CN113636191A

CN113636191A - Storage and transportation device for engineering geological exploration samples and use method thereof

Info

Publication number: CN113636191A
Application number: CN202110971272.6A
Authority: CN
Inventors: 张永善; 雷有德; 武明德; 宋星莹
Original assignee: Qinghai Shengtuo Ecological Technology Co ltd
Current assignee: Qinghai Shengtuo Ecological Technology Co ltd
Priority date: 2021-08-24
Filing date: 2021-08-24
Publication date: 2021-11-12
Anticipated expiration: 2041-08-24
Also published as: CN113636191B

Abstract

The invention belongs to the technical field of geological exploration, in particular to a storage and transportation device for engineering geological exploration samples and a using method thereof, aiming at the problem that samples cannot be quickly found when the samples need to be taken out due to disordered sampling and storage in the prior art, the invention provides the following scheme. When the device is used and a ground to-be-explored sample needs to be sampled, the sample can be taken out and directly screwed on the tray without transferring again and can be placed in the storage box only by pricking the sampling tube into the sampling position, and the integrity and the related characteristics of the sample are prevented from being damaged in the transferring process.

Description

Storage and transportation device for engineering geological exploration samples and use method thereof

Technical Field

The invention relates to the technical field of geological exploration, in particular to a storage and transportation device for engineering geological exploration samples and a using method thereof.

Background

Geological exploration is investigation and research activities of surveying and detecting geology through various means and methods, determining a proper bearing stratum, determining a foundation type according to the foundation bearing capacity of the bearing stratum and calculating foundation parameters. Geological exploration mainly comprises methods such as pit, groove exploration, drilling, geophysical exploration and the like.

In the prior art, during geological exploration, substances in underground rock formations are extracted into cylindrical samples with specified diameters by geological exploration equipment, so that the geology of the extracted ground is analyzed. In the prior art, when a cylindrical sample is stored, the cylindrical sample is directly placed in a box body, and the storage box in the prior art lacks the fixing operation of the cylindrical sample, so that the cylindrical sample is very easy to shake and collide successively in the transferring process, the cylindrical sample is damaged, and the use of later detection and analysis is not facilitated, which is a great disadvantage in the prior art; in addition, the sample storage box in the prior art is inconvenient for the taking operation of the samples when in use, very easily causes disorder among the samples, is inconvenient for the selection and taking operation of the samples, is not beneficial to use, and is another disadvantage in the prior art.

Disclosure of Invention

The invention provides a storage and transportation device for engineering geological exploration samples and a using method thereof, aiming at overcoming the problem that in the prior art, samples cannot be found quickly when the samples need to be taken out due to disordered sampling and storage.

In order to achieve the purpose, the invention adopts the following technical scheme: a storage and transportation device for engineering geological exploration samples and a using method thereof comprise a storage box with a cavity arranged therein and a cubic structure as a whole, wherein a sliding bearing is embedded in the inner wall of the bottom of the storage box, a supporting pipe is rotatably connected in the middle of the sliding bearing, a rotating supporting plate is sleeved on the outer wall of the circumference of the supporting pipe close to the bottom end, three to five counter bore positions are arranged on the upper surface of the rotating supporting plate close to the edge, a guide frame with a vertical tubular structure is fixed on each counter bore position, an anti-skidding top block is slidably connected with the inner wall of the top end of the guide frame, a compression spring is fixed at the bottom end of the anti-skidding top block, a tray is placed at the top end of the anti-skidding top block, sampling pipes are screwed at the outer wall of the top end of the tray, a cover plate is fixed at the top end of the storage box, and an inlet is reserved at the top end of one of the cover plate, so that when the storage box is used, when the ground is required to be explored for sampling, the sampling position is required to be pricked by the sampling tube, the sample can be taken out and then directly placed into the storage box by screwing the sample on the tray without transferring again, and the integrity and the relevant characteristics of the sample are prevented from being damaged in the transferring process.

According to the preferable scheme of the invention, the top end of the anti-skid ejector block is arranged in a conical shape, the top end of the anti-skid ejector block is fixed with a silica gel anti-skid layer, and the bottom of the tray is reserved with a groove with an upward concave shape matched with the shape of the top end of the anti-skid ejector block.

