A geological exploration sample carrying tool

By designing a toolbox with a sliding support plate and a limiting slider, the problem that existing geological exploration sample carrying tools cannot store different types of samples at the same time has been solved, realizing flexible storage and stable carrying within the same tool.

CN224393463UActive Publication Date: 2026-06-23SHANXI ZHONGBANG GEOLOGICAL SURVEY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANXI ZHONGBANG GEOLOGICAL SURVEY CO LTD
Filing Date
2025-08-15
Publication Date
2026-06-23

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Abstract

The application relates to a geological exploration sample carrying tool and relates to the technical field of sample carrying, which comprises a tool box, a box cover and a clamping assembly; the top of the tool box is in an open shape, a first supporting plate is arranged in the tool box, and the first supporting plate is fixedly connected with the tool box; a first sample storage hole is arranged on the first supporting plate and used for storing a test tube; a first limiting sliding block is fixedly arranged in the tool box; a second limiting sliding block is fixedly arranged in the tool box; a second supporting plate is horizontally arranged in the tool box, the second supporting plate is placed on the first limiting sliding block and the second limiting sliding block and is slidably connected with the tool box; a second sample storage hole is arranged on the second supporting plate; a plurality of first limiting sliding blocks, second limiting sliding blocks and second supporting plates are arranged along the length direction of the tool box; the box cover is arranged at the top end of the tool box; the clamping assembly is arranged on the box cover and used for connecting the box cover and the tool box. The application has the effect that different types of samples can be easily stored in the same tool.
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Description

Technical Field

[0001] This application relates to the technical field of sample carrying, and in particular to a geological exploration sample carrying tool. Background Technology

[0002] Geological exploration sample carrying tools are specialized tools used to carry various types of collected samples during geological exploration. By storing the samples, they can prevent damage, contamination, or confusion during transportation, thus ensuring the reliability of subsequent experimental analysis results.

[0003] Currently, existing geological exploration sample carrying tools typically include a box, a fixing strap, and a reagent kit. When collecting solid samples such as rock cores, operators place the rock cores inside the box and secure them with the fixing strap. When collecting liquid samples such as water samples, operators put the water sample into a test tube and then place the test tube into the reagent kit.

[0004] Existing geological exploration sample carrying tools require operators to prepare different carrying devices depending on the type of sample collected, making it impossible to flexibly store different types of samples using the same tool. Utility Model Content

[0005] To facilitate the storage of different types of samples in the same tool, this application provides a geological exploration sample carrying tool.

[0006] This application provides a geological exploration sample carrying tool, which adopts the following technical solution:

[0007] A geological exploration sample carrying tool includes a toolbox, a lid, and a snap-fit ​​assembly. The toolbox is horizontally positioned with an open top. A first support plate is horizontally positioned inside the toolbox, located at the bottom of the toolbox and fixedly connected to it. A first sample storage hole is provided on the first support plate for storing test tubes. A first limiting slider is vertically positioned inside the toolbox and fixedly connected to it. A second limiting slider is vertically positioned inside the toolbox and fixedly connected to it. A second support plate is horizontally positioned inside the toolbox, resting on the first and second limiting sliders and slidably connected to it. A second sample storage hole is provided on the second support plate, directly opposite the first sample storage hole. Multiple first, second, and second limiting sliders and second support plates are provided along the length of the toolbox. The lid is horizontally positioned at the top opening of the toolbox. The snap-fit ​​assembly is located on the lid and connects the lid to the toolbox.

[0008] By adopting the above technical solution, during use, the operator can choose whether to slide the second support plate out of the toolbox according to the sample type; when storing liquid samples, the test tube is inserted into the first and second sample storage holes, making the test tube easy to store; when storing solid samples, the operator slides multiple second support plates out of the toolbox according to the size of the solid sample, and the operator passes the cable tie through the first sample storage hole to fix the solid sample on the first support plate, making the solid sample easy to store, thus making it easy to store different types of samples in the same tool.

[0009] Optionally, the second support plate is provided with a first clearance groove and a second clearance groove; when the second support plate is rotated 180 degrees, the first clearance groove is directly opposite to the first limiting slider, the second clearance groove is directly opposite to the second limiting slider, and the second sample storage hole is misaligned with the first sample storage hole.

