CN219039031U - Prospecting device for geological environment monitoring - Google Patents

Abstract

The utility model provides an exploration device for geological environment monitoring. Including the shallow, the top of shallow is fixed with the truss, actuating mechanism is installed to the top of truss, installation component is installed to actuating mechanism's below, sampling component is installed to installation component's below, sampling component is including the top cap, the outer wall threaded connection of top cap has the pipeline, the inner wall of pipeline is fixed with the spacing ring, the upper surface hinged joint of spacing ring has the bottom. According to the prospecting device for geological environment monitoring, the sampling assembly is designed on the device, the oil cylinder controls the pipeline to descend to collide with loose soil, the bottom cover can be controlled to overturn unidirectionally during collision, sand and soil can enter the pipeline unidirectionally after overturning, and then the bottom cover overturns and the limiting ring is closed, so that a user can quickly take a large number of different patterns, and the prospecting accuracy of the device is improved.

Description

Prospecting device for geological environment monitoring

Technical Field

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

Background

Geological environments are primarily referred to as hard shells, i.e. rock circles, from the subsurface. Geological environments are the products of earth evolution. The rock is weathered under the action of solar energy, so that consolidated substances are released and participate in a geographic environment, and the consolidated substances participate in a geological cycle, namely a interstellar substance large cycle, and in the monitoring of the geological environment, the rock and a clay layer are firstly required to be subjected to exploration treatment.

Exploration is the direct observation of mineralization in rock outages or sediments. Modern exploration also includes the use of geologic, geophysical and geochemical tools to search for anomalies that may narrow the search. Once an anomaly is found and interpreted as a potential prospect, direct observation can be focused on this area.

The existing prospecting device for geological environment monitoring on the market exists in working use, patterns are saved in a drilling and detention mode when patterns in the clay layer are sampled by the traditional technology, and the prospecting effect is easily affected due to the fact that the patterns are detention by the technology.

Accordingly, it is desirable to provide an exploration device for geological environment monitoring that solves the above-mentioned problems.

Disclosure of Invention

The utility model provides an exploration device for geological environment monitoring, which solves the problems that the patterns are stored in a drilling and detention mode when the patterns in a clay layer are sampled by the traditional technology, and the exploration effect is easily affected by the inconvenient detention of all the patterns by the technology.

In order to solve the technical problems, the prospecting device for geological environment monitoring comprises a trolley, wherein a truss is fixed at the top of the trolley, a driving mechanism is installed above the truss, a mounting assembly is installed below the driving mechanism, a sampling assembly is installed below the mounting assembly, the sampling assembly comprises a top cover, a pipeline is connected with the outer wall of the top cover through threads, a limiting ring is fixed on the inner wall of the pipeline, and a bottom cover is hinged to the upper surface of the limiting ring.

Preferably, the top of shallow just is located the right side of truss and is fixed with the screening case, the inner wall of screening case is fixed with the sieve.

Preferably, the driving mechanism comprises a limiting plate fixed on the upper surface of the truss, an oil cylinder is fixedly arranged at the top of the limiting plate, a sliding rod is connected to the bottom end opening of the oil cylinder in a sliding mode, a mounting box is fixed at the bottom of the sliding rod, and a motor is fixedly arranged on the inner wall of the mounting box.

Preferably, the installation component includes fixed connection in the cutting ferrule of motor output shaft, the notch has been seted up to the outer wall of cutting ferrule, and the quantity of notch is two, the inside block of cutting ferrule has the draw-in lever, the top of draw-in lever is fixed with the kicking block.

Preferably, the output shaft of the motor is rotationally connected with the mounting box through a bearing, and the clamping rod and the clamping sleeve are of an adaptive conical structure.

Preferably, the upper surface of the top cover is fixedly connected with the bottom of the clamping rod, and the diameter of the bottom cover is slightly larger than the aperture of the limiting ring.

Preferably, the front end of the positioning bolt penetrates through the ball seat and extends to the outer wall of the ball head.

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

the device is designed with a sampling assembly, the oil cylinder controls the pipeline to descend to collide with loose soil, the bottom cover can be controlled to overturn unidirectionally during collision, sand and soil can enter the pipeline unidirectionally after overturning, and then the bottom cover overturns and is closed with the limiting ring, so that a user can quickly take a large number of different patterns, and the accuracy of device exploration is improved.

Drawings

FIG. 1 is a schematic view of a geological environment monitoring exploration apparatus according to a preferred embodiment of the present utility model;

FIG. 2 is a schematic cross-sectional view of the drive mechanism of FIG. 1;

FIG. 3 is a schematic view of the mounting assembly of FIG. 1 in a disassembled configuration;

fig. 4 is a schematic cross-sectional view of the sampling assembly of fig. 1.

Reference numerals in the drawings: 1. a cart; 2. truss; 3. a driving mechanism; 31. a limiting plate; 32. an oil cylinder; 33. a slide bar; 34. a mounting box; 35. a motor; 4. a mounting assembly; 41. a cutting sleeve; 42. a notch; 43. a clamping rod; 44. a top block; 5. a sampling assembly; 51. a top cover; 52. a pipe; 53. a limiting ring; 54. a bottom cover; 6. a screening box; 7. a sieve plate.

Detailed Description

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

Referring to fig. 1 to 4 in combination, fig. 1 is a schematic structural diagram of a preferred embodiment of an exploration device for geological environment monitoring according to the present utility model; FIG. 2 is a schematic cross-sectional view of the drive mechanism of FIG. 1; FIG. 3 is a schematic view of the mounting assembly of FIG. 1 in a disassembled configuration; fig. 4 is a schematic cross-sectional view of the sampling assembly of fig. 1. The utility model provides an exploration device for geological environment monitoring, includes shallow 1, and the top of shallow 1 is fixed with truss 2, and actuating mechanism 3 is installed to truss 2's top, and installation component 4 is installed to actuating mechanism 3's below, and sampling component 5 is installed to installation component 4's below, and sampling component 5 is including top cap 51, and the outer wall threaded connection of top cap 51 has pipeline 52, and the inner wall of pipeline 52 is fixed with spacing ring 53, and the upper surface hinged joint of spacing ring 53 has bottom 54.

