CN215932174U

CN215932174U - Geological remote sensing detection device

Info

Publication number: CN215932174U
Application number: CN202122121097.XU
Authority: CN
Inventors: 任国强
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-09-03
Filing date: 2021-09-03
Publication date: 2022-03-01
Anticipated expiration: 2031-09-03

Abstract

The utility model discloses a geological remote sensing detection device, which comprises a detection box assembly, wherein the detection box assembly is internally provided with: the telescopic detection assembly can be accommodated in the detection box assembly and comprises an accommodating top cover, a telescopic rod assembly is arranged at the bottom of the accommodating top cover, and a collecting roller assembly capable of keeping axial movement is arranged at the bottom of the telescopic rod assembly; collect the roller components, collect roller components and include the gyro wheel, the joint groove has been seted up between two parties to the inside of gyro wheel, collect roller components can keep being located telescopic link assembly's inside. The geological remote sensing detection device provided by the utility model can collect soil in the collecting tank through the collecting tank and the collecting plate, so as to bring further detection; can control flexible detection subassembly through display screen, flexible remote lever and control button, observe the ground bottom situation, avoid missing key information.

Description

Geological remote sensing detection device

Technical Field

The utility model relates to the technical field of geological exploration, in particular to a geological remote sensing detection device.

Background

Since geological exploration allows prediction of earthquakes, exploration of minerals and observation of the development of the earth's evolution, but geological exploration is also very dangerous, it is carried out to use geological remote sensing in order to avoid casualties.

Patent CN213120586U, a geological remote sensing detection device, including surveying plectane and surveying the main part, its characterized in that: the upper part of the detection circular plate is fixedly connected with a rotating block, the rotating block is rotatably connected with a connecting block, two corresponding sides of the connecting block are fixedly connected with mounting pieces, a bottom piece is fixedly connected onto the mounting pieces through bolts, the upper part of the bottom piece is fixedly connected with a telescopic plate, a section of meshed teeth are arranged on the telescopic plate, two sides of the telescopic plate are fixedly connected with sliding strips, a shell is arranged in a manner of being matched with the telescopic plate, a sliding cavity is arranged in the shell, a sliding chute is fixedly connected in the sliding cavity and is matched with the sliding strips, the sliding strips are slidably connected in the sliding chute, a round hole is arranged at the upper part of the shell and is communicated with the sliding cavity, a limiting hole is arranged at one end, close to the sliding cavity, of the round hole, a plurality of groups of limiting teeth are fixedly connected onto the inner wall of the limiting hole, and a regulation and control assembly is arranged in the round hole, the regulation and control subassembly includes pivot, regulation and control gear and spacing tooth, the pivot is passed the round hole, the pivot is located sliding chamber inside's end fixedly connected with the regulation and control gear is located the regulation and control gear with it has to fix between the spacing hole spacing gear, the regulation and control gear with rodent meshing on the expansion plate is connected spacing gear with spacing hole and spacing tooth phase-match, the pivot is located the outside end fixedly connected with of shell rotates the handle, shell one side is provided with the mounting groove, the main part shell is installed in the dress inslot closing, it is in to survey the main part fixed mounting in the main part shell, be located on the shell the bottom fixedly connected with handle of main part shell. The utility model has the advantages of adjustable working length and convenient carrying, and is mainly used for geological detection.

In the actual operation process, the geological remote sensing detection device cannot observe the geology of the ground more intuitively and cannot be actively operated; the geological remote sensing detection cannot sample the soil on the side wall of the ground bottom, so that further observation and detection are carried out.

Accordingly, there is a need for improvement in the above-mentioned problems of the prior art.

SUMMERY OF THE UTILITY MODEL

In view of the above problems in the prior art, an aspect of the present invention is to provide a remote sensing device for geology to solve the problem that the condition of the soil in the ground cannot be observed more intuitively, and the remote sensing device can conveniently and quickly control a telescopic detection assembly to perform geology detection through a display screen, a telescopic remote rod and a control button; and can take a sample bottom soil through collecting wheel components, further detect.

