CN117907024A - Geothermal detecting device capable of conducting multidirectional detection - Google Patents

Abstract

The invention provides a geothermal detecting device capable of detecting multiple directions, and mainly relates to the field of geothermal detecting equipment. The utility model provides a geothermal detection device that can diversified detects, includes locating support, sampling device, the locating support includes the main shaft pole, main shaft pole bottom fixed mounting fixing base, slidable mounting sliding seat on the main shaft pole, movable mounting link assembly on fixing base and the sliding seat, the link assembly outer end rotates the installation locating sleeve, movable mounting sampling device in the locating sleeve, sampling device includes the sample drilling rod, inside movable mounting sample inner tube of sample drilling rod, a plurality of sampling windows have been seted up on the sample drilling rod. The invention has the beneficial effects that: according to the invention, multipoint omnidirectional soil sampling can be carried out through a brand-new structural design, so that the efficiency of soil sampling work can be greatly improved, the representativeness of collected soil can be improved through the multipoint omnidirectional sampling, and the reliability of detection data is further improved.

Description

Geothermal detecting device capable of conducting multidirectional detection

Technical Field

The invention mainly relates to the field of geothermal detection equipment, in particular to a geothermal detection device capable of detecting in multiple directions.

Background

With the continuous development of the economic level of China, the improvement of science and technology is more focused on clean energy heating, geothermal energy is stored underground, the geothermal energy is natural thermal energy extracted from the crust, the energy comes from lava in the earth and exists in a thermal form and is not influenced by climatic conditions, the geothermal energy is converted into heat energy which can be used for life and industry through geothermal equipment, and the underground mineral is required to be acquired when the geothermal energy is detected due to uneven distribution and great acquisition difficulty, so that the content of the underground mineral is analyzed.

There are various targets for geothermal exploration, such as groundwater, soil, rock, etc. The traditional geological equipment for detecting the geothermal energy is inconvenient to sample the soil in different directions in the soil, the randomness of sampling is large, the collected data is easy to influence, the representativeness of the detection result is to be improved, and the efficiency of the soil geothermal energy detection work is also unfavorable to be improved.

Therefore, there is a need to provide a new geothermal detecting device capable of detecting multiple directions to solve the above technical problems.

Disclosure of Invention

In order to solve the defects in the prior art, the invention provides the geothermal detection device capable of multi-azimuth detection, which can carry out multi-point all-round soil sampling through a brand-new structural design, can greatly improve the efficiency of soil sampling work, can further improve the representativeness of collected soil through the multi-point all-round sampling, and further improve the reliability of detection data.

The invention aims to achieve the aim, and the aim is achieved by the following technical scheme:

The utility model provides a geothermal detection device that can diversely detect, includes locating support, sampling device, the locating support includes the main shaft pole, main shaft pole bottom fixed mounting fixing base, slidable mounting sliding seat on the main shaft pole, movable mounting connecting rod assembly on fixing base and the sliding seat, connecting rod assembly outer end rotates the installation locating sleeve, movable mounting sampling device in the locating sleeve, sampling device includes the sample drilling rod, the inside movable mounting sample inner tube of sample drilling rod, a plurality of sampling windows have been seted up on the sample drilling rod, sampling window one end rotates the installation and turns over the board, it sets up the sand grip to turn over the board outer end, a plurality of storage bins have been seted up in the sample inner tube, the storage bin opening suits with the sampling window.

The connecting rod assembly comprises a long rod and a short rod, wherein one end of the long rod is rotationally connected with the fixed seat, a sliding groove is formed in the middle of the long rod, one end of the short rod is rotationally connected with the sliding seat, one end of the short rod, far away from the sliding seat, is slidably mounted in the sliding groove, and the outer end of the long rod is rotationally connected with the positioning sleeve.

The sliding seat is fixedly connected with a plurality of L-shaped rods, and the upper ends of the L-shaped rods are connected with an operation ring.

The device comprises a sampling window, a rotating shaft is arranged on one side of the turning plate, the turning plate is rotatably arranged in the sampling window through the rotating shaft, a tip is arranged at one end, far away from the rotating shaft, of the turning plate, and a closed end corresponding to the tip is arranged on the sampling window.

The top end of the main shaft rod is fixedly connected with a hand ring.

The short rod is provided with a groove, and the groove is adapted to the rotation connection part of the long rod and the positioning sleeve.