[0010] By adopting the above technical solution, when storing solid samples, the operator can rotate the second support plate 180 degrees and pass the cable tie used to fix the solid sample through the second sample storage hole, so that the second support plate can easily slide to the bottom of the toolbox through the first limit slider and the second limit slider, thereby making the second support plate easy to store.

[0011] Optionally, the snap-fit ​​assembly includes a sliding rod and a snap-fit ​​block; the toolbox has a sliding groove, and the bottom wall of the sliding groove has a rotating groove; the sliding rod is inserted into the box cover, and one end is located in the rotating groove; the snap-fit ​​block is fixedly mounted on the sliding rod and is located in the rotating groove.

[0012] By adopting the above technical solution, after the sample is stored, the operator places the lid on the top of the toolbox and inserts the sliding rod into the sliding groove. When the lid closes the top opening of the toolbox, the operator rotates the sliding rod, which drives the locking block to rotate into the rotating groove, making it difficult for the lid to detach from the toolbox, thus making it easy for the operator to carry the toolbox.

[0013] Optionally, the snap-fit ​​assembly, the sliding groove, and the rotating groove are provided in two sets, and are respectively located on both sides of the toolbox along its length.

[0014] By adopting the above technical solution, during use, the snap-fit ​​components on both sides simultaneously fix the lid and the toolbox from both ends, improving the stability of the connection between the lid and the toolbox.

[0015] Optionally, the toolbox is provided with a partition component for dividing the internal space of the toolbox.

[0016] By adopting the above technical solution, when in use, the operator can divide the inside of the toolbox into multiple independent spaces using the partition components, making it easy to distinguish the storage locations of solid samples and liquid samples.

[0017] Optionally, the partition assembly includes a partition plate; a first partition groove is formed on the inner side wall of the toolbox, and a second partition groove is formed on the inner side wall of the toolbox away from the first partition groove; a receiving groove is formed on one side of the lid, and the partition plate is horizontally disposed in the receiving groove.

[0018] By adopting the above technical solution, when the operator slides the second support plate to the bottom of the toolbox, the operator takes out the partition plate from the receiving slot. The two ends of the partition plate are inserted into the first partition slot and the second partition slot respectively, realizing the spatial division inside the toolbox. At the same time, the second sample storage hole on the second support plate that slides to the bottom of the toolbox is misaligned with the sample storage hole on the first support plate, making it easy to store soil samples on the second support plate at the bottom of the toolbox.

[0019] Optionally, the partition assembly further includes a sliding plate and a spring; a placement groove is provided on one side of the partition plate; the sliding plate is vertically disposed in the placement groove and slidably connected to the partition plate, and a handle is fixedly connected to one side of the sliding plate; the spring is located in the placement groove, and its two ends are fixedly connected to the sliding plate and the partition plate respectively.

[0020] By adopting the above technical solution, when the partition plate needs to be removed from the receiving slot, the operator pulls the handle to remove the partition plate. After the partition plate is inserted into the toolbox, the operator places the lid on the top of the toolbox. The lid presses against the handle, and the handle drives the sliding plate to slide into the placement slot. The spring is in a compressed state, so that when the toolbox is closed, the space on both sides of the partition plate is separated.

[0021] Optionally, the top of the lid is hinged with a handle.

[0022] By adopting the above technical solution, the operator can easily carry the equipment through the handle, thus improving the portability of the equipment.

[0023] In summary, this application includes at least one of the following beneficial technical effects:

[0024] 1. By incorporating snap-fit ​​components, the lid and toolbox can be easily connected;

[0025] 2. By setting up dividers, the internal space of the toolbox can be easily divided. Attached Figure Description

[0026] Figure 1 This is a structural schematic diagram of an embodiment of this application;

[0027] Figure 2 This is a cross-sectional view of an embodiment of this application;

[0028] Figure 3 This is a partial cross-sectional view of the sliding groove in an embodiment of this application;

[0029] Figure 4 This is a cross-sectional view of an embodiment of this application for showing the placement slot;

[0030] Figure 5 This is a cross-sectional view of the display card connector block according to an embodiment of this application;

[0031] Figure 6 This is a cross-sectional view of an embodiment of this application to show the sliding state of the second support plate.

