CN216815533U - Device for monitoring mine geological environment - Google Patents

Abstract

The utility model provides a device for monitoring mine geological environment, which comprises: a movable seat; the rotating disc is rotatably connected to the top of the moving seat, and communicating holes are formed in the rotating disc and the moving seat; the spout, the spout is seted up in the front and the back at rolling disc top, the equal sliding connection in both sides of spout inside has first slider and second slider, the top fixed mounting of second slider has the removal structure, fixed plate fixed mounting has the motor in the inboard of removal structure, the one end fixed mounting of motor output shaft has the hob. The device for monitoring the mine geological environment, provided by the utility model, can be used for quickly and stably punching, can be used for controlling the depth according to actual needs, and is simple and convenient in structure, so that the monitoring device can be quickly put into work, and the working efficiency is improved.

Description

Device for monitoring mine geological environment

Technical Field

The utility model relates to the field of geological exploration, in particular to a device for monitoring mine geological environment.

Background

The geological exploration is investigation and research activities of surveying and detecting geology through various means and methods, determining a proper bearing stratum, determining a foundation type according to the foundation bearing capacity of the bearing stratum and calculating foundation parameters.

In order to understand the state of the geological environment when conducting geological surveys, environmental monitoring devices are therefore required.

At present, when geological environment monitoring is carried out, because the ground and the underground condition are different, thereby the monitoring work needs to be carried out deep into the underground to acquire more stable data, and the existing environment monitoring device reaches a proper depth through manual digging when detecting the low, consumes time and labor, and has low working efficiency.

Therefore, it is necessary to provide a device for monitoring mine geological environment to solve the technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a device for monitoring a mine geological environment, which solves the problems that the prior environmental monitoring device needs to go deep underground to monitor and acquire more stable data because the ground and the underground conditions are different when the geological environment is monitored, and the prior environmental monitoring device needs to reach a proper depth through manual hole digging when the prior environmental monitoring device detects the low conditions, consumes time and labor and has low working efficiency.

In order to solve the technical problem, the utility model provides a device for monitoring mine geological environment, which comprises: a movable seat;

the rotating disc is rotatably connected to the top of the moving seat, and communicating holes are formed in the rotating disc and the moving seat;

the sliding grooves are formed in the front side and the back side of the top of the rotating disc, a first sliding block and a second sliding block are connected to the two sides of the inner portion of each sliding groove in a sliding mode, a moving structure is fixedly installed on the top of each second sliding block, a motor is fixedly installed on the inner side of each moving structure through a fixing plate, and a spiral rod is fixedly installed at one end of an output shaft of the motor;

the connecting frame is fixedly arranged at the top of the first sliding block, and a monitoring device is fixedly arranged on the inner side of the top of the connecting frame;

the first clamping groove is formed in the top of the movable seat;

the first bolt is arranged at the top of the front face of the rotating disc.

Preferably, the outer sides of the first sliding block and the second sliding block are provided with second clamping grooves.

Preferably, the front and the back of the top of the rotating disc and the outer side of the sliding groove are provided with second bolts through fixing seats.

Preferably, the moving structure comprises a sliding rod, a third sliding block is connected to the surface of the sliding rod in a sliding manner, and a spring is arranged at the bottom of the third sliding block and on the surface of the sliding rod.

Preferably, the top of hob has seted up the quad slit, the inside of quad slit is provided with the plug block, the third draw-in groove has all been seted up at the top of hob both sides.

Preferably, the both sides of grafting piece all rotate and are connected with the bolt, the surface cover of bolt is equipped with the nut, the inboard of nut just for being located the surface of bolt is provided with the joint pole.

Preferably, both sides of the top of the insertion block are provided with limiting structures, and the outer side of the bottom of each limiting structure is fixedly connected with the top of the clamping rod.

