CN215910134U - Geological information acquisition equipment based on big data - Google Patents

Abstract

The utility model discloses geological information acquisition equipment based on big data, which comprises a base, a fixing assembly and a collecting assembly, wherein the fixing assembly consists of a storage box, a storage drawer, a pulley, an adjusting block, a sleeve, a vertical shaft, a positioning column and a limiting shaft, the storage box is installed at the top of the base, the storage drawer is inserted into the side wall of the storage box, the positioning column and the limiting shaft are installed inside the storage drawer, a through groove B is formed in the surface of the positioning column, the pulley and the adjusting block are installed at the bottom of the base, the sleeve is installed inside the adjusting block, the vertical shaft is inserted into the sleeve, and a through groove A is formed in the bottom of the vertical shaft. According to the utility model, the pulley is prevented from driving the base through the fixing assembly, so that the position is prevented from moving, further certain errors exist in the acquired data, and soil is prevented from falling from the drilling head when the drilling head rises through the collecting assembly, so that the soil quality detection is prevented from being influenced.

Description

Geological information acquisition equipment based on big data

Technical Field

The utility model relates to the technical field of geological information acquisition, in particular to geological information acquisition equipment based on big data.

Background

The working processes of each specialty of basic geological investigation, mineral geological investigation, engineering geological investigation, environmental geological investigation and disaster geological investigation (collectively referred to as geological investigation) are essentially the processes of information acquisition, arrangement, processing, interpretation and application, and geological information acquisition equipment is needed in the geological investigation process.

Patent No. CN201721874094.0 discloses a detachable intelligent geological information acquisition device, which comprises a shell, wherein the shell is of a hollow structure, and a placing groove with an upward opening is arranged on the side wall of one side of the shell, two symmetrically arranged information collecting devices are arranged in the placing groove, the two information acquisition devices are connected with the bottom of the placing groove through telescopic sleeve rods, the side walls of the two sides of the shell are connected with auxiliary supporting devices through supporting rod threads, two symmetrically arranged fixed blocks are arranged on the bottom wall of the shell, two rotating rods which are horizontally arranged are arranged on the side wall of one side of each of the two fixing blocks, which is opposite to the side wall of the other side of the two fixing blocks, one ends of the two rotating rods, which are far away from the fixing blocks, penetrate through the side wall of one side of the shell, first mounting blocks are sleeved on the two rotating rods, the pulley is connected to the first mounting block, and a strip-shaped opening matched with the pulley is formed in the bottom wall of the shell. The utility model has simple structure, convenient disassembly and convenient storage after use.

This geological information collection equipment based on big data has following drawback: the existing geological information acquisition equipment is usually directly placed on the ground in the acquisition process and is not fixed, but internal electrical elements of the geological information acquisition equipment vibrate during working, so that the position of the geological information acquisition equipment moves, and further certain errors exist in acquired data; after the raw materials are collected, the raw materials fall off from the drilling head in the rising process, and detection is affected.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide geological information acquisition equipment based on big data, which can effectively solve the problems in the background technology.

In order to achieve the purpose, the utility model adopts the technical scheme that:

the utility model provides a geological information collection equipment based on big data, includes the base, still includes fixed subassembly and collection subassembly, fixed subassembly comprises bin, storage steamer tray, pulley, regulating block, sleeve, vertical axis, reference column and spacing axle, the bin is installed at the base top, it has the storage steamer tray to peg graft to the bin lateral wall, storage steamer tray internally mounted has reference column and spacing axle, logical groove B has been seted up on the reference column surface, pulley and regulating block are installed to the base bottom, regulating block internally mounted has the sleeve, the inside grafting of sleeve has vertical axis, logical groove A has been seted up to vertical axis bottom.

Furthermore, the collecting assembly consists of a power box, a manipulator, a drilling head, an opening and a clamping sleeve, the power box is installed at the top of the base, the manipulator is installed on the surface of the power box, the clamping sleeve is installed at the bottom of the power box, the clamping sleeve is provided with the opening, and the drilling head is detachably installed at the bottom of the clamping sleeve; through collecting the subassembly, prevent when the drill bit rises, soil from dropping from the boring head, influence soil quality and detect.