In order to achieve the above object, the present invention provides a remote sensing device for geological features, which comprises a probe box assembly, wherein the probe box assembly is internally provided with:

the telescopic detection assembly can be accommodated in the detection box assembly and comprises an accommodating top cover, a telescopic rod assembly is arranged at the bottom of the accommodating top cover, and a collecting roller assembly capable of keeping axial movement is arranged at the bottom of the telescopic rod assembly;

collect the roller components, collect roller components and include the gyro wheel, the joint groove has been seted up between two parties to the inside of gyro wheel, collect roller components can keep being located telescopic link assembly's inside.

Preferably, the telescopic rod assembly comprises a plurality of telescopic rods, an inner groove is formed in each telescopic rod, the plurality of telescopic rods can be sequentially clamped in the inner groove, and a slotted hole communicated with each other is formed in the middle of the top of each telescopic rod.

Preferably, the telescopic rod assembly is internally connected with a telescopic cable, the telescopic cable is connected to a telescopic rod at the bottommost part of the telescopic rod assembly, and an ultrasonic camera is fixed at the bottom of the telescopic rod assembly.

Preferably, the telescopic rod at the bottommost part of the telescopic rod component is internally provided with a roller groove, and the top of the roller groove is provided with connecting rods distributed in an array manner.

Preferably, the clamping groove can be clamped on the outer side wall of the telescopic cable, clamping rods are fixed on the outer walls of two opposite sides of the roller, a cross beam is arranged inside the two clamping rods in a connected mode, a spring is fixed in the middle of the top of the cross beam, the top end, far away from one side of the cross beam, of the spring is connected to the telescopic rod, and the spring is assembled to limit the roller to keep axial movement.

Preferably, a collecting groove is formed in the roller, a collecting plate extending to the outer wall of the roller is arranged in the collecting groove, a connecting groove is formed in the top end, away from one side of the roller, of the clamping rod, and the connecting groove can be clamped on the connecting rod.

Preferably, the detection box assembly comprises a box shell, a motor is arranged in the box shell, a containing groove is formed in the outer side wall, far away from one side of the motor, of the box shell, a hinge is fixed at the top end of the containing groove, and the hinge is assembled to drive the telescopic detection assembly to keep axial movement.

Preferably, the outer wall of one side of the box body shell is provided with a display screen, and the bottom of the display screen is provided with a telescopic remote rod and a control button.

Advantageous effects

Compared with the prior art, the geological remote sensing detection device provided by the utility model has the following beneficial effects:

according to the utility model, the telescopic detection assembly can be controlled through the display screen, the telescopic remote rod and the control button, the ground condition can be observed more intuitively, and the missing of key information is avoided.

The collecting groove and the collecting plate of the collecting roller assembly can collect soil on the side wall and clamp the soil in the collecting groove, so that further detection is carried out.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to the drawings.

FIG. 1 is a schematic structural diagram of a geological remote sensing device according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a cross section of a geological remote sensing device provided by an embodiment of the utility model;

FIG. 3 is a schematic diagram of a probe box assembly according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a telescopic probe assembly according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a collecting roller assembly according to an embodiment of the present invention.

The main reference numbers:

1. a probe box assembly; 2. a telescopic detection assembly; 3. collecting roller assemblies; 101. a case body shell; 102. A motor; 103. a display screen; 104. a telescopic remote lever; 105. a control button; 106. a receiving groove; 107. a hinge; 201. a storage top cover; 202. a telescopic rod assembly; 203. an inner tank; 204. a slot; 205. an ultrasonic camera; 206. a retractable cable; 207. a spring; 208. a roller groove; 209. a connecting rod; 210. a telescopic rod; 301. a roller; 302. a clamping and connecting rod; 303. a clamping groove; 304. collecting tank; 305. a cross beam; 306. a collection plate; 307. and connecting the grooves.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

