CN112357432A - Rock core sample storage equipment for geotechnical engineering exploration - Google Patents

Abstract

The invention discloses rock core sample storage equipment for geotechnical engineering exploration, and belongs to the technical field of civil engineering. The invention comprises a base; the top surface of the base is fixedly connected with a supporting beam frame; a driving roller and a driven roller are respectively and rotatably connected between the inner surfaces of the supporting beam frames; the peripheral sides of the driving roller and the driven roller are connected with two symmetrically arranged annular driving belts; the surface of the support beam frame is fixedly connected with a main driving motor at a position corresponding to the driving roller; one end of an output shaft of the main driving motor is fixedly connected with the driving roller; the surfaces of the two endless driving belts are provided with a group of storage mechanisms which are distributed at equal intervals; the storage mechanism includes a positioning frame. According to the invention, through the design of the annular driving belt and the storage mechanism, the fixed storage structure of the traditional sample storage device is changed into a movable storage structure, the arrangement position of the storage mechanism is conveniently and rapidly changed through the movable storage structure, and the core sample is conveniently and rapidly taken and placed through the rapid change of the arrangement position.

Description

Rock core sample storage equipment for geotechnical engineering exploration

Technical Field

The invention belongs to the technical field of civil engineering, and particularly relates to rock core sample storage equipment for geotechnical engineering exploration.

Background

The geotechnical engineering investigation refers to the activities of finding out, analyzing and evaluating geological and environmental characteristics and geotechnical engineering conditions of a construction site and compiling investigation files according to the requirements of construction engineering, wherein the activities involve the recording and storage of cores obtained by exploration, and the recording and storage of the cores play a vital role in later geotechnical analysis and the storage of analysis process evidences. In the process of carrying out core editing and recording, classified storage is carried out according to the core obtaining depth and the core type, the storage is required to be reliable and can not be confused, and in the whole geotechnical analysis process, frequent core samples need to be taken, so the requirement of frequently taking the core is also considered when the core is stored.

In the prior art, a plurality of excessively narrow battens are generally used for forming a plurality of parallel compartments for storing a core sample, the core sample is placed in the compartments during use, and a mark marked on the surface of the core sample is exposed through a gap between the narrow battens. When the core storage tool is used, the narrow wood strips are usually connected through the iron rods, so that the structure of the core storage tool is easy to loosen after a large number of core samples are loaded, and even long-distance transportation cannot be carried out; the mark that usually needs to be with the rock core sample exposes in the outside, and traditional narrow stuff instrument of making can only be in order to conveniently observe and look for the rock core sample, this just requires when placing the rock core sample, can only place two rows of rock core samples side by side, this has just led to when carrying out the rock core sample and cataloguing, the strorage device that needs a large amount of narrow stuff to make, when transporting and depositing, need consider a plurality of strorage device and pile up the stability and the problem of easily empting when placing, and current strorage device adopts fixed structure more, owing to be fixed structure, lead to current strorage device to be not convenient for carry out taking fast of rock core and put.

Disclosure of Invention

The invention aims to provide rock core sample storage equipment for geotechnical engineering exploration, which solves the problems in the background technology through the design of a storage mechanism.

In order to achieve the purpose, the invention provides the following technical scheme: a rock core sample storage device for geotechnical engineering exploration comprises a base; the top surface of the base is fixedly connected with a supporting beam frame; a driving roller and a driven roller are respectively and rotatably connected between the inner surfaces of the supporting beam frames; the peripheral sides of the driving roller and the driven roller are connected with two symmetrically arranged annular driving belts; the surface of the supporting beam frame is fixedly connected with a main driving motor at a position corresponding to the driving roller; one end of the output shaft of the main driving motor is fixedly connected with the driving roller; a group of storage mechanisms which are distributed at equal intervals are arranged on the surfaces of the two annular driving belts;