Furthermore, a thread groove is formed in the sleeve, threads are carved on the outer wall of the vertical shaft, and the threads are matched with the thread groove; and adjusting the vertical shaft, wherein the vertical shaft horizontally moves downwards in the sleeve through the thread groove, the vertical shaft is pulled, and the vertical shaft drives the sleeve to adjust the angle in the adjusting block.

Furthermore, the size of the through groove A is matched with that of the limiting shaft, and the size of the through groove B is matched with that of the vertical shaft; the vertical shaft is inserted into the through groove B formed in the positioning column, the limiting shaft is inserted into the through groove A formed in the vertical shaft, and the limiting shaft limits the vertical shaft.

Furthermore, a collecting vessel is arranged inside the drilling head; after the drilling probe is inserted into the ground, soil generated by the drilling probe enters the drilling probe through the opening and enters the collecting vessel. And collecting the soil.

Compared with the prior art, the utility model has the following beneficial effects:

1. when the quality information needs to be collected, the storage drawer is pulled to draw a positioning column and a limiting shaft in the storage drawer out of the storage box, the positioning column is inserted into the ground surface, the positioning column is fixed, the vertical shaft is adjusted and horizontally moves downwards in the sleeve through the threaded groove, the vertical shaft is pulled to drive the sleeve to adjust the angle in the adjusting block, the vertical shaft is inserted into a through groove B formed in the positioning column, the limiting shaft is inserted into a through groove A formed in the vertical shaft, the limiting shaft limits the vertical shaft, and the fixing component prevents the pulley from driving the base to move so that the collected data has certain errors.

2. When the soil quality detection device is used, the drilling probe is arranged in the clamping sleeve, the controller is adjusted, the controller drives the clamping sleeve to vertically move downwards, the clamping sleeve drives the drilling probe to vertically move downwards, the drilling probe starts to drill a hole on the ground surface, after the drilling probe is inserted into the ground, soil generated by the drilling probe enters the drilling probe through the opening and enters the collecting vessel, and the soil quality detection is prevented from being influenced because the soil falls out of the drilling probe when the drilling probe ascends through the collecting assembly.

Drawings

FIG. 1 is a front view of a big data based geological information acquisition device of the present invention;

FIG. 2 is a schematic diagram of the expansion of the interior of a grinding box of the geological information acquisition equipment based on big data according to the utility model;

FIG. 3 is an expanded schematic diagram of a drilling head of the geological information acquisition equipment based on big data.

In the figure: 1. a base; 2. a power box; 3. a manipulator; 4. a storage tank; 5. a storage drawer; 6. a pulley; 7. drilling a probe; 8. an adjusting block; 9. a sleeve; 10. a thread groove; 11. a vertical axis; 12. a through groove A; 13. a positioning column; 14. a through groove B; 15. a limiting shaft; 16. a fixing assembly; 17. an opening; 18. a clamping sleeve; 19. a collection vessel; 20. and (4) collecting the components.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the utility model easy to understand, the utility model is further described with the specific embodiments.

As shown in fig. 1-3, a geological information collection equipment based on big data, including base 1, still include fixed subassembly 16 and collection subassembly 20, fixed subassembly 16 comprises bin 4, storage steamer tray 5, pulley 6, regulating block 8, sleeve 9, vertical axis 11, reference column 13 and spacing axle 15, bin 4 is installed at base 1 top, bin 4 lateral wall is pegged graft and is had storage steamer tray 5, storage steamer tray 5 internally mounted has reference column 13 and spacing axle 15, logical groove B14 has been seted up on reference column 13 surface, pulley 6 and regulating block 8 are installed to base 1 bottom, regulating block 8 internally mounted has sleeve 9, sleeve 9 is inside to be pegged graft and is had vertical axis 11, logical groove a12 has been seted up to vertical axis 11 bottom.

The collecting assembly 20 comprises a power box 2, a manipulator 3, a drilling head 7, an opening 17 and a clamping sleeve 18, wherein the power box 2 is installed at the top of the base 1, the manipulator 3 is installed on the surface of the power box 2, the clamping sleeve 18 is installed at the bottom of the power box 2, the opening 17 is formed in the clamping sleeve 18, and the drilling head 7 is detachably installed at the bottom of the clamping sleeve 18; by means of the collecting assembly 20, soil is prevented from falling from the drilling head 7 when the drilling head 7 ascends, and soil quality detection is prevented from being influenced.