[0032] Explanation of reference numerals in the attached figures:

[0033] 1. Toolbox; 11. First support plate; 111. First sample storage hole; 12. First limiting slider; 13. Second limiting slider; 14. Second support plate; 141. Second sample storage hole; 142. First clearance groove; 143. Second clearance groove; 15. Sliding groove; 16. Rotating groove; 17. First dividing groove; 18. Second dividing groove; 2. Box cover; 21. Receiving groove; 22. Handle; 3. Snap-fit ​​assembly; 31. Sliding rod; 311. Rotating handle; 32. Snap-fit ​​block; 4. Dividing assembly; 41. Dividing plate; 411. Placement groove; 42. Sliding plate; 421. Handle; 43. Spring. Detailed Implementation

[0034] The following is in conjunction with the appendix Figure 1-6 This application will be described in further detail.

[0035] This application discloses a geological exploration sample carrying tool. (Refer to...) Figure 1 A geological exploration sample carrying tool includes a toolbox 1, a lid 2, a snap-fit ​​assembly 3, and a partition assembly 4. The toolbox 1 is horizontally positioned and rectangular in shape, with an open top. The lid 2 is horizontally positioned at the top opening of the toolbox 1. The snap-fit ​​assembly 3 is located on the lid 2 and serves to connect the lid 2 and the toolbox 1. The partition assembly 4 is located on the toolbox 1 and serves to divide the internal space of the toolbox 1.

[0036] In use, the partition component 4 divides the inside of the toolbox 1 into multiple spaces. After the operator places the sample inside the toolbox 1, the operator closes the lid 2 on the top opening of the toolbox 1, and the snap-fit ​​component 3 connects the lid 2 and the toolbox 1.

[0037] Reference Figure 2A first support plate 11 is horizontally arranged inside the toolbox 1. The first support plate 11 is rectangular and located at the bottom of the toolbox 1, and is fixedly connected to the toolbox 1. A first sample storage hole 111 is provided on the first support plate 11. The first sample storage hole 111 is circular and is used to store test tubes. A first limiting slider 12 is vertically arranged inside the toolbox 1. The first limiting slider 12 is rectangular and is fixedly connected to the toolbox 1. Multiple first limiting sliders 12 are spaced apart along the length of the toolbox 1. A second limiting slider 13 is vertically arranged inside the toolbox 1. The second limiting slider 13 is rectangular and is fixedly connected to the toolbox 1. Multiple second limiting sliders 13 are spaced apart along the length of the toolbox 1, and each corresponds to one of the multiple first limiting sliders 12.

[0038] A second support plate 14 is horizontally arranged inside the toolbox 1. The second support plate 14 is rectangular and rests on the first limiting slider 12 and the second limiting slider 13. The second support plate 14 is slidably connected to the toolbox 1 in the vertical direction. Multiple second support plates 14 are arranged along the length of the toolbox 1, each corresponding to one of the multiple first limiting sliders 12. A second sample storage hole 141 is formed on the second support plate 14. The second sample storage hole 141 is rectangular and is directly opposite to the first sample storage hole 111. A first clearance groove 142 is formed on the second support plate 14. The first clearance groove 142 is rectangular. A second clearance groove 143 is formed on the second support plate 14. The second clearance groove 143 is rectangular.

[0039] Reference Figure 3 The toolbox 1 has two sets of sliding grooves 15, located on opposite sides of its length. A rotating groove 16 is also provided on the toolbox 1, communicating with the sliding grooves 15. Two sets of rotating grooves 16 correspond one-to-one with the two sets of sliding grooves 15. A first dividing groove 17, rectangular in shape, is provided on the inner wall of the toolbox 1, located between two adjacent second support plates 14. A second dividing groove 18, rectangular in shape, is provided on the inner wall of the toolbox 1 away from the first dividing groove 17. Multiple first dividing grooves 17 and second dividing grooves 18 are spaced apart along the length of the toolbox 1.

[0040] Reference Figure 4 The lid 2 is rectangular in shape, and a receiving groove 21 is provided on one side of the lid 2. The receiving groove 21 is rectangular in shape, and multiple receiving grooves 21 are provided along the length of the lid 2, corresponding one-to-one with multiple first partition grooves 17. A handle 22 is hinged to the top of the lid 2.