the storage mechanism comprises a positioning frame; the peripheral side surface of the positioning frame is fixedly connected with two annular driving belts through a connecting piece; a hinge shaft is fixedly arranged between the inner surfaces of the positioning frames; the peripheral side surface of the hinge shaft is hinged with an accommodating module a;

the inner wall of the containing module a is rotatably connected with a transmission main screw rod through a bearing; the circumferential side surface of the transmission main screw is respectively provided with a positive thread part and a reverse thread part; the positions of the peripheral side surface of the transmission main screw, which correspond to the positive thread part and the reverse thread part, are respectively connected with a receiving module b; a group of telescopic frames distributed in a circumferential array are fixedly connected between the opposite surfaces of the two receiving modules b and the receiving module a;

the containing modules a and b respectively comprise a movable plate, a fixed plate and two symmetrically arranged hinge bases a; the bottom surface of the movable plate and the top surface of the fixed plate are both fixedly connected with a hinge seat b; the inner walls of the two twisting seats b are hinged with a first limiting rubber rod and a second limiting rubber rod; the inner wall of the twisting seat a is hinged with the two first limiting rubber rods; the inner wall of the other twisting seat a is hinged with two second limiting rubber rods;

the inner wall of the fixing plate at the storage module a is hinged with the hinge shaft through a connecting piece; the inner wall of the fixing plate at the containing module b is in sliding fit with the hinge shaft through a connecting piece;

two symmetrically arranged pressure applying springs matched with the storage module b are further sleeved on the circumferential side face of the hinge shaft; the peripheral side surfaces of the first limiting rubber rod and the second limiting rubber rod are fixedly connected with the telescopic frame; the peripheral side surfaces of the first limiting rubber rod and the second limiting rubber rod are rotatably connected with rollers;

the top surface of the fixing plate at the containing module a is fixedly connected with a group of guide rods; the peripheral side surfaces of the guide rods are in sliding connection with the movable plates at the storage module a; a transmission auxiliary screw rod is rotatably connected inside the fixing plate at the containing module a; the peripheral side surface of the transmission auxiliary screw is connected with a movable plate at the position of the storage module a;

a double-head telescopic limiting pipe is fixedly connected between the opposite surfaces of the fixed plate and the movable plate at the position of the containing module b at the rear side;

the top surface of the support beam frame is fixedly connected with a fence mechanism; and a hot air distribution mechanism is fixedly arranged between the inner surfaces of the support beam frames.

The scheme is as follows:

the main driving motor, the hot air supply assembly and the electric push rod are common parts in the prior art, and the adopted models and the like can be customized according to actual use requirements;

as a preferred embodiment, the enclosure mechanism comprises two groups of symmetrically arranged electric push rods and a pull plate; the peripheral side surfaces of the two groups of electric push rods are fixedly connected with the supporting beam frame; the top ends of the two groups of electric push rods are fixedly connected with a top seat; a corrugated telescopic enclosure is fixedly arranged between the opposite surfaces of the top seat and the pulling plate; the bottom surface of the top seat and the top surface of the base are both fixedly connected with a group of magnetic strips matched with the pulling plate; a shaping strip is fixedly arranged inside the corrugated telescopic enclosure; the shaping strip is of a continuous U-shaped structure.

As a preferred embodiment, the hot air distribution mechanism comprises an air distribution pipe and a hot air supply assembly; one surface of the air distributing pipe is fixedly connected with the support beam frame; a group of hot air spray pipes distributed in a linear array are fixedly arranged between the inner surfaces of the support beam frames; one end of each group of hot air spray pipes is fixedly communicated with the air distributing pipe; one end of the air outlet of the hot air supply assembly is fixedly communicated with the air distribution pipe through an air supply pipe; the surface of the supporting beam frame is also fixedly provided with a temperature and humidity sensor matched with the hot air distribution mechanism; the air outlet direction of the hot air spray pipe is parallel to the horizontal line.

