CN219285412U - Geological environment monitoring device - Google Patents

Abstract

The utility model provides a geological environment monitoring device, comprising: a bottom plate; the fixed frame, fixed frame fixed mounting in the top of bottom plate, the top fixed mounting of the medial surface of fixed frame has driving motor, driving motor's output fixed mounting has the thread bush, the bottom threaded connection of the medial surface of thread bush has the threaded rod, the spacing groove has all been seted up to the both sides of threaded rod, the lateral surface of threaded rod is provided with the retainer plate, the both sides of the medial surface of retainer plate are all fixed mounting has the limiting plate, the one end sliding connection of limiting plate in the medial surface of spacing groove. According to the geological environment monitoring device, the structures such as the driving motor, the threaded sleeve, the threaded rod, the limiting groove, the fixed ring, the limiting plate, the connecting rod and the detection radar are matched with each other, so that the detection radar can be protected when the geological environment monitoring device is used, and damage to the detection radar caused when the geological environment monitoring device moves is avoided.

Description

Geological environment monitoring device

Technical Field

The utility model relates to the technical field of environment monitoring devices, in particular to a geological environment monitoring device.

Background

The ground penetrating radar, which is an advanced novel nondestructive testing technology, has the technical advantages of no damage, rapidness, accuracy, real-time imaging and traceability of the detection result, and is increasingly widely applied in the field of geological environment monitoring in recent years. The ground penetrating radar can be used for detecting various materials such as rock, soil and gravel, artificial materials such as concrete, bricks, asphalt and the like, and can also be used for determining the positions of metal or nonmetal pipelines, sewer, cables, cable pipelines, holes, foundation layers, steel bars in the concrete and other underground buried parts, detecting the depths and the thicknesses of different rock strata and detecting the local loosening and void of a soil layer and gradually forming underground holes under the action of water erosion.

As in the prior art patent application publication CN 209514079U, which is composed of a moving carrier, a case and a transceiver antenna device fixed on the moving carrier, and a host, a transmitter and a receiver fixed inside the case; the motion carrier comprises a supporting plate, a push-pull rod arranged on one side of the supporting plate and four damping wheel devices arranged at the bottom of the supporting plate; through setting up shock attenuation buffer layer and setting up shock attenuation wheel device in the casing mounting base upper surface of backup pad bottom of backup pad, realized effectual shock attenuation protection, prevent that mine geological environment monitoring device from jolting impaired, prolonged the life of device; the wiring groove is formed in the supporting plate, and the cable is arranged in the wiring groove, so that road barriers can be effectively prevented from hooking and damaging the cable during field operation; when encountering up-down abrupt slopes, the angle of the push-pull rod can be adjusted to a convenient push-pull position through the first rotating device, so that the use flexibility of the motion carrier is improved, the manpower is greatly saved, but the device is arranged outside the detection radar when not in use, and the detection radar is easily damaged due to collision.

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

Disclosure of Invention

The utility model provides a geological environment monitoring device, which solves the problem that a detection radar is arranged outside when moving and is easy to damage due to collision.

In order to solve the technical problems, the utility model provides a geological environment monitoring device, which comprises:

a bottom plate;

the fixing frame is fixedly arranged at the top of the bottom plate, the top of the inner side surface of the fixing frame is fixedly provided with a driving motor, the output end of the driving motor is fixedly provided with a threaded sleeve, the bottom of the inner side surface of the threaded sleeve is in threaded connection with a threaded rod, both sides of the threaded rod are provided with limit grooves, the outer side surface of the threaded rod is provided with a fixing ring, both sides of the inner side surface of the fixing ring are fixedly provided with limit plates, one end of each limit plate is slidably connected with the inner side surface of each limit groove, both sides of each fixing ring are fixedly provided with connecting rods, and one end of each connecting rod is fixedly arranged on the inner side surface of the fixing frame;

and the detection radar is fixedly arranged at the bottom of the threaded rod.

Preferably, a through hole is formed in the bottom of the bottom plate, a positioning hole is formed in one side of the inner side surface of the through hole, and a magnet is fixedly mounted on one side of the inner side surface of the positioning hole.

Preferably, the sliding cavity is formed in the other side of the inner side surface of the through hole, the sliding groove is formed in the top of the inner side surface of the sliding cavity, the baffle is connected to the inner side surface of the sliding cavity in a sliding mode, the movable plate is fixedly mounted at one end of the top of the baffle and is connected to the inner side surface of the sliding groove in a sliding mode, and the metal plate is fixedly mounted at one end of the movable plate.

Preferably, the rollers are fixedly arranged around the bottom of the bottom plate, and a push rod is fixedly arranged at one end of the top of the bottom plate.

Preferably, the two sides of the fixed frame are provided with heat dissipation holes, and the heat dissipation holes are arranged on one side of the driving motor.

Preferably, a sliding rod is slidably connected to the periphery of the top of the fixed frame, a buffer spring is sleeved on the outer side surface of the sliding rod, the buffer spring is arranged at the top of the fixed frame, and a detection device is mounted at the top of the sliding rod.