[0041] When in use, the operator can choose whether to slide the second support plate 14 out of the toolbox 1 according to the sample type; when storing liquid samples, the test tube is inserted into the first sample storage hole 111 and the second sample storage hole 141 to make the test tube easy to store.

[0042] Reference Figure 5 and Figure 6 When it is necessary to store solid samples, the operator flips at least one second support plate 14 180 degrees according to the size of the solid sample. The operator passes the cable tie used to fix the solid sample through the second sample storage hole 141. The second support plate 14 slides to the bottom of the toolbox 1 through the first limiting slider 12 and the second limiting slider 13.

[0043] Reference Figure 1 and Figure 5 Two sets of snap-fit ​​components 3 are provided, located on opposite sides of the toolbox 1 along its length. Each snap-fit ​​component 3 includes a sliding rod 31 and a snap-fit ​​block 32. The sliding rod 31 is vertically inserted into the cover 2 and is circular in shape, with one end located within the rotating groove 16. A handle 311 is horizontally positioned at the top of the sliding rod 31 and is fixedly connected to it. The snap-fit ​​block 32 is fixedly mounted on the sliding rod 31 and is rectangular in shape, located within the rotating groove 16.

[0044] After the sample is stored, the operator places the lid 2 on top of the toolbox 1 and inserts the sliding rod 31 into the sliding groove 15. After the lid 2 closes the top opening of the toolbox 1, the operator rotates the sliding rod 31, which drives the locking block 32 to rotate into the rotating groove 16.

[0045] Reference Figure 1 and Figure 4 Multiple partition components 4 are provided, each corresponding to one of the multiple receiving slots 21. Each partition component 4 includes a partition plate 41, a sliding plate 42, and a spring 43. The partition plate 41 is horizontally disposed within the receiving slot 21 and is rectangular in shape. The partition plate 41 is slidably connected to the lid 2 along the width direction of the lid 2. A placement slot 411 is provided on one side of the partition plate 41. The sliding plate 42 is vertically disposed within the placement slot 411 and is rectangular in shape. The sliding plate 42 is slidably connected to the partition plate 41 along the width direction of the lid 2. A handle 421 is horizontally disposed on one side of the sliding plate 42 and is fixedly connected to the sliding plate 42. Multiple springs 43 are spaced apart along the length direction of the sliding plate 42.

[0046] After the operator slides the second support plate 14 to the bottom of the toolbox 1, the operator pulls the handle 421 to remove the partition plate 41 from the receiving slot 21. The two ends of the partition plate 41 are inserted into the first partition slot 17 and the second partition slot 18, respectively. After the partition plate 41 is inserted into the toolbox 1, the operator places the lid 2 on top of the toolbox 1. The lid 2 presses against the handle 421, and the handle 421 drives the sliding plate 42 to slide into the placement slot 411, and the spring 43 is in a compressed state.

[0047] The implementation principle of a geological exploration sample carrying tool according to an embodiment of this application is as follows: When storing liquid samples, the operator inserts the test tube into the first sample storage hole 111 and the second sample storage hole 141. When storing solid samples, the operator rotates multiple second support plates 14 by 180 degrees according to the size of the solid sample. The operator passes the cable ties used to fix the solid sample through the second sample storage hole 141, and the second support plates 14 slide to the bottom of the toolbox 1 via the first limiting slider 12 and the second limiting slider 13.

[0048] After the operator slides the second support plate 14 to the bottom of the toolbox 1, the operator pulls the handle 421 to remove the partition plate 41 from the receiving slot 21. The two ends of the partition plate 41 are inserted into the first partition slot 17 and the second partition slot 18, respectively. After the partition plate 41 is inserted into the toolbox 1, the operator places the lid 2 on top of the toolbox 1. The lid 2 presses against the handle 421, and the handle 421 drives the sliding plate 42 to slide into the placement slot 411, and the spring 43 is in a compressed state.