As a preferred embodiment, the hot wind supply assembly includes a hot wind box body; one surface of the hot air box body is fixedly connected with the supporting beam frame; a fan and an electric heating wire are respectively and fixedly connected inside the hot air box body; one end of the air outlet of the hot air box body is fixedly communicated with the air supply pipe; an air inlet is fixedly arranged on the surface of the hot air box body.

As a preferred embodiment, a group of universal casters distributed in a rectangular array is fixedly connected to the bottom surface of the base; the included angle between the axis of the hinge seat a and the axis of the hinge seat b is 90 degrees; and the end parts of the transmission main screw rod and the transmission auxiliary screw rod are fixedly provided with driving rotary handles.

As a preferred embodiment, the peripheral side surfaces of the driving roller and the driven roller and the positions corresponding to the two annular driving belts are fixedly connected with a limiting wheel disc; and the surface of the limiting wheel disc is fixedly provided with a wheel groove matched with the annular driving belt.

In a preferred embodiment, the cross section of the guide rod is of a T-shaped structure; the thread directions of the forward thread part and the reverse thread part are opposite and the thread pitches are the same; a rubber buffer pad is fixedly arranged on the peripheral side surface of the roller; and friction grains are fixedly arranged on the surface of the rubber buffer pad.

As a preferred embodiment, the positioning frame is of a U-like structure; a power-off brake is fixedly arranged in the main driving motor; the supporting beam frame is of a U-shaped structure; the included angle between the axis of the transmission main screw and the axis of the transmission auxiliary screw is 90 degrees.

Compared with the prior art, the rock core sample storage equipment for geotechnical engineering exploration, provided by the invention, at least has the following beneficial effects:

(1) according to the invention, through the design of the annular driving belt and the storage mechanism, the fixed storage structure of the traditional sample storage device is changed into a movable storage structure, the arrangement position of the storage mechanism is conveniently and rapidly changed through the movable storage structure, and the core sample is conveniently and rapidly taken and placed through the rapid change of the arrangement position.

(2) According to the invention, through the design of the storage module a and the storage module b, the non-adjustable structure of the traditional storage device is changed into an adjustable structure, before the storage device is used, the distance between the storage module a and the storage module b can be quickly adjusted through the adjustment of the transmission main screw rod, the storage device is further suitable for the storage operation of rock core samples with different lengths through the adjustment of the distance, the distance between the first limiting rubber rod and the second limiting rubber rod can be quickly adjusted through the adjustment of the transmission auxiliary screw rod, the clamping radius of the storage device can be quickly adjusted through the change of the distance, the storage device can be further suitable for the storage operation of rock core samples with different radii through the adjustment of the clamping radius, and the practicability and the universality of the storage device are effectively improved through the realization of the adjustable effect.

(3) According to the invention, through the design of the hot air distribution mechanism and the enclosure mechanism, the device can have a double use mode, so that the practicability of the device is effectively improved, through the design of the hot air distribution mechanism, the set temperature and humidity in the device can be maintained under the sealing condition, and through the maintenance of the temperature and humidity, the long-term preservation of the core sample is facilitated.

Drawings

FIG. 1 is a schematic structural diagram of a core sample storage device for geotechnical engineering exploration;

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

FIG. 3 is a schematic structural diagram of a fence mechanism, a driving roller and a driven roller;

FIG. 4 is a schematic structural view of the fixed plate, the movable plate and the telescopic frame;

FIG. 5 is an enlarged view of a portion of FIG. 4 at A;

FIG. 6 is a schematic top view of the structure of FIG. 4;

FIG. 7 is a schematic view of the storage mechanism;

fig. 8 is a schematic structural view of the receiving module b;

fig. 9 is a schematic structural view of the receiving module a.

