Geological sample transport box with shock absorption function

By introducing wheel plates, vertical dampers, anti-tilt mechanisms, and anti-shell-detachment structures into the geological sample transport box, the problem of sample damage due to bumps during transportation was solved, achieving safe transport and complete protection of the samples.

CN224376309UActive Publication Date: 2026-06-19SHAANXI COALFIELD GEOLOGY GRP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHAANXI COALFIELD GEOLOGY GRP CO LTD
Filing Date
2025-06-18
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

The existing geological sample transport boxes lack effective shock absorption and protection structures, making the samples susceptible to damage from bumps and collisions during transportation.

Method used

The system employs a combination of wheel plates, vertical dampers, anti-tilt mechanisms, anti-detachment mechanisms, and mounting mechanisms. The vertical dampers reduce vibration, the anti-tilt mechanisms maintain the stability of the storage box, and the anti-detachment and mounting mechanisms prevent samples from falling out, ensuring the safety of samples during transportation.

Benefits of technology

This effectively reduces the damage to samples caused by vibration during transportation, ensuring the integrity and safety of the samples and guaranteeing the accuracy of subsequent analyses.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the field of geological sample transportation technology, and in particular to a geological sample transportation box with shock absorption function, solving the problem that samples are easily damaged by bumps and collisions during transportation in existing technologies. A geological sample transportation box with shock absorption function includes wheel plates, a storage box mounted on the top of the wheel plates via a vertical damper, an anti-tilting mechanism between the storage box and the top of the wheel plates, several storage slots on the surface of the storage box, a support plate slidably connected inside the storage slots, and an anti-detachment shell fitted on the top of the storage box, with an installation mechanism between the anti-detachment shell and the storage box. This utility model protects the geological samples stored in the storage slots of the storage box, ensuring the safety and integrity of the geological samples.
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Description

Technical Field

[0001] This utility model relates to the field of geological sample transportation technology, and in particular to a geological sample transportation box with shock absorption function. Background Technology

[0002] Geological samples refer to physical materials collected from the Earth's surface or subsurface for studying geological structure, rock and mineral composition, geological history, geochemical characteristics, etc. Geological sampling is an indispensable foundational task in geological surveys, research, and resource development. Its core purpose is to reveal geological structure, material composition, evolutionary processes, and resource distribution patterns through the systematic collection and analysis of materials from the Earth's surface or deep layers (such as rocks, soil, water, and sediments). By collecting rock samples from different strata and analyzing their mineral composition, isotopic ages, etc., major geological events such as plate tectonics, volcanic activity, and changes in sedimentary environments can be traced. Columnar samples of lake and marine sediments (such as samples obtained by box samplers) can reflect paleoclimate and paleoenvironmental changes. Rock samples collected in fault zones or folded areas can be analyzed... Its deformation characteristics (such as the degree of fragmentation and the orientation of minerals) can be used to infer the direction of tectonic stress and the formation mechanism of geological structures, providing geological basis for earthquake risk assessment and engineering site selection. By sampling soil and rock debris geochemically (such as collecting samples of river sediments), the abnormal distribution of ore-forming elements such as copper, gold, and uranium can be analyzed to locate the approximate range of concealed ore bodies. In oil exploration, by collecting borehole cuttings or formation fluids (such as groundwater samples) and analyzing the hydrocarbons (such as methane and heavy hydrocarbons) and biomarkers, it can be determined whether the formation has oil-generating conditions or oil and gas potential. By collecting river, lake, and groundwater samples and analyzing indicators such as pH value, heavy metals (such as lead and cadmium), and organic matter (such as pesticide residues), the degree of water pollution can be assessed, providing data support for drinking water safety and water pollution control.

[0003] In the existing technology, after the geological sample collection is completed, the geological sample needs to be stored, and then these stored geological samples need to be moved and transported until the collected samples are transported to the laboratory for analysis and research.

[0004] However, existing transport containers often lack effective shock absorption and protection structures. During transportation, samples are easily damaged by bumps, causing collisions with geological samples inside the storage device and affecting subsequent research work. Utility Model Content

[0005] The purpose of this invention is to provide a geological sample transport box with shock absorption function, which solves the problem that samples are easily damaged by bumps and collisions during transportation in the prior art.