[0049] When soil samples need to be stored, the operator slides the second support plate 14 to the bottom of the toolbox 1. The second sample storage hole 141 on the second support plate 14 is misaligned with the first sample storage hole 111 on the first support plate 11. The partition plate 41 is inserted into the first partition groove 17 and the second partition groove 18, so that the box cover 2, the first support plate 11, the second support plate 14 and the partition plate 41 form a sealed space, thereby making it difficult for soil to fall into other storage areas of the toolbox 1.

[0050] After the sample is stored, the operator places the lid 2 on top of the toolbox 1 and inserts the sliding rod 31 into the sliding groove 15. After the lid 2 closes the top opening of the toolbox 1, the operator rotates the sliding rod 31, which drives the locking block 32 to rotate into the rotating groove 16. The operator then carries the equipment through the handle 22.

[0051] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A geological sample carrying tool, characterized by: The utility model provides a tool box, which comprises a tool box (1), a box cover (2) and a clamping assembly (3), wherein the tool box (1) is horizontally arranged and has an open top; a first supporting plate (11) is horizontally arranged in the tool box (1) and is fixedly connected to the bottom of the tool box (1); a first sample storage hole (111) is formed in the first supporting plate (11) and used for storing a test tube; a first limiting sliding block (12) is vertically arranged in the tool box (1) and fixedly connected to the tool box (1); a second limiting sliding block (13) is vertically arranged in the tool box (1) and fixedly connected to the tool box (1); a second supporting plate (14) is horizontally arranged in the tool box (1) and slidably connected to the tool box (1) and placed on the first limiting sliding block (12) and the second limiting sliding block (13); a second sample storage hole (141) is formed in the second supporting plate (14) and arranged opposite to the first sample storage hole (111); a plurality of first limiting sliding blocks (12), second limiting sliding blocks (13) and second supporting plates (14) are arranged along the length direction of the tool box (1); the box cover (2) is horizontally arranged at the top opening of the tool box (1); the clamping assembly (3) is arranged on the box cover (2) and used for connecting the box cover (2) and the tool box (1).

2. The geological sample carrying tool according to claim 1, characterized in that: A first accommodating groove (142) and a second accommodating groove (143) are formed in the second supporting plate (14); when the second supporting plate (14) is turned over by 180 degrees, the first accommodating groove (142) is arranged opposite to the first limiting sliding block (12), the second accommodating groove (143) is arranged opposite to the second limiting sliding block (13), and the second sample storage hole (141) is dislocated from the first sample storage hole (111).

3. The geological sample carrying tool according to claim 1, characterized in that: The clamping assembly (3) comprises a sliding rod (31) and a clamping block (32); a sliding groove (15) is formed in the tool box (1), and a rotating groove (16) is formed in the bottom wall of the sliding groove (15); the sliding rod (31) is inserted into the box cover (2) and located in the rotating groove (16); and the clamping block (32) is fixedly arranged on the sliding rod (31) and located in the rotating groove (16).

4. A geological sample carrying tool according to claim 3, characterized in that: The clamping assembly (3), the sliding groove (15) and the rotating groove (16) are arranged in two groups and located on the two sides of the length direction of the tool box (1).

5. The geological sample carrying tool according to claim 1, characterized in that: The tool box (1) is provided with a separation assembly (4) for separating the internal space of the tool box (1).

6. A geological sample carrying tool according to claim 5, characterized in that: The separation assembly (4) comprises a separation plate (41); a first separation groove (17) is formed in the inner side wall of the tool box (1), and a second separation groove (18) is formed in the inner side wall of the tool box (1) away from the first separation groove (17); a containing groove (21) is formed in one side of the box cover (2), and the separation plate (41) is horizontally arranged in the containing groove (21).

7. A geological sample carrying tool according to claim 6, characterized in that: The separation assembly (4) further comprises a sliding plate (42) and a spring (43); one side of the separation plate (41) is provided with a placing groove (411); the sliding plate (42) is vertically arranged in the placing groove (411) and is in sliding connection with the separation plate (41), and one side of the sliding plate (42) is fixedly connected with a handle (421); the spring (43) is located in the placing groove (411) and has two ends fixedly connected with the sliding plate (42) and the separation plate (41) respectively.

8. The geological sample carrying tool according to claim 1, characterized in that: The top end of the box cover (2) is hingedly connected with a handle (22).