As a preferable scheme in the invention, the lower surface of the anti-skid ejector block is provided with four jacks close to the circumferential edge, and the bottom of each jack is fixed with a guide rod matched with the jack, so that the anti-skid ejector block can be ensured to vertically descend when a heavy object is pressed at the top end of the anti-skid ejector block when in use until the opening at the top end of the sampling tube is lower than the lower surface of the inlet, and the anti-skid ejector block can still tightly abut against the bottom of the tray when being subjected to radial force along with the rotation of the supporting plate driving the sampling tube to rotate in the storage box.

As a preferable scheme in the invention, a plurality of roller grooves are formed in the lower surface of the rotating supporting plate close to the edge, and rollers are rotatably connected in the roller grooves.

In a preferable scheme of the invention, the top end of the supporting tube is inserted with an internal thread tube, the lower surface of the cover plate is provided with a rotating hole matched with the outer diameter of the internal thread tube, the top end of the internal thread tube is screwed with a 7-shaped screwing handle, the sampling tube filled with a sample can be rotated to the inside by rotating the screwing handle, then the empty sampling tube is exposed for taking, and the internal thread tube can also be used as a water filling port for filling water into a water tank at the bottom end.

As a preferable scheme in the invention, a thread groove is formed on the circumferential inner wall of the sampling tube close to the bottom end, the diameter of the thread groove is larger than the inner diameter of the sampling tube, and a clamping thread matched with the thread groove is formed on the circumferential outer wall of the top end of the tray.

As a preferable scheme in the invention, telescopic ejector rods distributed equidistantly are fixed on the circumferential outer wall of the sampling tube close to the top end, the top end of each telescopic ejector rod is connected with an inner sliding rod in a sliding manner, a ball is embedded in the top end of each inner sliding rod, and a return spring is arranged at the bottom end of each inner sliding rod, so that sliding friction between the top end of the sampling tube and the inner wall of the lower surface of the cover plate can be avoided when the sampling tube is used, and the sampling tube can be enabled to normally rotate and change positions in the storage box.

According to the preferable scheme of the invention, the bottom of the storage box is fixed with the water tank, the water tank is internally fixed with the pump body, the water outlet end of the pump body is fixed with the delivery pipe, the top end of the delivery pipe penetrates through the cover plate twice and is fixed with the spraying disc, the middle part of the delivery pipe is positioned on the upper surface of the cover plate and is fixed with the valve, and the sampling pipe is internally fixed with the spiral cutters which are distributed in a spiral shape, so that the friction force between the inner wall of the sampling pipe and a sample can be increased during sampling, and the holding capacity of the sample is improved.

As a preferable scheme in the invention, the inner wall of the top end of the sampling tube is provided with a self-locking thread, the inner wall of the top end of the sampling tube is screwed with a sealing cover, the outer wall of the sampling tube is fixed with a transparent plate box, a label card is inserted in the transparent plate box, and the outer wall of the storage box is provided with an observation window, so that the sampling tube with the sealing cover can be placed in a liquid containing process.

The use method of the storage and transportation device for engineering geological exploration samples comprises the following steps:

the method comprises the following steps: before use, an open type or a sealed type sampling tube is selected according to the characteristics of an object with a sampling function, and if the object to be sampled is solid, the sampling tube with the spiral cutter on the inner wall of the tube is taken out from the tray and then sampling is carried out;

step two: during sampling, the top end of the sampling tube is buckled at a position to be sampled on the ground, then the sampling tube is pressed and rotated at the same time, then the sampling tube is pulled upwards, and finally the end part of the sampling tube is sealed by a tray;

then inserting the written label card into the transparent plate box, and then placing the sampling tube with the sample on the top end of the anti-skid top block from the inlet;

step three: finally, the sampling tube is pressed downwards until the opening at the top end is lower than the lower surface of the cover plate, and then the sampling tube is rotated to the inside of the storage box, so that the other empty sampling tube can be popped out;

when the liquid sample is required to be contained, the liquid sample is poured into the sampling tube with the sealing cover, and then the sealing cover is sealed.