[0006] To achieve the above objectives, the present invention adopts the following technical solution:

[0007] A geological sample transport box with shock absorption function includes a wheel plate, a storage box is provided on the top of the wheel plate through a vertical damper, an anti-tilting mechanism is provided between the storage box and the top of the wheel plate, a number of storage slots are opened on the surface of the storage box, a bearing plate is slidably connected inside the storage slots, an anti-detachment shell is fitted on the top of the storage box, and an installation mechanism is provided between the anti-detachment shell and the storage box.

[0008] Preferably, the anti-tilting mechanism includes four insertion rods fixedly connected to the bottom of the storage box, and four receiving cylinders fixedly connected to the top of the wheel plate, with the insertion rods passing through the interior of adjacent receiving cylinders.

[0009] Preferably, two U-shaped anti-detachment rods are fixedly connected to the top of the wheel plate and the bottom of the storage box. One end of the anti-detachment rod passes through the surface of the adjacent anti-detachment rod, and one end of the anti-detachment rod is triangular.

[0010] Preferably, the installation mechanism includes two L-shaped fixing rods fixedly connected to the top of the storage box, and two auxiliary slots are opened on the top of the anti-detachment device, with the fixing rods passing through the interior of the adjacent auxiliary slots.

[0011] Preferably, the surface of the anti-shell is provided with a movable groove, and a movable block is elastically connected inside the movable groove by a compression spring. A U-shaped anti-moving block is fixedly connected to the top of the movable block. Both ends of the anti-moving block are U-shaped, and a fixing rod passes through one end of the adjacent anti-moving block.

[0012] Preferably, the anti-shelling surface is threaded with several screws, and the surface of the screws is rotatably connected with anti-collision pads, which are inserted into the interior of adjacent storage tanks.

[0013] This utility model has the following beneficial effects:

[0014] When transporting geological samples, the vertical dampers on the wheel plates can easily reduce the vibration of the storage box caused by bumps, thereby protecting the geological samples in the storage tank and ensuring the safety and integrity of the geological samples. Attached Figure Description

[0015] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0016] Figure 1 This is a schematic diagram of the structure of this utility model;

[0017] Figure 2 for Figure 1Side view of the installation mechanism;

[0018] Figure 3 for Figure 1 Side view of the anti-displacement mechanism;

[0019] Figure 4 for Figure 3 Side view of the storage box;

[0020] Figure 5 for Figure 1 A cross-sectional view of the anti-shelling agent.

[0021] In the diagram: 1. Wheel plate; 2. Vertical damper; 3. Storage box; 4. Anti-tilting mechanism; 5. Storage slot; 6. Bearing plate; 7. Anti-detachment shell; 8. Installation mechanism; 9. Screw; 10. Anti-collision pad; 401. Insertion rod; 402. Receiving cylinder; 403. Anti-detachment rod; 801. Fixing rod; 802. Auxiliary slot; 803. Moving slot; 804. Compression spring; 805. Moving block; 806. Anti-movement block. Detailed Implementation

[0022] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present utility model and are not intended to limit the present utility model.

[0023] Reference Figure 1-5A geological sample transport box with shock absorption function includes a wheel plate 1, which is a mobile transport vehicle for conveniently moving and transporting geological samples. The wheels conveniently move the geological samples on the wheel plate 1 for transport. A storage box 3 is provided on the top of the wheel plate 1 via a vertical damper 2. The storage box 3 stores the geological samples. When it is necessary to transport the geological samples, the storage box 3 is transported by the wheel plate 1, thus facilitating the transport of the geological samples. When vibration is encountered during transportation, the vertical damper 2 can reduce the damage to the geological samples inside the storage box 3 and reduce the transmission of vibration. The vertical damper 2 is an existing shock-absorbing structure. An anti-tilting mechanism 4 is provided between the storage box 3 and the top of the wheel plate 1. When vibration occurs during transportation, the anti-tilting mechanism 4 can ensure that the storage box 3 does not shake on the wheel plate 1. To prevent tilting and ensure the stability of the storage box 3, several storage slots 5 are formed on the surface of the storage box 3. A support plate 6 is slidably connected inside the storage slot 5. When it is necessary to store geological samples, the support plate 6 needs to be pulled out, and then the geological sample is placed inside the support plate 6. Then, the support plate 6 is pushed into the storage slot 5 to store the geological sample. The top of the storage box 3 is fitted with an anti-detachment shell 7. After the geological sample is placed into the storage slot 5, the anti-detachment shell 7 is fitted inside the storage box 3 from top to bottom to prevent the geological sample from detaching from the storage slot 5 and protect the geological sample. An installation mechanism 8 is provided between the anti-detachment shell 7 and the storage box 3. The installation mechanism 8 ensures that the anti-detachment shell 7 will not easily separate from the storage box 3 and can stably protect the geological sample inside the storage slot 5.