The outside of sample drilling rod sets up the soil auger, sample drilling rod upper end sets up the public head of drive joint.

The utility model discloses a sampling drill pipe, including sampling inner tube top, sampling inner tube top sets up the mark transversal line, sampling inner tube top is provided with U type handle, the inside mark longitudinal line that is provided with of sampling drill pipe.

Compared with the prior art, the invention has the beneficial effects that:

According to the invention, the multi-point all-dimensional soil sampling can be carried out through the structures of the positioning bracket and the sampling device, the positioning bracket can position, can conveniently store the self structure and the sampling device, is convenient to carry, use and operate, can greatly improve the efficiency of soil sampling work, and can collect samples at different depths and different orientations in the sample taking hole through the sampling device, so that the sample data is more accurate and representative.

Drawings

FIG. 1 is a schematic view of the present invention in its stowed configuration;

FIG. 2 is a schematic view of the structure of the present invention in use;

FIG. 3 is a schematic diagram of a sampling device according to the present invention;

FIG. 4 is a schematic view of the structure of the sampling drill rod of the present invention;

FIG. 5 is a schematic view of a sampling inner barrel according to the present invention;

FIG. 6 is a schematic view of the structure of the turning plate of the present invention;

fig. 7 is a schematic view of the driving device of the present invention in use.

The reference numbers shown in the drawings: 1. a positioning bracket; 2. a sampling device; 3. a driving device; 11. a main shaft lever; 12. a fixing seat; 13. a sliding seat; 14. a connecting rod assembly; 15. positioning a sleeve; 21. sampling a drill rod; 22. sampling an inner cylinder; 110. a hand ring; 210. sampling window; 211. turning plate; 212. a convex strip; 213. drilling a soil spiral; 214. driving the male connector; 215. marking a longitudinal line; 220. a storage bin; 221. marking a transverse line; 222. u-shaped handles; 141. a long rod; 142. a short bar; 1410. a chute; 1420. a groove; 131. an L-shaped rod; 132. an operating ring; 2111. a rotating shaft; 2112. a tip; 2100. a closed end.

Detailed Description

The application will be further described with reference to the accompanying drawings and specific embodiments. It is to be understood that these examples are illustrative of the present application and are not intended to limit the scope of the present application. Further, it will be understood that various changes and modifications may be made by those skilled in the art after reading the teachings of the application, and equivalents thereof fall within the scope of the application as defined by the claims.

Referring to fig. 1-7, a geothermal detecting device capable of detecting multiple directions comprises a positioning bracket 1 and a sampling device 2, wherein the positioning bracket 1 comprises a main shaft rod 11, a fixed seat 12 is fixedly arranged at the bottom of the main shaft rod 11, a sliding seat 13 is slidably arranged on the main shaft rod 11, a connecting rod assembly 14 is movably arranged on the fixed seat 12 and the sliding seat 13, a positioning sleeve 15 is rotatably arranged at the outer end of the connecting rod assembly 14, the sampling device 2 is movably arranged in the positioning sleeve 15, the sampling device 2 comprises a sampling drill rod 21, a sampling inner barrel 22 is movably arranged in the sampling drill rod 21, a plurality of sampling windows 210 are arranged on the sampling drill rod 21, a turning plate 211 is rotatably arranged at one end of the sampling window 210, a raised strip 212 is arranged at the outer end of the turning plate 211, a plurality of storage bins 220 are arranged in the sampling inner barrel 22, and the openings of the storage bins 220 are matched with the sampling windows 210; the side of the protruding strip 212, which is close to the rotating shaft 2111 of the turning plate 211, is a cambered surface, so that the turning plate 211 can be kept in a closed state by a relatively small acting force when the sampling drill rod 21 is drilled into the soil, and the side of the protruding strip 212, which is far away from the turning plate 211, is a plane, so that the sampling drill rod 21 has a relatively large acting force when rotating in the soil in the opposite direction to the drilling process, and the turning plate 211 can be opened and abutted against the limiting end of the sampling window 210.

The connecting rod assembly 14 comprises a long rod 141 and a short rod 142, one end of the long rod 141 is rotatably connected with the fixed seat 12, a sliding groove 1410 is formed in the middle of the long rod 141, one end of the short rod 142 is rotatably connected with the sliding seat 13, one end of the short rod 142, which is far away from the sliding seat 13, is slidably mounted in the sliding groove 1410, and the outer end of the long rod 141 is rotatably connected with the positioning sleeve 15.