In the figure: 1. a base; 2. a support beam frame; 3. a drive roll; 4. a driven roller; 5. an endless drive belt; 6. a main drive motor; 7. a storage mechanism; 8. a positioning frame; 9. a hinge shaft; 10. a storage module a; 11. a drive main screw; 12. a positive thread portion; 13. a reverse threaded portion; 14. a storage module b; 15. a telescopic frame; 16. a movable plate; 17. a fixing plate; 18. a hinge base a; 19. a twisting seat b; 20. a first limit rubber bar; 21. a second limiting rubber rod; 22. a pressure applying spring; 23. a drum; 24. a guide bar; 25. a drive assist screw; 26. a double-head telescopic limiting pipe; 27. a fence mechanism; 28. a hot air distribution mechanism; 29. an electric push rod; 30. pulling a plate; 31. a top seat; 32. a corrugated telescopic enclosure; 33. a magnetic strip; 34. air distributing pipes; 35. a hot air supply assembly; 36. a hot air nozzle; 37. a temperature and humidity sensor; 38. a universal caster.

Detailed Description

The present invention will be further described with reference to the following examples.

The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention. The conditions in the embodiments can be further adjusted according to specific conditions, and simple modifications of the method of the present invention based on the concept of the present invention are within the scope of the claimed invention.

Referring to fig. 1 to 9, the present invention provides a core sample storage apparatus for geotechnical engineering exploration, which includes a base 1; the top surface of the base 1 is fixedly connected with a supporting beam frame 2; a driving roller 3 and a driven roller 4 are respectively and rotatably connected between the inner surfaces of the supporting beam frames 2; two symmetrically arranged annular driving belts 5 are connected to the peripheral sides of the driving roller 3 and the driven roller 4; the surface of the supporting beam frame 2 is fixedly connected with a main driving motor 6 corresponding to the position of the driving roller 3; the main driving motor 6 is used for driving the two annular driving belts 5 to run at a set speed, and one end of an output shaft of the main driving motor 6 is fixedly connected with the driving roller 3; a group of storage mechanisms 7 which are distributed at equal intervals are arranged on the surfaces of the two endless driving belts 5; the arrangement position of the storage mechanism 7 can be changed rapidly through the arrangement of the connection state;

the storage mechanism 7 includes a positioning frame 8; the peripheral side surface of the positioning frame 8 is fixedly connected with the two annular driving belts 5 through a connecting piece; a hinge shaft 9 is fixedly arranged between the inner surfaces of the positioning frames 8; the peripheral side surface of the hinge shaft 9 is hinged with an accommodating module a 10;

the inner wall of the containing module a10 is rotationally connected with a transmission main screw 11 through a bearing; the peripheral side surface of the transmission main screw 11 is respectively provided with a positive thread part 12 and a reverse thread part 13; the peripheral side surface of the transmission main screw 11 and the positions corresponding to the positive thread part 12 and the reverse thread part 13 are both connected with a receiving module b 14; a group of expansion brackets 15 distributed in a circumferential array are fixedly connected between the opposite surfaces of the two storage modules b14 and the storage module a 10; through the arrangement of the forward threaded part 12 and the reverse threaded part 13, the two containing modules b14 can synchronously approach to each other or synchronously separate from each other, the distance between the two containing modules b14 is changed, and then the size of a containing cavity of the device is changed;

the storage module a10 and the storage module b14 each include a movable plate 16, a fixed plate 17 and two symmetrically arranged hinge bases a 18; the bottom surface of the movable plate 16 and the top surface of the fixed plate 17 are both fixedly connected with a hinge seat b 19; the inner walls of the two twisting seats b19 are hinged with a first limiting rubber rod 20 and a second limiting rubber rod 21; the first limiting rubber rod 20 and the second limiting rubber rod 21 are made of rubber; through the arrangement of the rubber material, a soft clamping state can be formed during clamping, and the damage to the surface of the core during clamping is effectively avoided through the formation of the soft clamping state;

the inner wall of a twisting seat a18 is hinged with two first limit rubber rods 20; the inner wall of the other twisting seat a18 is hinged with two second limit rubber rods 21;