As shown in fig. 1-5, a remote sensing device for geological features comprises a probe box assembly 1, wherein:

the telescopic detection assembly 2 is accommodated in the detection box assembly 1, the telescopic detection assembly 2 comprises an accommodating top cover 201, a telescopic rod assembly 202 is arranged at the bottom of the accommodating top cover 201, and a collecting roller assembly 3 capable of keeping axial movement is arranged at the bottom of the telescopic rod assembly 202;

collect roller assembly 3, collect roller assembly 3 and include gyro wheel 301, the joint groove 303 has been seted up between two parties to the inside of gyro wheel 301, collects roller assembly 3 and can keep being located telescopic link assembly 202's inside.

The geological remote sensing detection device mainly aims to control the telescopic detection assembly 2 through the display screen 103, the telescopic remote rod 104 and the control button 105, observe the ground bottom condition more intuitively and avoid missing key information; soil from the side walls is collected and caught within collection trough 304 by collection trough 304 and collection plate 306 of collection roller assembly 3, thereby allowing further testing.

As shown in fig. 1, 2 and 4, the telescopic rod assembly 202 includes a plurality of telescopic rods 210, an inner groove 203 is formed inside the telescopic rod 210, the plurality of telescopic rods 210 can be sequentially sleeved inside the inner groove 203 to achieve the telescopic effect, and a through hole 204 is formed in the middle of the top of the telescopic rod 210.

The internally connected with of telescopic rod subassembly 202 has flexible cable 206, and flexible cable 206 connects in telescopic rod subassembly 202's bottom, and flexible cable 206 can follow telescopic rod subassembly 202 and stretch out and draw back and accomodate, and telescopic rod subassembly 202's bottom is fixed with ultrasonic camera 205, can carry out the dual detection of ultrasonic wave and make a video recording.

The inside of the telescopic rod 210 at the bottommost part of the telescopic rod assembly 202 is provided with a roller groove 208 communicated with the outer wall, and the top of the roller groove 208 is provided with connecting rods 209 distributed in an array for clamping and connecting the collecting roller assemblies 3.

As can be seen from fig. 1 and 5, the clamping groove 303 can clamp the outer side wall of the retractable cable 206, so that the roller 301 is accommodated in the retractable rod 210, the clamping rods 302 are fixed on the outer walls of two opposite sides of the roller 301, the cross beam 305 is connected between the two clamping rods 302, the spring 207 is fixed in the center of the top of the cross beam 305, the other end of the spring 207 is fixed on the retractable rod 210, and the roller 301 has an external ejection acting force.

The collecting groove 304 is formed in the roller 301, the collecting plate 306 extending to the outer wall of the roller is arranged in the collecting groove 304, the collecting plate 306 is used for scraping and rubbing the side wall of soil through axial rotation of the roller 301, a soil sample is collected in the collecting groove 304, the connecting groove 307 is formed in the top end of the clamping rod 302, which is far away from one side of the roller 301, the connecting groove 307 is clamped to the connecting rod 209, and the roller 301 can keep axial movement.

As can be seen from fig. 1, 2 and 3, the probe box assembly 1 includes a box housing 101, a motor 102 is disposed inside the box housing 101, a receiving groove 106 is disposed on a side of the box housing 101 away from the motor 102, the receiving groove 106 enables the telescopic probe assembly 2 to be received therein, a hinge 107 is fixed to a top end of the receiving groove 106, and the hinge 107 is used for enabling the telescopic probe assembly 2 to keep axial movement.

The outer wall of one side of the box body shell 101 is provided with a display screen 103, and a telescopic remote rod 104 and a control button 105 are fixed at the bottom of the display screen 103 and used for controlling the telescopic detection assembly 2 to stretch and close and an ultrasonic camera 205 to open and close.