The sliding seat 13 is fixedly connected with a plurality of L-shaped rods 131, and the upper ends of the L-shaped rods 131 are fixedly connected with an operation ring 132; the operating ring 132 facilitates lifting the slide seat 13 upwards, and the positioning sleeve 15 and the sampling device 2 are retracted by the link assembly 14.

A rotating shaft 2111 is arranged at one side of the turning plate 211, the turning plate 211 is rotatably arranged in the sampling window 210 through the rotating shaft 2111, a tip 2112 is arranged at one end of the turning plate 211 far away from the rotating shaft 2111, and a closed end 2100 corresponding to the tip 2112 is arranged on the sampling window 210; the side of the sampling window 210 far from the closed end 2100 is provided with a limiting end, and the limiting end can limit the opening angle of the turning plate 211; the tip 2112 facilitates cutting the soil and guiding the soil through the sampling window 210 into the storage bin 220.

The top end of the main shaft rod 11 is fixedly connected with a hand ring 110, and the hand ring 110 is convenient for taking the device.

The short rod 142 is provided with a groove 1420, and the groove 1420 is adapted to the rotation connection position of the long rod 141 and the positioning sleeve 15.

The outside of the sampling drill rod 21 is provided with a soil drilling screw 213, and the upper end of the sampling drill rod 21 is provided with a driving joint male head 214.

The top of the sampling inner cylinder 22 is provided with a marking transverse line 221, the top of the sampling inner cylinder 22 is provided with a U-shaped handle 222, and the inside of the sampling drill rod 21 is provided with a marking longitudinal line 215; the marker lines are used for positive alignment when the sampling inner barrel 22 is installed into the sampling drill pipe 21, enabling the sampling window 210 to be aligned with the opening of the storage bin 220 in the sampling inner barrel 22.

The driving device 3 comprises a machine main body, an operation handle is arranged on one side of the machine main body, a driving motor and a speed reducing mechanism are arranged in the machine main body, the output end of the speed reducing mechanism is connected with an output shaft, the bottom of the output shaft is fixedly connected with a driving joint female head, and a driving joint male head 214 is adapted to the driving joint female head.

The utility model discloses a main shaft rod 11, including main shaft rod 11, main shaft rod 11 top movable mounting has the fixed pin, the pin hole seat has been seted up on main shaft rod 11 top and the sliding seat 13, the pin hole has been seted up to main shaft rod 11 side, will fix the pin and prevent losing in the pin hole seat at main shaft rod 11 top when the device uses, when the device was packed up, sliding seat 13 risees the highest position, pin hole seat on the sliding seat 13 aligns with the pin hole of main shaft rod 11 side, inserts the fixed pin and fixes sliding seat 13 position, is convenient for accomodate.

The outside of sampling inner tube 22 is provided with scrapes the ring, scrapes the ring and can prevent that soil from dropping into sampling drilling rod 21 when taking out sampling inner tube 22, and sampling drilling rod 21 tip is provided with the exhaust hole, makes the installation that sampling inner tube 22 can be smooth and easy into sampling drilling rod 21.

A number of said sampling windows 210 are helically distributed outside the position of the sampling drill rod 21.

The inner diameter of the positioning sleeve 15 is slightly larger than that of the sampling drill rod 21 and the earth-boring screw 213.