Compared with the related art, the device for monitoring the mine geological environment has the following beneficial effects:

the utility model provides a device for monitoring mine geological environment, which can rapidly and stably carry out punching work through the mutual matching of structures such as a moving seat, a rotating disc, a first sliding block, a sliding groove, a second sliding block, a moving structure, a motor, a screw rod, a connecting frame, a monitoring device, a communication hole, a first bolt, a first clamping groove and the like, can control the depth according to actual needs, has a simple and convenient structure, and can enable the monitoring device to rapidly enter the work, thereby improving the work efficiency.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of the device for monitoring the mine geological environment, provided by the utility model;

FIG. 2 is a schematic structural view of the top of the movable base shown in FIG. 1;

FIG. 3 is a schematic structural diagram of a second embodiment of the device for monitoring the geological environment of the mine, provided by the utility model;

fig. 4 is an enlarged view of the portion a shown in fig. 3.

The reference numbers in the figures: 1. a movable seat, 2, a rotating disc, 3, a first sliding block, 31, a sliding chute, 4, a second sliding block, 5, a second clamping groove, 6, a movable structure, 61, a sliding rod, 62, a third sliding block, 63, a spring, 7, a motor, 8, a screw rod, 9, a connecting frame, 10, a monitoring device, 11, a communication hole, 12, a first bolt, 13, a second bolt, 14 and a first clamping groove,

15. square hole, 16, plug-in block, 17, third draw-in groove, 18, restriction structure, 19, joint pole, 20, bolt, 21, nut.

Detailed Description

The utility model is further described with reference to the following figures and embodiments.

First embodiment

Referring to fig. 1 and fig. 2 in combination, wherein fig. 1 is a schematic structural diagram of a first embodiment of an apparatus for monitoring a geological environment of a mine according to the present invention; fig. 2 is a schematic structural view of the top of the movable base shown in fig. 1. An apparatus for mine geological environment monitoring, comprising: a movable seat 1;

the rotating disc 2 is rotatably connected to the top of the moving seat 1, and communicating holes 11 are formed in the rotating disc 2 and the moving seat 1;

the sliding chute 31 is arranged on the front side and the back side of the top of the rotating disc 2, a first sliding block 3 and a second sliding block 4 are connected to two sides of the inside of the sliding chute 31 in a sliding mode, a moving structure 6 is fixedly installed on the top of the second sliding block 4, a motor 7 is fixedly installed on the inner side of the moving structure 6 through a fixing plate, and a spiral rod 8 is fixedly installed at one end of an output shaft of the motor 7;

the top fixed mounting of fixed plate has the handle, thereby can make things convenient for the staff to carry out pushing motor 7 downwards through the handle and remove.

The connecting frame 9 is fixedly arranged at the top of the first sliding block 3, and the inner side of the top of the connecting frame 9 is fixedly provided with a monitoring device 10;

the first clamping groove 14 is formed in the top of the movable base 1, and the first clamping groove 14 is formed in the top of the movable base 1;

the quantity of first draw-in groove 14 is a plurality of, and uses the intercommunicating pore 11 to distribute around intercommunicating pore 11 as the center to can make rolling disc 2 rotate the position of difference and can make its first bolt 12 inject the inside of first draw-in groove 14 and carry out the rigidity to its rolling disc 2, thereby can conveniently carry out the position of operating according to the staff and adjust.

And the first bolt 12 is arranged at the top of the front surface of the rotating disc 2.

And a second clamping groove 5 is formed in the outer sides of the first sliding block 3 and the second sliding block 4.

The front and the back of the top of the rotating disc 2 and the outer side of the sliding groove 31 are provided with a second bolt 13 through a fixed seat.

The moving structure 6 comprises a slide rod 61, a third slide block 62 is connected to the surface of the slide rod 61 in a sliding manner, and a spring 63 is arranged at the bottom of the third slide block 62 and on the surface of the slide rod 61.

Thereby can improve the stability that motor 7 removed and thereby can conveniently receive ascending driving force and reset when its motor 7 does not receive downward driving force through the elastic deformation of spring 63 through removal structure 6.

The working principle of the device for monitoring the mine geological environment provided by the utility model is as follows:

when monitoring work is needed, the movable seat 1 is pushed to move to a proper position, so that the whole structure can move to a proper position, then the first bolt 12 is pulled upwards according to an actual operation position, the first bolt 12 is moved upwards through the stress of the first bolt 12, so that the first bolt is gradually separated from the state of being inserted into the first clamping groove 14 until the first bolt is completely separated, the rotating disc 2 is enabled to lose the state of being fixed in position, then the rotating disc 2 is rotated according to actual requirements, so that the rotating disc 2 rotates at the top of the movable seat 1, so that the positions of the monitoring device 10 and the motor 7 are changed until the position which is convenient for a worker to operate is adjusted, and then the first bolt 12 is pushed downwards, so that the first bolt 12 is inserted into the first clamping groove 14 matched with the current position state, so that the rotating disc 2 is fixed on the moving seat 1.