the inner wall of the fixed plate 17 at the receiving module a10 is hinged with the hinge shaft 9 through a connecting piece; the inner wall of the fixed plate 17 at the receiving module b14 is in sliding fit with the hinge shaft 9 through a connecting piece; through the arrangement of the connection state, the gravity center directions of the containing module a10 and the containing module b14 can be kept in a vertically downward state, the reel seat b19 and the reel seat a18 are used as counterweights, so that the gravity centers of the containing module a10 and the containing module b14 can be kept vertically downward, and the balance weights are used for realizing that the containing cavities of the two containing modules a10 and the containing module b14 have certain weight tolerance, namely core samples with different weights can be stored in a certain range in the two containing cavities of the same module;

two symmetrically arranged pressure springs 22 matched with the containing module b14 are sleeved on the circumferential side surface of the hinge shaft 9; the peripheral sides of the first limiting rubber rod 20 and the second limiting rubber rod 21 are fixedly connected with the telescopic frame 15; the circumferential side surfaces of the first limiting rubber rod 20 and the second limiting rubber rod 21 are rotatably connected with rollers 23; through the arrangement of the roller 23, the friction force between the core and the containing module a10 and the containing module b14 during taking out is reduced, and the core sample is conveniently and quickly taken out;

a group of guide rods 24 are fixedly connected to the top surface of the fixed plate 17 at the storage module a 10; the peripheral sides of the group of guide rods 24 are all connected with the movable plate 16 at the storage module a10 in a sliding way; a transmission auxiliary screw rod 25 is rotatably connected inside the fixed plate 17 at the containing module a 10; the peripheral side surface of the auxiliary transmission screw 25 is connected with the movable plate 16 at the storage module a10, the auxiliary transmission screw 25 is arranged for changing the distance between the fixed plate 17 and the movable plate 16, and when the distance is changed, the distance between the fixed plate 17 and the movable plate 16 at the storage module b14 can be synchronously changed, so that the capacity of the storage cavities at the storage module b14 and the storage module a10 can be conveniently adjusted through the change of the distance, and the storage module b14 and the storage module a10 can limit and clamp core samples with various radiuses through the adjustment operation;

a double-head telescopic limiting pipe 26 is fixedly connected between the opposite surfaces of the fixed plate 17 and the movable plate 16 at the storage module b14 at the rear side, and the double-head telescopic limiting pipe 26 is used for limiting the movable degree of the core sample from the rear part;

the top surface of the supporting beam frame 2 is fixedly connected with a fence mechanism 27; the hot air distribution mechanism 28 is fixedly installed between the inner surfaces of the supporting beam frames 2, the enclosure mechanism 27 is used for maintaining the inside of the device in a closed state, the hot air distribution mechanism 28 is used for dehumidifying and drying the closed cavity, and the dehumidifying and drying functions are realized, so that the storage of core samples is facilitated.

The main driving motor 6, the hot air supply assembly 35 and the electric push rod 29 are common parts in the prior art, and the adopted models and the like can be customized according to actual use requirements;

the enclosure mechanism 27 comprises two groups of electric push rods 29 and a pull plate 30 which are symmetrically arranged; the peripheral side surfaces of the two groups of electric push rods 29 are fixedly connected with the supporting beam frame 2; the top ends of the two groups of electric push rods 29 are fixedly connected with a top seat 31; a corrugated telescopic enclosure 32 is fixedly arranged between the opposite surfaces of the top seat 31 and the pulling plate 30; the bottom surface of the top seat 31 and the top surface of the base 1 are both fixedly connected with a group of magnetic strips 33 matched with the pulling plate 30; the inside of the corrugated telescopic enclosure 32 is fixedly provided with a shaping strip; moulding strip is continuous "U" type structure, arm-tie 30 is the iron material, the effect that magnetic stripe 33 set up lies in carrying on spacingly to arm-tie 30, through spacing, thereby make the flexible cover 32 that encloses of ripple keep accomodating or the state of expanding, the flexible cover 32 that encloses of ripple is corrosion-resistant rubber material, as further improvement, the flexible cover 32 that encloses of ripple also can adopt other suitable materials to replace, moulding strip is provided with four, and be located the flexible cover 32 that encloses of ripple respectively all around, moulding strip is magnesium aluminium material, certain scalability has.