To sum up, the beneficial effect in this scheme is:

1. according to the storage and transportation device for engineering geological exploration samples, the sampling tube capable of being taken out for direct sampling is arranged, so that when the device is used and ground to-be-explored is required to be sampled, the sampling tube is only required to be pricked into a sampling position, the samples can be taken out and then directly screwed on the tray without transferring again, and can be placed in the storage box, and the completeness and relevant characteristics of the samples are prevented from being damaged in the transferring process;

2. according to the storage and transportation device for engineering geological exploration samples, the sliding top block capable of sliding up and down and the guide rod at the bottom end of the sliding top block are arranged, so that the sliding top block can still vertically descend when a heavy object is pressed at the top end of the sliding top block when the device is used until the opening at the top end of the sampling tube is lower than the lower surface of the inlet, and the sliding top block can still tightly abut against the bottom of the tray when being subjected to radial force along with the rotation of the supporting plate to drive the sampling tube to rotate inside the storage box;

3. according to the storage and transportation device for engineering geological exploration samples, the 7-shaped screwing handle is arranged, the sampling tube with the samples can be rotated to the inside by rotating the screwing handle, then the empty sampling tube is exposed for taking, and the internal thread tube can also be used as a water injection port for injecting water into the water tank at the bottom end;

4. this kind of engineering geology investigation sample is with depositing conveyer through setting up the helical cutter that is heliciform structure at the sampling tube inner wall, can avoid the top of sampling tube and the lower surface inner wall of apron to form sliding friction when using, ensures that the sampling tube can be in the inside normal rotation transform position of depositing case 1.

Drawings

FIG. 1 is a schematic cross-sectional view of a storage and transportation device for engineering geological exploration samples according to the present invention;

FIG. 2 is a schematic three-dimensional structure of a storage and transportation device for engineering geological exploration samples according to the present invention;

FIG. 3 is a schematic view of an assembly structure of a spraying mechanism of a storage and transportation device for engineering geological exploration samples, which is provided by the invention;

FIG. 4 is a schematic view of a partial cross-sectional structure of a sampling tube of a storage and transportation device for engineering geological exploration samples according to the present invention;

fig. 5 is a schematic view of an assembly structure of a sampling tube of the storage and transportation device for engineering geological exploration samples, which is provided by the invention.

In the figure: the device comprises a storage box 1, a cover plate 101, an anti-skid top block 2, a tray 3, a sampling tube 4, a thread groove 401, an observation window 5, a transparent plate box 6, a label card 601, an inlet 7, a spiral cutter 8, a telescopic ejector rod 9, an inner sliding rod 901, a screwing handle 10, a support tube 11, a delivery tube 12, a spraying plate 1201, a valve 13, a pump body 14, a sliding bearing 15, a guide frame 16, a compression spring 17, a guide rod 18, a water tank 19, a roller 20 and a rotating supporting plate 21.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

In this example

Referring to fig. 1-5, a storage and transportation device for engineering geological exploration samples comprises a storage box 1 with a cavity arranged therein and a cubic structure as a whole, wherein a sliding bearing 15 is embedded in the inner wall of the bottom of the storage box 1, a support pipe 11 is rotatably connected in the middle of the sliding bearing 15, a rotating support plate 21 is sleeved on the outer wall of the circumference of the support pipe 11 near the bottom end, three to five counter sink holes are arranged on the upper surface of the rotating support plate 21 near the edge, a guide frame 16 with a vertical tubular structure is fixed on each counter sink hole, an anti-skid top block 2 is slidably connected to the inner wall of the top end of the guide frame 16, a compression spring 17 is fixed at the bottom end of the anti-skid top block 2, a tray 3 is placed at the top end of the anti-skid top block 2, a sampling pipe 4 is screwed on the outer wall of the top end of the tray 3, a cover plate 101 is fixed at the top end of the storage box 1, and an inlet 7 is reserved at the top end of one sampling pipe 4 on the surface of the cover plate 101, thereby can be when using, when needing to treat the exploration to the ground and take a sample, only need prick sampling position with sampling tube 4, need not to shift directly to deposit case 1 on tray 3 with its spiro union again after can taking out the sample, avoid destroying the integrality and the relevant characteristic of sample because of the transfer process.

In the invention, the top end of the anti-skid top block 2 is arranged in a conical shape, a silica gel anti-skid layer is fixed at the top end of the anti-skid top block, and a groove with an upward concave shape matched with the shape of the top end of the anti-skid top block 2 is reserved at the bottom of the tray 3.

Wherein, the lower surface of anti-skidding kicking block 2 is close to circumference edge and opens and has four jacks, and the bottom in every heavy hole position all is fixed with the guide bar 18 with jack looks adaptation, thereby can ensure when using that 2 tops of anti-skidding kicking block still can vertical decline when having the heavy object suppression, the top opening part up to sampling tube 4 is less than the lower surface position of entry 7, and along with rotating the rotation of layer board 21 drive sampling tube 4 and depositing case 1 inside, anti-skidding kicking block 2 still can be tight conflict in the bottom of tray 3 when receiving radial force.