When the device is used, the portable ring 110 is used for taking the device to the position to be sampled and detected, firstly, the soil surface layer is cleaned, the sampling device 2 is taken out of the positioning sleeve 15, the fixing pin is taken down and placed into a pin hole of the main shaft rod 11, the sliding seat 13 is slowly lowered through the operating ring 132, the connecting rod assembly 14 pushes the positioning sleeve 15 outwards to be close to the level with the fixing seat 12, the positioning bracket 1 is placed on the soil to be sampled, the sampling device 2 is inserted into the soil through the positioning sleeve 15 (if the soil is harder, holes are needed to be punched in the soil in advance), the driving device 3 is used for driving the sampling device 2 to drill into the soil, the soil drilling screw 213 continuously drills out the soil hole, and the acting force between the turning plate 211 and the soil on the sampling drill rod 21 in the soil drilling process keeps the turning plate 211 in a closed state all the time; after a sufficient depth is reached, the sampling drill rod 21 is reversely rotated, soil in a drilled hole is stripped downwards by a soil drilling screw 213 outside the reversely rotated sampling drill rod 21, the turnover plate 211 is opened to a maximum state by the interaction force of the soil, the convex strips 212 and the turnover plate 211, along with the reverse rotation of the sampling drill rod 21, the opened turnover plate 211 continuously collects the soil into a storage bin 220 of the sampling inner barrel 22 through a sampling window 210, a plurality of sampling devices 2 are sequentially taken out after the sampling is completed according to the process, the sampling inner barrel 22 and the sampling drill rod 21 are rotated to ensure that the sampling window 210 and the opening of the storage bin 220 are distributed in a staggered manner, and the collected soil can be stably stored; when the collected soil needs to be detected, the sampling inner cylinder 22 is taken out, horizontally arranged and rotated to pour out the soil; after the collection, the connecting rod assembly 14 is retracted into the positioning sleeve 15 by pulling the operating ring 132, the sliding seat 13 is fixed by using the fixing pin, and the sampling device 2 is placed into the positioning sleeve 15 to be stored.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (8)

1. The utility model provides a geothermal detection device that can diversified detects, includes locating support (1), sampling device (2), its characterized in that: the positioning support (1) comprises a main shaft rod (11), a fixed mounting seat (12) is fixedly arranged at the bottom of the main shaft rod (11), a sliding seat (13) is mounted on the main shaft rod (11) in a sliding mode, a connecting rod assembly (14) is movably mounted on the fixed seat (12) and the sliding seat (13), a positioning sleeve (15) is mounted at the outer end of the connecting rod assembly (14) in a rotating mode, a sampling device (2) is movably mounted in the positioning sleeve (15), the sampling device (2) comprises a sampling drill rod (21), a sampling inner cylinder (22) is movably mounted in the sampling drill rod (21), a plurality of sampling windows (210) are formed in the sampling drill rod (21), a turning plate (211) is rotatably mounted at one end of the sampling windows (210), a convex strip (212) is arranged at the outer end of the turning plate (211), a plurality of storage bins (220) are formed in the sampling inner cylinder (22), and the openings of the storage bins (220) are matched with the sampling windows (210).

2. The multi-azimuth detectable geothermal probe of claim 1, wherein: the connecting rod assembly (14) comprises a long rod (141) and a short rod (142), wherein one end of the long rod (141) is rotationally connected with the fixed seat (12), a sliding groove (1410) is formed in the middle of the long rod (141), one end of the short rod (142) is rotationally connected with the sliding seat (13), one end of the short rod (142) away from the sliding seat (13) is slidably installed in the sliding groove (1410), and the outer end of the long rod (141) is rotationally connected with the positioning sleeve (15).

3. The multi-azimuth detectable geothermal probe of claim 1, wherein: the sliding seat (13) is fixedly connected with a plurality of L-shaped rods (131), and the upper ends of the L-shaped rods (131) are fixedly connected with an operation ring (132).

4. The multi-azimuth detectable geothermal probe of claim 1, wherein: the utility model discloses a sampling window, including board (211), blind spot (2100), tip (2112) are set up to board (211) one side, board (211) set up pivot (2111), board (211) are installed in sampling window (210) through pivot (2111) rotation, board (211) are kept away from pivot (2111) one end and are set up tip (2112), have blind end (2100) that correspond with tip (2112) on sampling window (210).

5. The multi-azimuth detectable geothermal probe of claim 1, wherein: the top end of the main shaft rod (11) is fixedly connected with a hand ring (110).

6. The multi-azimuth detectable geothermal probe of claim 2, wherein: the short rod (142) is provided with a groove (1420), and the groove (1420) is adapted to the rotary connection part of the long rod (141) and the positioning sleeve (15).

7. The multi-azimuth detectable geothermal probe of claim 1, wherein: the outside of sampling drilling rod (21) sets up boring soil spiral (213), sampling drilling rod (21) upper end sets up drive joint male head (214).

8. The multi-azimuth detectable geothermal probe of claim 1, wherein: the top of the sampling inner cylinder (22) is provided with a marking transverse line (221), the top of the sampling inner cylinder (22) is provided with a U-shaped handle (222), and the inside of the sampling drill rod (21) is provided with a marking longitudinal line (215).