[0024] Furthermore, the anti-tilting mechanism 4 includes four insertion rods 401 fixedly connected to the bottom of the storage box 3, and four receiving cylinders 402 fixedly connected to the top of the wheel plate 1. The insertion rods 401 pass through the interior of adjacent receiving cylinders 402. When subjected to vibration, the storage box 3 will move up and down to a certain extent on the wheel plate 1. During this process, the insertion rods 401 will move up and down inside the receiving cylinders 402, thereby ensuring that the storage box 3 will not have a hard collision or tilt, thus ensuring the stability of the storage box 3 and enabling the storage box 3 to better protect the geological samples.

[0025] Furthermore, two U-shaped anti-detachment rods 403 are fixedly connected to the top of the wheel plate 1 and the bottom of the storage box 3. One end of the anti-detachment rod 403 passes through the surface of the adjacent anti-detachment rod 403, and the other end of the anti-detachment rod 403 is triangular. When the storage box 3 is vibrated and moves up and down on the wheel plate 1, it can be restricted by the inverted anti-detachment rods 403 to prevent the storage box 3 from vibrating too much and causing it to detach from the wheel plate 1. This can protect the storage box 3 and enable the storage box 3 to safely transport geological samples.

[0026] Furthermore, the installation mechanism 8 includes two L-shaped fixing rods 801 fixedly connected to the top of the storage box 3. The top of the anti-detachment shell 7 has two auxiliary slots 802. The fixing rods 801 pass through the adjacent auxiliary slots 802. After the geological sample is placed into the storage slot 5 on the storage box 3, the anti-detachment shell 7 is aligned with the storage box 3 from top to bottom, and then the anti-detachment shell 7 is moved downward. During this process, the fixing rods 801 can pass through the auxiliary slots 802 on the anti-detachment shell 7. The fixing rods 801 are restricted by the two auxiliary slots 802 to ensure that the anti-detachment shell 7 is stably restricted on the storage box 3, thereby ensuring the protection of the storage box 3 by the anti-detachment shell 7 and preventing the geological sample inside the storage slot 5 from detaching.

[0027] Furthermore, the surface of the anti-detachment shell 7 is provided with a movable groove 803. Inside the movable groove 803, a movable block 805 is elastically connected via a compression spring 804. A U-shaped anti-movement block 806 is fixedly connected to the top of the movable block 805. Both ends of the anti-movement block 806 are U-shaped. A fixing rod 801 passes through one end of an adjacent anti-movement block 806. During the installation of the anti-detachment shell 7, the anti-movement block 806 needs to be pulled away from the fixing rod 801 first. After the anti-detachment shell 7 is installed, the anti-movement block 806 is released. At this time, the movable block 805 can move by the elastic force of the compression spring 804 inside the movable groove 803, so that one end of the anti-movement block 806 restricts the fixing rod 801, thereby ensuring the stability of the fixing rod 801, thus restricting the anti-detachment shell 7, ensuring the stability of the anti-detachment shell 7 in protecting the storage box 3, and ensuring the safety of the geological sample.

[0028] Furthermore, the surface of the anti-detachment shell 7 is threaded with several screws 9, and the surface of the screws 9 is rotatably connected with anti-collision pads 10. The anti-collision pads 10 are inserted into the interior of the adjacent storage tank 5. A certain gap is left between the anti-detachment shell 7 and the storage box 3 to prevent the anti-collision pads 10 from affecting the anti-detachment shell 7 from leaving the storage box 3. After the anti-detachment shell 7 is put on the storage box 3, the screws 9 are rotated so that the anti-collision pads 10 can enter the interior of the adjacent storage tank 5 to squeeze the geological sample, thereby ensuring the safety of the geological sample and preventing the geological sample from being damaged by collision inside the storage tank 5.