Then, the second slider 4 is pushed inwards to move the second slider 4 inwards in the chute 31, then the second slider 4 moves to drive the moving structure 6, the motor 7 and the screw rod 8 to move synchronously until the second slider 4 moves to the middle of the chute 31, at the moment, the screw rod 8 is aligned with the communication hole 11, then the second bolt 13 which is closer to a worker is pushed inwards to make the second bolt 13 move inwards under stress, and the second bolt is inserted into a second clamping groove 5 formed in the outer side of the second slider 4, so that the current position of the second slider 4 is fixed, then the motor 7 is started, the screw rod 8 is driven to rotate through the rotation of the motor 7, and the handle is pushed downwards at the same time, the fixed plate is driven to move through the forced movement of the handle, and then the third slider 62 in the moving structure 6 is driven through the movement of the fixed plate, the third slide block 62 is forced to move downwards on the surface of the slide rod 61, and the third slide block 62 is moved to press the spring 63 to make the spring 63 elastically deformed, and at this time, the motor 7 and the screw 8 move downwards, and the screw 8 is inserted into the communication hole 11 until the ground is inserted for punching.

When its work of punching finishes, through loosening the promotion downwards to its handle, thereby it resets and motor 7 and hob 8 carry out the work of resetting to promote third slider 62 to make the surface of slide bar 61 go on the rebound through spring 63, second bolt 13 is extracted to the rethread, make its second bolt 13 break away from insert in second draw-in groove 5 can, thereby make second slider 4 lose by the state of rigidity, promote second slider 4 in the outside, make its second slider 4 reset, thereby make motor 7 and hob 8 reset can.

Then, the first sliding block 3 is pushed inwards to enable the first sliding block 3 to move inwards in the sliding groove 31, then the first sliding block 3 moves to drive the connecting frame 9 and the monitoring device 10 to move until the first sliding block 3 moves to the middle position of the sliding groove 31, the second bolt 13 is pushed inwards to enable the second bolt 13 to be inserted into a second clamping groove 5 formed in the outer side of the first sliding block 3 to fix the position of the first sliding block 3, and then the monitoring device 10 is used to enable the first sliding block 3 to enter a hole formed in the outer side of the first sliding block through the communication hole 11 to perform environment monitoring work of the position.

Compared with the related art, the device for monitoring the mine geological environment has the following beneficial effects:

through removing seat 1, rolling disc 2, first slider 3, spout 31, second slider 4, remove structure 6, motor 7, hob 8, link 9, monitoring devices 10, intercommunicating pore 11, first bolt 12, thereby mutually supporting between the first draw-in groove 14 isotructure can carry out quick and stable work of punching, and can control the degree of depth according to the needs of reality, moreover, the steam generator is simple in structure, and is convenient, thereby make entering into the work that monitoring devices 10 can be quick, thereby work efficiency is improved.

Second embodiment

Referring to fig. 3 and 4 in combination, based on the device for monitoring the mine geological environment provided by the first embodiment of the present application, the second embodiment of the present application provides another device for monitoring the mine geological environment. The second embodiment is only a preferred mode of the first embodiment, and the implementation of the second embodiment does not affect the implementation of the first embodiment alone.

Specifically, the difference that a device for monitoring of mine geological environment that the second embodiment of this application provided lies in, a device for monitoring of mine geological environment, quad slit 15 has been seted up at the top of hob 8, quad slit 15's inside is provided with plug 16, third draw-in groove 17 has all been seted up at the top of hob 8 both sides.

The shape of the insertion block 16 is matched with that of the square hole 15, so that the phenomenon that the work load of the clamping rod 19 is increased due to the fact that the clamping rod 19 is stressed due to insufficient friction force when the driving screw rod 8 rotates by the insertion block 16 can be avoided.

The two sides of the insertion block 16 are rotatably connected with bolts 20, nuts 21 are sleeved on the surfaces of the bolts 20, and clamping rods 19 are arranged on the inner sides of the nuts 21 and on the surfaces of the bolts.