A thread groove 10 is formed in the sleeve 9, threads are carved on the outer wall of the vertical shaft 11, and the threads are matched with the thread groove 10; and adjusting a vertical shaft 11, wherein the vertical shaft 11 horizontally moves downwards in the sleeve 9 through a thread groove 10, pulling the vertical shaft 11, and the vertical shaft 11 drives the sleeve 9 to adjust the angle in the adjusting block 8.

The size of the through groove A12 is matched with that of the limiting shaft 15, and the size of the through groove B14 is matched with that of the vertical shaft 11; the vertical shaft 11 is inserted into the through groove B14 formed in the positioning column 13, the limit shaft 15 is inserted into the through groove A12 formed in the vertical shaft 11, and the limit shaft 15 limits the vertical shaft 11.

Wherein, a collecting vessel 19 is arranged inside the drilling head 7; after the drilling head 7 is inserted into the ground, the soil produced by the drilling head 7 enters the interior of the drilling head 7 through the opening 17 and into the interior of the collection dish 19. And collecting the soil.

It should be noted that the utility model is a geological information collection device based on big data, when the geological information collection is needed, the storage drawer 5 is pulled, the positioning column 13 and the limiting shaft 15 in the storage drawer 5 are drawn out from the storage box 4, the positioning column 13 is inserted on the ground surface, the positioning column 13 is fixed, the vertical shaft 11 is adjusted, the vertical shaft 11 moves horizontally and downwards in the sleeve 9 through the thread groove 10, the vertical shaft 11 is pulled, the vertical shaft 11 drives the sleeve 9 to adjust the angle in the adjusting block 8, the vertical shaft 11 is inserted in the through groove B14 formed in the positioning column 13, the limiting shaft 15 is inserted in the through groove A12 formed in the vertical shaft 11, the limiting shaft 15 limits the vertical shaft 11, the fixing component 16 prevents the pulley 6 from driving the base 1 to move the position, and further causes certain error of the collected data, when in use, the drilling probe 7 is installed in the clamping sleeve 18, and adjusting the manipulator 3, driving the clamping sleeve 18 to vertically move downwards by the manipulator 3, driving the drilling head 7 to vertically move downwards by the clamping sleeve 18, starting drilling on the earth surface by the drilling head 7, after the drilling head 7 is inserted into the earth, allowing soil generated by the drilling head 7 to enter the inside of the drilling head 7 through the opening 17 and enter the inside of the collecting vessel 19, and preventing the soil from falling from the drilling head 7 to influence soil quality detection when the drilling head 7 ascends through the collecting assembly 20.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (5)

1. The geological information acquisition equipment based on big data comprises a base (1) and is characterized by further comprising a fixing component (16) and a collecting component (20), wherein the fixing component (16) consists of a storage bin (4), a storage drawer (5), a pulley (6), an adjusting block (8), a sleeve (9), a vertical shaft (11), a positioning column (13) and a limiting shaft (15), the storage bin (4) is installed at the top of the base (1), the storage drawer (5) is inserted into the side wall of the storage bin (4), the positioning column (13) and the limiting shaft (15) are installed inside the storage drawer (5), a through groove B (14) is formed in the surface of the positioning column (13), the pulley (6) and the adjusting block (8) are installed at the bottom of the base (1), the sleeve (9) is installed inside the adjusting block (8), the vertical shaft (11) is inserted into the sleeve (9), the bottom of the vertical shaft (11) is provided with a through groove A (12).

2. The big data-based geological information collection device according to claim 1, wherein: collect subassembly (20) and constitute by headstock (2), controller (3), probing head (7), opening (17) and centre gripping cover (18), install at base (1) top headstock (2), headstock (2) surface mounting has controller (3), centre gripping cover (18) are installed to headstock (2) bottom, opening (17) have been seted up in centre gripping cover (18), demountable installation has probing head (7) bottom centre gripping cover (18).

3. The big data-based geological information collection device according to claim 1, wherein: a thread groove (10) is formed in the sleeve (9), threads are carved on the outer wall of the vertical shaft (11), and the threads are matched with the thread groove (10).

4. The big data-based geological information collection device according to claim 1, wherein: the size of the through groove A (12) is matched with the size of the limiting shaft (15), and the size of the through groove B (14) is matched with the size of the vertical shaft (11).

5. The big data-based geological information collection device according to claim 2, wherein: and a collecting vessel (19) is arranged in the drilling head (7).

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