Wherein, the lower surface of the rotating supporting plate 21 is provided with a plurality of roller grooves near the edge, and the roller grooves are rotatably connected with rollers 20.

Wherein, the top of stay tube 11 is pegged graft and is had the internal thread pipe, and the lower surface of apron 101 is opened has the commentaries on classics hole with internal thread outside of tubes footpath looks adaptation, and the top spiro union of internal thread pipe has the handle 10 of twisting of 7 font structures, twists handle 10 through rotating and to rotate to inside with the sampling tube 4 that is equipped with the sample, exposes the empty sampling tube so that take immediately, and the internal thread pipe also can carry out the water injection as the water filling port to the water tank 19 of bottom.

Wherein, the circumference inner wall of sampling tube 4 is close to the bottom and is opened threaded groove 401, and the diameter of threaded groove 401 is greater than the internal diameter of sampling tube 4, and the top circumference outer wall of tray 3 is opened has the joint screw thread with threaded groove 401 looks adaptation.

The circumference outer wall of the sampling tube 4 is fixed with telescopic ejector rods 9 distributed equidistantly near the top end, the top end of each telescopic ejector rod 9 is connected with an inner sliding rod 901 in a sliding mode, the top end of each inner sliding rod 901 is embedded with a ball, and the bottom end of each inner sliding rod 901 is provided with a return spring, so that sliding friction between the top end of the sampling tube 4 and the inner wall of the lower surface of the cover plate 101 can be avoided when the sampling tube is used, and the sampling tube 4 can be enabled to normally rotate and change positions inside the storage box 1.

Wherein, the bottom of depositing case 1 is fixed with water tank 19, and is fixed with the pump body 14 in the water tank 19, and the delivery pipe 12 is fixed with to the play water end of pump body 14, and the apron 101 is fixed with spray tray 1201 twice through the top of delivery pipe 12, and the middle part of delivery pipe 12 is located the upper surface of apron 101 and is fixed with valve 13, and the inside of sampling tube 4 is fixed with the spiral cutter 8 that is the heliciform and distributes to can increase the frictional force of sampling tube 4 inner wall and sample in the time of the sample, improve the holding ability to the sample.

Wherein, the top inner wall of sampling tube 4 is opened there is self-locking screw thread, and the top inner wall spiro union of sampling tube 4 has sealed lid, and the outer wall of sampling tube 4 is fixed with transparent plate box 6, and has pegged graft in the transparent plate box 6 and have the label card 601, and the outer wall of case 1 is provided with observation window 5 to can only need place it in the sampling tube 4 that has sealed lid when needs splendid attire liquid can.

the method comprises the following steps: before use, the open type or sealed type sampling tube 4 is selected according to the characteristics of the object to be sampled, if the object to be sampled is solid, the sampling tube 4 with the spiral cutter 8 on the inner wall of the tube is taken out from the tray 3 for sampling;

step two: during sampling, the top end of the sampling tube 4 is buckled at a position to be sampled on the ground, then the sampling tube 4 is pulled upwards while rotating under the action of pressure, and finally the end part of the sampling tube 4 is sealed by the tray 3;

then inserting the written label card 601 into the transparent plate box 6, and then placing the sampling tube 4 with the sample on the top end of the anti-skid top block 2 from the inlet 7;

step three: finally, the sampling tube 4 is pressed downwards until the opening at the top end is lower than the lower surface of the cover plate 101, and then the sampling tube 4 is rotated to the inside of the storage box 1, so that the other empty sampling tube 4 can be popped out;

when the liquid sample is required to be contained, the liquid sample is poured into the sampling tube 4 with the sealing cover, and then the sealing cover is sealed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides an engineering geology investigation sample is with depositing conveyer, establishes the whole storage box (1) that is the cube structure of cavity in including, the bottom inner wall of depositing box (1) inlays and is equipped with slide bearing (15), and the centre of slide bearing (15) is rotated and is connected with stay tube (11), the circumference outer wall of stay tube (11) is close to the bottom and has cup jointed rotation layer board (21), its characterized in that, the upper surface of rotation layer board (21) is close to the edge and is provided with three to five counter bore positions, and every counter bore position all is fixed with guide frame (16) that are vertical tubular structure, and the top inner wall sliding connection of guide frame (16) has anti-skidding kicking block (2), the bottom of anti-skidding kicking block (2) is fixed with compression spring (17), and the top of anti-skidding kicking block (2) has placed tray (3), the top circumference outer wall department spiro union of tray (3) has sampling tube (4), and a cover plate (101) is fixed at the top end of the storage box (1), and an inlet (7) is reserved on the surface of the cover plate (101) positioned at the top end of one sampling tube (4).