The hot air distribution mechanism 28 comprises an air distribution pipe 34 and a hot air supply assembly 35; one surface of the air distributing pipe 34 is fixedly connected with the supporting beam frame 2; a group of hot air spray pipes 36 which are distributed in a linear array are fixedly arranged between the inner surfaces of the supporting beam frames 2; one end of each group of hot air spray pipes 36 is fixedly communicated with the air distributing pipe 34; one end of the air outlet of the hot air supply component 35 is fixedly communicated with the air distributing pipe 34 through an air supply pipe; the surface of the supporting beam frame 2 is also fixedly provided with a temperature and humidity sensor 37 matched with the hot air distribution mechanism 28; the air-out direction of hot-blast spray tube 36 is parallel with horizontal line, temperature and humidity sensor 37 is used for the inside humiture data under the real-time supervision the device closed condition, in using, the device is equipped with the controller, the controller is the PLC controller of ordinary model, temperature and humidity sensor 37 feeds back the real-time signal who monitors to the controller, the data feedback of controller according to temperature and humidity sensor 37, the operating condition of mechanism 28 is given to control hot-blast cloth, then realize under the closed condition to the inside dehumidification drying of the device, temperature and humidity sensor 37's model is HR-NTC.

The hot air supply unit 35 includes a hot air box body; one surface of the hot blast box body is fixedly connected with the supporting beam frame 2; the inside of the hot air box body is respectively and fixedly connected with a fan and an electric heating wire; one end of the air outlet of the hot air box body is fixedly communicated with the air supply pipe; an air inlet is fixedly arranged on the surface of the hot air box.

The bottom surface of the base 1 is fixedly connected with a group of universal casters 38 distributed in a rectangular array; the included angle between the axis of the hinge seat a18 and the axis of the hinge seat b19 is 90 degrees; the end parts of the transmission main screw rod 11 and the transmission auxiliary screw rod 25 are fixedly provided with driving rotary handles.

The peripheral side surfaces of the driving roller 3 and the driven roller 4 and the positions corresponding to the two annular driving belts 5 are fixedly connected with a limiting wheel disc; the surface of the limit wheel disc is fixedly provided with a wheel groove matched with the annular driving belt 5.

The cross section of the guide rod 24 is of a T-shaped structure; the forward thread part 12 and the reverse thread part 13 have the same thread direction and the same thread pitch; a rubber buffer pad is fixedly arranged on the peripheral side surface of the roller 23; the surface of the rubber buffer pad is fixedly provided with friction grains.

The positioning frame 8 is of a U-like structure; a power-off brake is fixedly arranged in the main driving motor 6; through the arrangement of the power-off brake, the motor can effectively self-limit related components in a power-off state, and the supporting beam frame 2 is of a U-shaped structure; the included angle between the axis of the main drive screw 11 and the axis of the auxiliary drive screw 25 is 90 deg..

When in use, the device is provided with two use states, wherein the first use state is an open use state, and the second use state is a closed use state;

in an open state, the device is in a mode shown in fig. 1, in the mode shown in fig. 1, the corrugated telescopic enclosure 32 is fully contracted, the pulling plate 31 is limited on the top seat 31, when in use, the distance between the two containing modules b14 and a10 can be adjusted by adjusting the transmission main screw 11, when the distance is changed, the telescopic frame 15 is driven to be telescopic, the contained length of the device can be changed by changing the distance, the storage of core samples with different lengths is facilitated by adjusting the contained length, each storage mechanism 7 can be independently adjusted during storage, the distance between the reel seat a18 and the reel seat b19 can be changed by adjusting the transmission auxiliary screw 25, the included angle between the first limiting rubber rod 20 and the second limiting rubber rod 21 can be conveniently changed by changing the included angle through changing the included angle, therefore, the rock cores with different radiuses can be clamped in a limiting mode, and in addition, each storage mechanism 7 can be independently operated in the adjusting operation, so that the storage operation of various rock core samples is facilitated;