And limiting structures 18 are arranged on two sides of the top of the insertion block 16, and the outer sides of the bottoms of the limiting structures 18 are fixedly connected with the tops of the clamping rods 19.

The limiting structure 18 comprises a sliding groove, the sliding groove is arranged on the outer side of the top of the insertion block 16, a sliding block is connected inside the sliding groove in a sliding mode, and the top of the sliding block is fixedly installed with the top of the clamping rod 19 through a connecting plate.

The working principle of the device for monitoring the mine geological environment provided by the utility model is as follows:

when the screw rod 8 needs to be disassembled, the bolts 20 at two sides of the insertion block 16 are respectively and sequentially rotated manually, the bolts 20 are rotated, the clamping rod 19 is fixedly connected with the nut 21 through the rotation of the bolts 20, the clamping rod 19 is limited through the limiting structure 18 through the rotation of the clamping rod 19, so that the nut 21 of the bolt 20 is driven to move outwards on the surface of the bolt 20 when the bolt 20 is rotated, the clamping rod 19 is driven to move through the movement of the nut 21, the sliding block in the limiting structure 18 is driven through the movement of the clamping rod 19 to move inside the sliding groove, the sliding block is gradually separated from the state inserted inside the third clamping groove 17 through the movement of the clamping rod 19 until the sliding block is completely separated, the fixed state between the insertion block 16 and the screw rod 8 is lost, and the screw rod 8 is pulled downwards, the screw rod 8 is forced to move downwards, so that the inserting block 16 is gradually separated from the state of being inserted in the square hole 15 until completely separated, and the dismounting work of the screw rod 8 is finished.

Compared with the related art, the device for monitoring the mine geological environment has the following beneficial effects:

thereby through mutually supporting between structures such as quad slit 15, grafting piece 16, third draw-in groove 17, limit structure 18, joint pole 19, bolt 20, nut 21 and install and dismantle its hob 8 that can be quick, and simple structure cost of manufacture is low to make hob 8 can dismantle after the work and maintain cleaning work.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (7)

1. An apparatus for mine geological environment monitoring, comprising: a movable seat;

the rotating disc is rotatably connected to the top of the moving seat, and communicating holes are formed in the rotating disc and the moving seat;

the sliding grooves are formed in the front side and the back side of the top of the rotating disc, a first sliding block and a second sliding block are connected to the two sides of the inner portion of each sliding groove in a sliding mode, a moving structure is fixedly installed on the top of each second sliding block, a motor is fixedly installed on the inner side of each moving structure through a fixing plate, and a spiral rod is fixedly installed at one end of an output shaft of the motor;

the connecting frame is fixedly installed at the top of the first sliding block, and a monitoring device is fixedly installed on the inner side of the top of the connecting frame;

the first clamping groove is formed in the top of the movable seat;

the first bolt is arranged at the top of the front face of the rotating disc.

2. The mine geological environment monitoring device as recited in claim 1, wherein a second slot is provided on the outer side of each of the first and second sliding blocks.

3. The device for mine geological environment monitoring according to claim 1, characterized in that the front and back of the top of the rotating disc and the outer side of the sliding groove are provided with a second bolt through a fixed seat.

4. The device for mine geological environment monitoring according to claim 1, characterized in that the moving structure comprises a slide bar, a third slide block is connected on the surface of the slide bar in a sliding manner, and a spring is arranged at the bottom of the third slide block and on the surface of the slide bar.

5. The device for monitoring the geological environment of the mine according to claim 1, wherein a square hole is formed in the top of the screw rod, an insertion block is arranged inside the square hole, and third clamping grooves are formed in the tops of two sides of the screw rod.

6. The device for monitoring the geological environment of the mine, as recited in claim 5, characterized in that bolts are rotatably connected to both sides of the insertion block, nuts are sleeved on the surfaces of the bolts, and clamping rods are arranged on the inner sides of the nuts and on the surfaces of the bolts.

7. A device for mine geological environment monitoring as defined in claim 6, wherein the top of the plugging block is provided with a limiting structure at two sides, and the outer side of the bottom of the limiting structure is fixedly connected with the top of the clamping rod.

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