Preferably, both sides of bottom plate all fixed mounting have the curb plate, the inside fixed mounting of curb plate has the screwed collar, the medial surface threaded connection of screwed collar has the lead screw, the top fixed mounting of lead screw has the rotor plate, the bottom fixed mounting of lead screw has the ground screw.

Compared with the related art, the geological environment monitoring device provided by the utility model has the following beneficial effects:

the utility model provides a geological environment monitoring device which is matched with structures such as a driving motor, a threaded sleeve, a threaded rod, a limiting groove, a fixed ring, a limiting plate, a connecting rod, a detection radar and the like, and can protect the detection radar when in use, so that damage to the detection radar when moving is avoided.

Drawings

FIG. 1 is a schematic diagram of a geological environment monitoring device according to a first embodiment of the present utility model;

FIG. 2 is a schematic view of the internal structure shown in FIG. 1;

FIG. 3 is an enlarged schematic view of portion A shown in FIG. 2;

FIG. 4 is an enlarged schematic view of portion B shown in FIG. 2;

fig. 5 is a schematic structural diagram of a geological environment monitoring device according to a second embodiment of the present utility model.

Reference numerals in the drawings: 1. the device comprises a bottom plate, 11, a roller, 12, a push rod, 13, a through hole, 14, a positioning hole, 15, a magnet, 16, a sliding cavity, 17, a sliding groove, 18, a baffle, 19, a moving plate, 10, a metal plate, 2, a fixed frame, 21, a heat dissipation hole, 3, a detection device, 31, a mounting plate, 32, a sliding rod, 33, a buffer spring, 4, a driving motor, 41, a thread bush, 42, a threaded rod, 43, a limit groove, 44, a fixed ring, 45, a limit plate, 46, a connecting rod, 47, a detection radar, 5, a side plate, 51, a threaded ring, 52, a screw rod, 53, a rotating plate, 54 and a ground nail.

Description of the embodiments

The utility model will be further described with reference to the drawings and embodiments.

Examples

Referring to fig. 1, fig. 2, fig. 3 and fig. 4 in combination, fig. 1 is a schematic structural diagram of a first embodiment of a geological environment monitoring device according to the present utility model; FIG. 2 is a schematic view of the internal structure shown in FIG. 1; FIG. 3 is an enlarged schematic view of portion A shown in FIG. 2; fig. 4 is an enlarged schematic view of a portion B shown in fig. 2. A geological environment monitoring device, comprising: a base plate 1;

the fixing frame 2 is fixedly arranged at the top of the bottom plate 1, the driving motor 4 is fixedly arranged at the top of the inner side surface of the fixing frame 2, the threaded sleeve 41 is fixedly arranged at the output end of the driving motor 4, the bottom of the inner side surface of the threaded sleeve 41 is in threaded connection with the threaded rod 42, the two sides of the threaded rod 42 are provided with the limit grooves 43, the outer side surface of the threaded rod 42 is provided with the fixing rings 44, the two sides of the inner side surface of the fixing rings 44 are fixedly provided with the limit plates 45, one end of each limit plate 45 is in sliding connection with the inner side surface of each limit groove 43, the two sides of each fixing ring 44 are fixedly provided with the connecting rods 46, and one end of each connecting rod 46 is fixedly arranged on the inner side surface of the fixing frame 2;

a detection radar 47, the detection radar 47 is fixedly mounted at the bottom of the threaded rod 46.

The bottom of the bottom plate 1 is provided with a through hole 13, one side of the inner side surface of the through hole 13 is provided with a positioning hole 14, and one side of the inner side surface of the positioning hole 14 is fixedly provided with a magnet 15.

The sliding cavity 16 is formed in the other side of the inner side surface of the through hole 13, the sliding groove 17 is formed in the top of the inner side surface of the sliding cavity 16, the inner side surface of the sliding cavity 16 is slidably connected with the baffle 18, a movable plate 19 is fixedly mounted at one end of the top of the baffle 18, the movable plate 19 is slidably connected to the inner side surface of the sliding groove 17, and a metal plate 10 is fixedly mounted at one end of the movable plate 19.

Rollers 11 are fixedly mounted on the periphery of the bottom plate 1, and a push rod 12 is fixedly mounted at one end of the top of the bottom plate 1.

The two sides of the fixed frame 2 are provided with heat dissipation holes 21, and the heat dissipation holes 21 are arranged on one side of the driving motor 4.

The inside sliding connection all around at the top of fixed frame 2 has slide bar 32, the lateral surface cover of slide bar 32 is equipped with buffer spring 33, buffer spring 33 set up in the top of fixed frame 2, detection device 3 is installed at the top 䯊 of slide bar 32.