under the closed state, flexible enclosure 32 of ripple fully expands, and the arm-tie 30 magnetism is inhaled on base 1, and hot-blast supply assembly 35 is through the cooperation with temperature and humidity sensor 37, and then makes the appearance chamber after the sealing maintain for setting for the humiture, through the maintenance of humiture to be favorable to the permanent storage of rock core sample.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides an equipment is deposited with rock core sample to geotechnical engineering exploration, includes base (1), its characterized in that:

the top surface of the base (1) is fixedly connected with a supporting beam frame (2); a driving roller (3) and a driven roller (4) are respectively and rotatably connected between the inner surfaces of the supporting beam frames (2); the peripheral sides of the driving roller (3) and the driven roller (4) are connected with two symmetrically arranged annular driving belts (5); the surface of the support beam frame (2) is fixedly connected with a main driving motor (6) at a position corresponding to the driving roller (3); one end of an output shaft of the main driving motor (6) is fixedly connected with the driving roller (3); a group of storage mechanisms (7) which are distributed at equal intervals are arranged on the surfaces of the two annular driving belts (5);

the storage mechanism (7) comprises a positioning frame (8); the peripheral side surface of the positioning frame (8) is fixedly connected with the two annular driving belts (5) through a connecting piece; a hinge shaft (9) is fixedly arranged between the inner surfaces of the positioning frames (8); the peripheral side surface of the hinge shaft (9) is hinged with an accommodating module a (10);

the inner wall of the containing module a (10) is rotatably connected with a transmission main screw rod (11) through a bearing; the peripheral side surface of the transmission main screw rod (11) is respectively provided with a forward thread part (12) and a reverse thread part (13); the peripheral side surface of the transmission main screw rod (11) and the positions corresponding to the positive thread part (12) and the negative thread part (13) are both connected with a receiving module b (14); a group of expansion brackets (15) distributed in a circumferential array are fixedly connected between the opposite surfaces of the two receiving modules b (14) and the receiving module a (10);

the containing modules a (10) and b (14) respectively comprise a movable plate (16), a fixed plate (17) and two symmetrically arranged hinge bases a (18); the bottom surface of the movable plate (16) and the top surface of the fixed plate (17) are fixedly connected with a hinge seat b (19); the inner walls of the two twisting seats b (19) are hinged with a first limiting rubber rod (20) and a second limiting rubber rod (21); the inner wall of the twisting seat a (18) is hinged with the two first limiting rubber rods (20); the inner wall of the other twisting seat a (18) is hinged with two second limiting rubber rods (21);

the inner wall of a fixing plate (17) at the position of the storage module a (10) is hinged with a hinge shaft (9) through a connecting piece; the inner wall of a fixing plate (17) at the position of the receiving module b (14) is in sliding fit with the hinge shaft (9) through a connecting piece;

two symmetrically arranged pressure applying springs (22) matched with the storage module b (14) are sleeved on the peripheral side surface of the hinge shaft (9); the peripheral sides of the first limiting rubber rod (20) and the second limiting rubber rod (21) are fixedly connected with the telescopic frame (15); the circumferential side surfaces of the first limiting rubber rod (20) and the second limiting rubber rod (21) are rotatably connected with rollers (23);

a group of guide rods (24) are fixedly connected to the top surface of the fixing plate (17) at the accommodating module a (10); the peripheral side surfaces of the guide rods (24) are connected with a movable plate (16) at the position of the storage module a (10) in a sliding manner; a transmission auxiliary screw rod (25) is rotatably connected inside the fixing plate (17) at the accommodating module a (10); the peripheral side surface of the transmission auxiliary screw rod (25) is connected with a movable plate (16) at the position of the receiving module a (10);

a double-head telescopic limiting pipe (26) is fixedly connected between the opposite surfaces of the fixed plate (17) and the movable plate (16) at the position of the containing module b (14) at the rear side;

the top surface of the supporting beam frame (2) is fixedly connected with a fence mechanism (27); and a hot air distribution mechanism (28) is fixedly arranged between the inner surfaces of the supporting beam frames (2).