The working principle is as follows: firstly, placing a detection box assembly 1 on one side of a detected land, and opening a telescopic detection assembly 2 through a hinge 107;

telescopic rod assembly 202 is telescopic through telescopic remote rod 104 to enable roller 301 to be ejected outwards, telescopic rod assembly 202 is extended into the detected cave, and roller 301 slides along the inner wall of soil;

the ultrasonic camera 205 is turned on through the control button 105, observation can be carried out through the display screen 103, the collection plate 306 is enabled to scrape and rub the inner wall of the soil through rolling of the roller 301, and the soil is collected into the collection groove 304;

after exploration, through flexible remote lever 104, make flexible detection subassembly 2 shrink and withdraw, make gyro wheel 301 accomodate in the inside of telescopic link 210, leave the exploration cave after flexible rod subassembly 202, take out the soil sample in the gyro wheel 301 and carry out further exploration, through hinge 107, make flexible detection subassembly 2 accomodate in the inside of accomodating groove 106.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the utility model.

Claims

1. A remote geological sensing detection device comprises a detection box assembly (1), and is characterized in that the detection box assembly (1) is internally provided with:

the telescopic detection assembly (2) can be accommodated in the detection box assembly (1), the telescopic detection assembly (2) comprises an accommodating top cover (201), a telescopic rod assembly (202) is arranged at the bottom of the accommodating top cover (201), and a collecting roller assembly (3) capable of keeping axial movement is arranged at the bottom of the telescopic rod assembly (202);

collect roller assembly (3), collect roller assembly (3) including gyro wheel (301), joint groove (303) have been seted up in the centre to the inside of gyro wheel (301), collect roller assembly (3) can keep being located telescopic link assembly (202) inside.

2. The remote geological sensing detection device according to claim 1, characterized in that the telescopic rod assembly (202) comprises a plurality of telescopic rods (210), an inner groove (203) is formed inside each telescopic rod (210), the plurality of telescopic rods (210) can be sequentially clamped inside the inner groove (203), and a through hole (204) is formed in the center of the top of each telescopic rod (210).

3. The remote geological sensing device as claimed in claim 2, characterized in that a telescopic cable (206) is connected inside the telescopic rod assembly (202), the telescopic cable (206) is connected to the bottommost telescopic rod (210) of the telescopic rod assembly (202), and an ultrasonic camera (205) is fixed at the bottom of the telescopic rod assembly (202).

4. The remote geological sensing detection device according to claim 3, characterized in that a roller groove (208) is formed inside a telescopic rod (210) at the bottommost part of the telescopic rod assembly (202), and connecting rods (209) distributed in an array are arranged at the top of the roller groove (208).

5. The remote geological sensing device as claimed in claim 3, wherein the clamping groove (303) can be clamped on the outer side wall of the telescopic cable (206), clamping rods (302) are fixed on the outer walls of two opposite sides of the roller (301), a cross beam (305) is arranged inside the two clamping rods (302), a spring (207) is fixed in the center of the top of the cross beam (305), the top end of the spring (207) far away from one side of the cross beam (305) is connected to the telescopic rod (210), and the spring (207) is assembled to limit the roller (301) to keep axial movement.

6. The remote geological sensing detection device according to claim 5, characterized in that a collecting groove (304) is formed inside the roller (301), a collecting plate (306) extending to the outer wall of the roller (301) is arranged inside the collecting groove (304), a connecting groove (307) is formed at the top end of one side of the clamping rod (302) far away from the roller (301), and the connecting groove (307) can be clamped to the connecting rod (209).

7. The remote geological sensing detection device according to claim 1, wherein the detection box assembly (1) comprises a box body shell (101), a motor (102) is arranged inside the box body shell (101), a containing groove (106) is formed in the outer side wall of one side, away from the motor (102), of the box body shell (101), a hinge (107) is fixed at the top end of the containing groove (106), and the hinge (107) is assembled to drive the telescopic detection assembly (2) to keep axial movement.

8. The remote sensing device for geological exploration, according to claim 7, characterized in that a display screen (103) is arranged on the outer wall of one side of the box body casing (101), and a telescopic remote rod (104) and a control button (105) are arranged at the bottom of the display screen (103).