[0029] In summary:

[0030] When geological samples need to be transported, they are first placed into the storage slot 5 on the storage box 3. During this process, the support plate 6 can be pulled out first, then the sample can be placed on the support plate 6, and then the support plate 6 can be returned to the storage slot 5. After that, the anti-detachment shell 7 is put on the storage box 3. During this process, the fixing rod 801 needs to pass through the auxiliary slot 802, and the anti-moving block 806 needs to abut against the fixing rod 801 to ensure the stability of the anti-detachment shell 7 and fix it on the storage box 3. The anti-moving block 806 can restrict the fixing rod 801 by the force applied to the moving block 805 by the compression spring 804 inside the moving slot 803. Then, the screw 9 on the anti-detachment shell 7 is rotated so that the anti-collision pad 10 on the screw 9 enters the adjacent storage slot 5 to protect the geological sample. The sample is restricted to protect the geological sample during transportation. The storage box 3 is then moved by the movement of the wheel plate 1. When encountering vibration, the vertical damper 2 can buffer the storage box 3 to ensure the safety of the geological sample inside the storage box 3. During the up and down movement of the storage box 3, the insertion rod 401 moves in and out of the receiving cylinder 402 to ensure the stability of the storage box 3, and the anti-detachment rod 403 prevents the storage box 3 from detaching from the wheel plate 1. With the above structure, when it is necessary to transport geological samples, vibration protection can be easily provided to prevent the geological sample from being damaged by collision inside the storage tank 5 due to vibration caused by bumps during transportation. This ensures the safety and integrity of the geological sample during transportation, facilitating subsequent analysis and use.

[0031] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. A geological sample transport box with shock absorption function, comprising wheel plates (1), characterized in that, The top of the wheel plate (1) is provided with a storage box (3) via a vertical damper (2). An anti-tilting mechanism (4) is provided between the storage box (3) and the top of the wheel plate (1). Several storage slots (5) are opened on the surface of the storage box (3). A bearing plate (6) is slidably connected inside the storage slot (5). An anti-detachment shell (7) is fitted on the top of the storage box (3). An installation mechanism (8) is provided between the anti-detachment shell (7) and the storage box (3).

2. The geological sample transport box with shock absorption function according to claim 1, characterized in that, The anti-tilt mechanism (4) includes four insertion rods (401) fixedly connected to the bottom of the storage box (3), and four receiving cylinders (402) fixedly connected to the top of the wheel plate (1). The insertion rods (401) pass through the interior of the adjacent receiving cylinders (402).

3. A geological sample transport box with shock absorption function according to claim 1, characterized in that, The top of the wheel plate (1) and the bottom of the storage box (3) are both fixedly connected to two U-shaped anti-detachment rods (403). One end of the anti-detachment rod (403) passes through the surface of the adjacent anti-detachment rod (403), and one end of the anti-detachment rod (403) is triangular.

4. A geological sample transport box with shock absorption function according to claim 1, characterized in that, The installation mechanism (8) includes two L-shaped fixing rods (801) fixedly connected to the top of the storage box (3). The top of the anti-detachment shell (7) has two auxiliary slots (802), and the fixing rods (801) pass through the adjacent auxiliary slots (802).

5. A geological sample transport box with shock absorption function according to claim 4, characterized in that, The surface of the anti-detachment shell (7) is provided with a movable groove (803). Inside the movable groove (803), a movable block (805) is elastically connected by a compression spring (804). A U-shaped anti-moving block (806) is fixedly connected to the top of the movable block (805). Both ends of the anti-moving block (806) are U-shaped. The fixing rod (801) passes through one end of the adjacent anti-moving block (806).

6. A geological sample transport box with shock absorption function according to claim 1, characterized in that, The surface of the anti-detachment shell (7) is threaded with several screws (9), and the surface of the screws (9) is rotatably connected with anti-collision pads (10), which are inserted into the interior of the adjacent storage tank (5).