2. Core sample storage equipment for geotechnical engineering exploration according to claim 1, characterized in that said containment means (27) comprise two groups of symmetrically arranged electric push rods (29) and a pull plate (30); the peripheral side surfaces of the two groups of electric push rods (29) are fixedly connected with the supporting beam frame (2); the top ends of the two groups of electric push rods (29) are fixedly connected with a top seat (31); a corrugated telescopic enclosure (32) is fixedly arranged between the opposite surfaces of the top seat (31) and the pulling plate (30); the bottom surface of the top seat (31) and the top surface of the base (1) are fixedly connected with a group of magnetic strips (33) matched with the pulling plate (30); a shaping strip is fixedly arranged inside the corrugated telescopic enclosure (32); the shaping strip is of a continuous U-shaped structure.

3. Core sample storage device for geotechnical engineering exploration according to claim 1, characterized in that said hot air distribution mechanism (28) comprises a branch air pipe (34) and a hot air supply assembly (35); one surface of the air distributing pipe (34) is fixedly connected with the supporting beam frame (2); a group of hot air spray pipes (36) which are distributed in a linear array are fixedly arranged between the inner surfaces of the supporting beam frames (2); one end of each group of hot air spray pipes (36) is fixedly communicated with the air distributing pipe (34); one end of the air outlet of the hot air supply assembly (35) is fixedly communicated with the air distribution pipe (34) through an air supply pipe; a temperature and humidity sensor (37) matched with the hot air distribution mechanism (28) is fixedly arranged on the surface of the support beam frame (2); the air outlet direction of the hot air spray pipe (36) is parallel to the horizontal line.

4. Core sample storage device for geotechnical engineering exploration according to claim 3, characterized in that said hot air supply assembly (35) comprises a hot air box; one surface of the hot blast box body is fixedly connected with the supporting beam frame (2); a fan and an electric heating wire are respectively and fixedly connected inside the hot air box body; one end of the air outlet of the hot air box body is fixedly communicated with the air supply pipe; an air inlet is fixedly arranged on the surface of the hot air box body.

5. The rock core sample storage device for geotechnical engineering exploration according to claim 1, wherein a group of universal casters (38) distributed in a rectangular array is fixedly connected to the bottom surface of the base (1); the included angle between the axis of the hinge seat a (18) and the axis of the hinge seat b (19) is 90 degrees; and the end parts of the transmission main screw rod (11) and the transmission auxiliary screw rod (25) are fixedly provided with driving rotary handles.

6. The rock core sample storage device for geotechnical engineering exploration according to claim 1, wherein the peripheral side surfaces of the driving roller (3) and the driven roller (4) and the positions corresponding to the two annular driving belts (5) are fixedly connected with a limiting wheel disc; the surface of the limiting wheel disc is fixedly provided with a wheel groove matched with the annular driving belt (5).

7. Core sample storage equipment for geotechnical engineering exploration according to claim 1, characterized in that said guide rod (24) is of "T" type structure in cross section; the thread directions of the positive thread part (12) and the reverse thread part (13) are opposite and the thread pitches are the same; a rubber buffer pad is fixedly arranged on the peripheral side surface of the roller (23); and friction grains are fixedly arranged on the surface of the rubber buffer pad.

8. Core sample storage equipment for geotechnical engineering exploration according to claim 1, characterized in that said positioning frame (8) is of a "U" -like structure; a power-off brake is fixedly arranged in the main driving motor (6); the supporting beam frame (2) is of a U-shaped structure; the included angle between the axis of the transmission main screw rod (11) and the axis of the transmission auxiliary screw rod (25) is 90 degrees.

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