side of the camera mounting seat 22 close to the mounting plate 17 is provided with a fixture block 23, and the fixture block 23 is inserted into the mounting groove 18 and is in sliding connection with the mounting groove. The clamping block 23 is provided with a pin hole 24, the bolt 20 is inserted into the pin hole 24 and is connected with the pin hole in a sliding mode, and the bottom of the camera mounting seat 22 is provided with a camera 25.

In this embodiment, when carrying out the dam body monitoring in tailing storehouse, start ultrasonic wave side slot appearance 8 and camera 25, camera 25 can the omnidirectional detect the particular case in the tailing storehouse, and ultrasonic wave side slot appearance 8 then detects the dam body, start the drive assembly in the base 3 when ultrasonic wave side slot appearance 8 carries out work and make base 3 slide along slide rail 1, thereby scan whole dam, in time discover the crack that the dam appears and with signal feedback to the control room, prevent that the dam crack from expanding and leading to the dam to break. When the camera needs to be replaced, starting motor 12, motor 12 drives lead screw 13 and rotates, the movable rod 11 descends gradually under the conduction of lead screw 13 this moment, when movable rod 11 reduces to appropriate height, the staff stirs group board 19 and makes bolt 20 retract, then take off camera mount pad 22, change or maintain camera 25 after with camera mount pad 22 card go into mounting groove 18 in, loosen group board 19, bolt 20 stretches out and reinsert in pinhole 24 under the promotion of spring 21 automatically, thereby fix camera mount pad 22 on mounting panel 17, starting motor 12 reverses afterwards, movable rod 11 rises to initial height.

Example two

As shown in fig. 1 and 3, compared with the first embodiment, the digital monitoring system for the tailings pond provided by the utility model has the advantages that the slide rail 1 is an i-shaped slide rail, and the slide rail 1 is provided with the slide groove 2. The bottom symmetry of base 3 sets up two sets of gyro wheels 4, and gyro wheel 4 lies in I-shaped slide rail both sides recess respectively and rather than upper surface rolling contact, and the bottom of base 3 sets up drive wheel 5, and drive wheel 5 lies in the inside of spout 2 and rather than lower surface rolling contact.

In this embodiment, the rollers 4 on both sides can reduce the friction between the base 3 and the slide rail 1, and the rollers 4 abut against the upper surface of the groove on the side of the i-shaped side surface to prevent the whole base 3 from turning on one side, and the driving wheel 5 is arranged in the sliding groove 2 to limit the position of the whole base 3.

EXAMPLE III

As shown in fig. 2, compared with the first embodiment, the digital monitoring system for the tailings pond provided by the present invention has the structure that the threading pipe 14 is arranged inside the vertical rod 6, the threading pipe 14 includes an inner pipe and an outer pipe, the inner pipe is sleeved inside the outer pipe and is slidably connected with the outer pipe, the inner pipe is arranged inside the vertical rod 6, and the outer pipe is arranged inside the movable rod 11. The side of the movable rod 11 is provided with a threading hole 16, and the threading pipe 14 is communicated with the threading hole 16.

In this embodiment, threading pipe 14 mainly is the effect of playing the direction, conveniently threads in montant 6 and movable rod 11, and the end of a thread comes out the back from through wires hole 16 and is connected with the wiring end of camera 25 again, and the cable can also effectually avoid in threading pipe 14 to contact with lead screw 13, prevents that the cable epidermis is damaged.

The embodiments of the present invention have been described in detail with reference to the drawings, but the present invention is not limited thereto, and various changes can be made within the knowledge of those skilled in the art without departing from the gist of the present invention.

Claims (8)

1. The digital monitoring system for the tailing pond is characterized by comprising a slide rail (1), a movable rod (11), a mounting plate (17) and a camera mounting seat (22);

a base (3) is arranged on the sliding rail (1), a vertical rod (6) is vertically arranged on the base (3), a cross rod (7) is arranged on the vertical rod (6), and an ultrasonic side seam instrument (8) is arranged below the cross rod (7); the movable rod (11) is arranged inside the vertical rod (6) in a sliding manner, a motor (12) is arranged in the vertical rod (6), a lead screw (13) is arranged at the output end of the motor (12), and the top end of the lead screw (13) is inserted into the movable rod (11) and is in threaded connection with the movable rod;

the mounting plate (17) is arranged on the movable rod (11), the mounting plate (17) is provided with a mounting groove (18), the mounting plate (17) is internally provided with a shifting plate (19) in a sliding manner, the shifting plate (19) is horizontally provided with a bolt (20), and the bolt (20) is inserted into the mounting groove (18) and is connected with the mounting groove in a sliding manner; a spring (21) is arranged in the mounting plate (17), and the other end of the spring (21) is connected with one end, far away from the bolt (20), of the shifting plate (19);

the camera mounting seat (22) is arranged on the mounting plate (17), one side, close to the mounting plate (17), of the camera mounting seat (22) is provided with a fixture block (23), and the fixture block (23) is inserted into the mounting groove (18) and is in sliding connection with the mounting groove; the clamping block (23) is provided with a pin hole (24), the bolt (20) is inserted into the pin hole (24) and is in sliding connection with the pin hole, and the bottom of the camera mounting seat (22) is provided with a camera (25).

2. The digital monitoring system for the tailings pond according to claim 1, wherein the slide rail (1) is an I-shaped slide rail, and a chute (2) is arranged on the slide rail (1); the bottom symmetry of base (3) sets up two sets of gyro wheels (4), and gyro wheel (4) are located I-shaped slide rail both sides recess respectively and rather than upper surface rolling contact, and the bottom of base (3) sets up drive wheel (5), and drive wheel (5) are located the inside of spout (2) and rather than lower surface rolling contact.

3. The digital monitoring system for the tailings ponds according to claim 1, wherein a control box (9) is arranged on the vertical rod (6), and an antenna is arranged on the control box (9), wherein the antenna is a telescopic antenna.

4. The digital monitoring system for the tailings pond according to claim 1, wherein a threading pipe (14) is arranged inside the vertical rod (6), the threading pipe (14) comprises an inner pipe and an outer pipe, the inner pipe is sleeved inside the outer pipe and is slidably connected with the outer pipe, the inner pipe is arranged inside the vertical rod (6), and the outer pipe is arranged inside the movable rod (11); the side surface of the movable rod (11) is provided with a threading hole (16), and the threading pipe (14) is communicated with the threading hole (16).

5. The digital monitoring system for the tailings pond according to claim 1, wherein a sliding rod (15) is arranged in the vertical rod (6), the sliding rod (15) is parallel to the screw rod (13), and the sliding rod (15) is slidably connected with the movable rod (11).

6. The digital monitoring system for the tailings pond of claim 1 further comprising a storage battery pack; the side of movable rod (11) sets up telescopic bracket, and telescopic bracket's output sets up photovoltaic power generation board (26), photovoltaic power generation board (26) and storage battery electric connection, storage battery and each electrical part electric connection.

7. A digital monitoring system for a tailings pond according to claim 1, wherein a climate instrument (27) is arranged at the top end of the movable rod (11).

8. A digital monitoring system for a tailings pond according to claim 1, wherein a signal transceiver is arranged in the control box (9).

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