The top of shallow 1 just is located truss 2's right side and is fixed with screening case 6, and screening case 6's inner wall is fixed with sieve 7.

The driving mechanism 3 comprises a limiting plate 31 fixed on the upper surface of the truss 2, an oil cylinder 32 is fixedly arranged at the top of the limiting plate 31, a sliding rod 33 is slidably connected to the bottom end opening of the oil cylinder 32, an installation box 34 is fixed to the bottom of the sliding rod 33, and a motor 35 is fixedly arranged on the inner wall of the installation box 34.

The installation component 4 includes fixed connection in the cutting ferrule 41 of motor 35 output shaft, and notch 42 has been seted up to the outer wall of cutting ferrule 41, and the quantity of notch 42 is two, and the inside block of cutting ferrule 41 has clamping lever 43, and the top of clamping lever 43 is fixed with kicking block 44.

The output shaft of the motor 35 is rotationally connected with the mounting box 34 through a bearing, the clamping rod 43 and the clamping sleeve 41 are in a conical structure in a matched mode, the oil cylinder 32 controls the sliding rod 33 to drive the mounting box 34 to control the drill bit rotating below to descend so as to rotationally loosen soil.

The upper surface of top cap 51 is fixed connection with the bottom of draw-in lever 43, and the diameter of bottom 54 slightly is greater than the aperture of spacing ring 53, and hydro-cylinder 32 control pipeline 52 descends and contradicts to the earth of relaxation, then steerable bottom 54 carries out one-way upset when contradicting, and the grit earth can one-way enter into pipeline 52 after the upset, and later bottom 54 upset is closed with spacing ring 53, and such design is convenient for the user quick to take a large amount of different patterns to the accuracy of device exploration has been improved.

The utility model provides a prospecting device for geological environment monitoring, which has the following working principle:

the first step: first the user needs to install the drill bit inside the ferrule 41 before exploring, and then the user activates the motor 35 to control the ferrule 41 so that the drill bit performs a rotational movement.

And a second step of: then, the user starts the oil cylinder 32 to control the sliding rod 33 to drive the installation box 34 to control the drill bit rotating below to descend so as to rotationally loosen soil.

And a third step of: after the mud is drilled, the user needs to insert the triangular iron into the notch 42 to knock so that the drill bit and the clamping sleeve 41 are separated, then the user inserts the clamping rod 43 into the clamping sleeve 41, then the motor 35 is closed, the oil cylinder 32 controls the pipeline 52 to descend to collide with loose soil, the bottom cover 54 can be controlled to overturn unidirectionally during collision, sand and soil can enter the pipeline 52 unidirectionally after overturning, and then the bottom cover 54 overturns and the limiting ring 53 are closed, so that the design is convenient for the user to quickly take a large number of different patterns, and the accuracy of device exploration is improved.

Fourth step: the user then rotates the pipe 52 and pours the pattern in the pipe 52 onto the screening box 6, the screen 7 screens the water and the earth sample, and the user performs geological exploration by the density of the earth sample and the type of ore.

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

the device is designed with the sampling assembly 5, the oil cylinder 32 controls the pipeline 52 to descend to collide with loose soil, the bottom cover 54 can be controlled to overturn unidirectionally during collision, sand and soil can enter the pipeline 52 unidirectionally after overturning, and then the bottom cover 54 overturns and is closed with the limiting ring 53, so that the device is convenient for users to quickly take a large number of different patterns, and the accuracy of device exploration 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 (6)

1. The utility model provides a geological environment monitoring is with exploration device, includes shallow, its characterized in that: the top of shallow is fixed with the truss, actuating mechanism is installed to the top of truss, installation component is installed to actuating mechanism's below, sampling component is installed to installation component's below, sampling component is including the top cap, the outer wall threaded connection of top cap has the pipeline, the inner wall of pipeline is fixed with the spacing ring, the upper surface hinged joint of spacing ring has the bottom.

2. The prospecting apparatus for geological environment monitoring according to claim 1, wherein a screening box is fixed on the top of the cart and on the right side of the truss, and a screen plate is fixed on the inner wall of the screening box.

3. The prospecting device for geological environment monitoring according to claim 2, wherein the driving mechanism comprises a limiting plate fixed on the upper surface of the truss, an oil cylinder is fixedly installed at the top of the limiting plate, a sliding rod is slidably connected to the bottom end opening of the oil cylinder, a mounting box is fixed at the bottom of the sliding rod, and a motor is fixedly installed on the inner wall of the mounting box.

4. The prospecting device for geological environment monitoring according to claim 3, wherein the mounting assembly comprises a clamping sleeve fixedly connected to the motor output shaft, the outer wall of the clamping sleeve is provided with two notches, clamping rods are clamped in the clamping sleeve, and a jacking block is fixed to the top of each clamping rod.

5. The prospecting apparatus for geological environment monitoring according to claim 4, wherein the output shaft of the motor is rotatably connected to the mounting box via a bearing, and the clamping rod and the clamping sleeve are in a tapered structure.

6. The prospecting apparatus for geological environment monitoring according to claim 5, wherein the top surface of the top cover is fixedly connected with the bottom of the clamping rod, and the diameter of the bottom cover is slightly larger than the aperture of the limiting ring.

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