2. The device for storing and transporting engineering geological exploration samples as claimed in claim 1, wherein the top end of the anti-skid top block (2) is arranged in a conical shape, a silica gel anti-skid layer is fixed on the top end of the anti-skid top block, and a groove with an upward concave shape matched with the shape of the top end of the anti-skid top block (2) is reserved at the bottom of the tray (3).

3. The device for storing and transporting engineering geological exploration samples as claimed in claim 2, wherein four insertion holes are formed in the lower surface of the anti-skid top block (2) close to the circumferential edge, and a guide rod (18) matched with the insertion holes is fixed at the bottom of each insertion hole.

4. The apparatus for storing and transporting samples for engineering geological exploration according to claim 1, wherein a plurality of roller grooves are formed on the lower surface of the rotating supporting plate (21) near the edge, and rollers (20) are rotatably connected in the roller grooves.

5. The device for storing and transporting engineering geological exploration samples as claimed in claim 1, wherein an internal threaded pipe is inserted into the top end of the supporting pipe (11), a rotary hole matched with the outer diameter of the internal threaded pipe is formed in the lower surface of the cover plate (101), and a 7-shaped screwing handle (10) is screwed on the top end of the internal threaded pipe.

6. The device for storing and transporting engineering geological exploration samples as claimed in claim 1, wherein a threaded groove (401) is formed on the inner circumferential wall of the sampling tube (4) near the bottom end, the diameter of the threaded groove (401) is larger than the inner diameter of the sampling tube (4), and a clamping thread matched with the threaded groove (401) is formed on the outer circumferential wall of the top end of the tray (3).

7. The device for storing and transporting engineering geological exploration samples as claimed in claim 1, wherein telescopic push rods (9) are fixed on the outer circumferential wall of the sampling tube (4) near the top end and are distributed equidistantly, an inner sliding rod (901) is slidably connected to the top end of the telescopic push rods (9), a ball is embedded in the top end of the inner sliding rod (901), and a return spring is arranged at the bottom end of the inner sliding rod (901).

8. The engineering geological survey sample storage and transportation device as claimed in claim 1, wherein a water tank (19) is fixed at the bottom of the storage tank (1), a pump body (14) is fixed in the water tank (19), a delivery pipe (12) is fixed at the water outlet end of the pump body (14), a spraying disc (1201) is fixed at the top end of the delivery pipe (12) penetrating through a cover plate (101) twice, a valve (13) is fixed on the upper surface of the cover plate (101) in the middle of the delivery pipe (12), and spiral cutters (8) distributed in a spiral shape are fixed inside the sampling pipe (4).

9. The device for storing and transporting engineering geological exploration samples as claimed in claim 1, wherein the inner wall of the top end of the sampling tube (4) is provided with self-locking threads, the inner wall of the top end of the sampling tube (4) is in threaded connection with a sealing cover, the outer wall of the sampling tube (4) is fixed with a transparent plate box (6), a label card (601) is inserted into the transparent plate box (6), and the outer wall of the storage box (1) is provided with an observation window (5).

10. The method of claim 1, wherein the step of using the storage and transportation device for engineering geological survey samples comprises the steps of:

the method comprises the following steps: before the sampling device is used, an open type or sealed type sampling tube (4) is selected according to the characteristics of an object with a sampling function, and if the object to be sampled is solid, the sampling tube (4) with the spiral cutter (8) on the inner wall of the tube is taken out of the tray (3) and then sampling is carried out;

step two: during sampling, the top end of the sampling tube (4) is buckled at a position to be sampled on the ground, then the sampling tube is pressed and rotated at the same time, then the sampling tube (4) is pulled upwards, and finally the end part of the sampling tube (4) is sealed by the tray (3);

then inserting the written label card (601) into the transparent plate box (6), and then placing the sampling tube (4) filled with the sample on the top end of the anti-skid top block (2) from the inlet (7);

step three: finally, the sampling tube (4) is pressed downwards until the opening at the top end is lower than the lower surface of the cover plate (101), and then the sampling tube is rotated to the inside of the storage box (1), so that the other empty sampling tube (4) can be ejected;

when the liquid sample is required to be contained, the liquid sample is poured into the sampling tube (4) with the sealing cover, and then the sealing cover is sealed.