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

when the device is used, when a user moves the device, the user pushes the push rod 12 and then rolls on the ground through the roller 11 to move the device, the detection radar 47 is contained on the inner side surface of the fixed frame 2, the detection radar 47 can be protected at the moment, when the device is moved to a proper position and then needs to be detected, the user pulls the moving plate 19 to slide on the inner side surface of the sliding groove 17 and then drives the baffle 18 to move so as to move out of the inner side surface of the positioning hole 14, then the driving motor 4 is started, the threaded sleeve 41 is driven to rotate through the rotation of the driving motor 4, the threaded rod 42 rotates on the outer side surface of the threaded rod 42, the threaded rod 42 slides on the inner side surface of the limiting groove 43 through the limiting plate 45 to limit the threaded rod 42, and the threaded rod 42 can only move up and down.

Compared with the related art, the geological environment monitoring device provided by the utility model has the following beneficial effects:

through driving motor 4, thread bush 41, threaded rod 42, spacing groove 43, retainer plate 44, limiting plate 45, connecting rod 46, detection radar 47 isotructure mutually support, when using, can play the effect of protecting detection radar 47, avoid when removing, cause the damage to detection radar 47.

Examples

Referring to fig. 5 in combination, another geological environment monitoring device is provided according to a second embodiment of the present application. The second embodiment is merely a preferred manner of the first embodiment, and implementation of the second embodiment does not affect the implementation of the first embodiment alone.

Specifically, the second embodiment of the present application provides a geological environment monitoring device, and is characterized in that, a geological environment monitoring device, the both sides of bottom plate 1 are all fixed mounting has curb plate 5, the inside fixed mounting of curb plate 5 has screw circle 51, the medial surface threaded connection of screw circle 51 has lead screw 52, the top fixed mounting of lead screw 52 has rotating plate 53, the bottom fixed mounting of lead screw 52 has ground screw 54.

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

when in use, after the user moves the device to a proper position, the rotating plate 53 is rotated, the screw rod 52 is driven to rotate through the rotation of the rotating plate 53, so that the screw rod 52 is in threaded connection with the inner side surface of the threaded ring 51, then the screw rod moves downwards, the grounding nail 54 is driven to move downwards, the grounding nail 54 is inserted into the ground, and then the device is fixed.

Compared with the related art, the geological environment monitoring device provided by the utility model has the following beneficial effects:

the side plate 5, the thread ring 51, the screw rod 52, the rotating plate 53, the ground nail 54 and other structures are matched with each other, so that the device can be fixed and prevented from moving when being used, and the stability of the device is improved.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (7)

1. A geological environment monitoring device, comprising:

a bottom plate;

the fixing frame is fixedly arranged at the top of the bottom plate, the top of the inner side surface of the fixing frame is fixedly provided with a driving motor, the output end of the driving motor is fixedly provided with a threaded sleeve, the bottom of the inner side surface of the threaded sleeve is in threaded connection with a threaded rod, both sides of the threaded rod are provided with limit grooves, the outer side surface of the threaded rod is provided with a fixing ring, both sides of the inner side surface of the fixing ring are fixedly provided with limit plates, one end of each limit plate is slidably connected with the inner side surface of each limit groove, both sides of each fixing ring are fixedly provided with connecting rods, and one end of each connecting rod is fixedly arranged on the inner side surface of the fixing frame;

and the detection radar is fixedly arranged at the bottom of the threaded rod.

2. The geological environment monitoring device according to claim 1, wherein a through hole is formed in the bottom of the bottom plate, a positioning hole is formed in one side of the inner side surface of the through hole, and a magnet is fixedly mounted on one side of the inner side surface of the positioning hole.

3. The geological environment monitoring device according to claim 2, wherein a sliding cavity is formed in the other side of the inner side surface of the through hole, a sliding groove is formed in the top of the inner side surface of the sliding cavity, a baffle is slidably connected to the inner side surface of the sliding cavity, a movable plate is fixedly mounted at one end of the top of the baffle, the movable plate is slidably connected to the inner side surface of the sliding groove, and a metal plate is fixedly mounted at one end of the movable plate.

4. A geological environment monitoring device according to claim 3, wherein rollers are fixedly mounted on the periphery of the bottom of the base plate, and a push rod is fixedly mounted at one end of the top of the base plate.

5. The geological environment monitoring device of claim 4, wherein the two sides of the fixed frame are provided with heat dissipation holes, and the heat dissipation holes are arranged on one side of the driving motor.

6. The geological environment monitoring device according to claim 5, wherein a sliding rod is slidably connected to the periphery of the top of the fixed frame, a buffer spring is sleeved on the outer side surface of the sliding rod, the buffer spring is arranged at the top of the fixed frame, and a detection device is mounted on the top 䯊 of the sliding rod.

7. The geological environment monitoring device according to claim 6, wherein side plates are fixedly mounted on two sides of the bottom plate, a thread ring is fixedly mounted in the side plates, a screw rod is connected to the inner side face of the thread ring in a threaded mode, a rotating plate is fixedly mounted on the top of the screw rod, and ground nails are fixedly mounted on the bottom of the screw rod.

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