Blood sample collection box with shock-absorbing buffer function

By introducing shock-absorbing and reinforcing components into the blood sample collection box, the vibration energy is dissipated by mechanical movement and the sample is stabilized in multiple directions, thus solving the problem of sample shaking during transportation and achieving effective protection and improved stability of the sample.

CN224466559UActive Publication Date: 2026-07-07CHINESE PEOPLES LIBERATION ARMY GENERAL HOSPITAL HAINAN HOSPITAL

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHINESE PEOPLES LIBERATION ARMY GENERAL HOSPITAL HAINAN HOSPITAL
Filing Date
2025-07-02
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing blood sample collection kits are prone to shaking during transportation, causing sample tubes to collide with the box walls, labels to fall off, or tubes to break. They lack effective shock absorption mechanisms, which affects sample quality and testing accuracy.

Method used

It employs shock-absorbing and reinforcing components, including guide plates, sliding plates, telescopic columns, rotating rods, rotating blocks, and drive power supplies, to dissipate vibration energy through mechanical movement and achieve multi-directional stable fixation through damping springs and clamping wheels to prevent shaking.

Benefits of technology

It effectively buffers vibrations, prevents sample damage, improves transportation stability and testing accuracy, and ensures sample quality.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model provides a blood sample collection box with shock attenuation buffering function belongs to blood detection technical field. Including shock attenuation subassembly, shock attenuation subassembly includes the guide plate of setting in the collection box bottom, all is provided with the slot in the guide plate, the guide plate is slidably provided with the sliding plate through the slot, the top of guide plate is provided with telescopic post, the lifting plate is slidably provided with telescopic post, the top of sliding plate is provided with fixed block, the top of fixed block is provided with rotary rod, the other end of rotary rod is provided with the rotating block, the rotating block is rotatably connected with lifting plate, in shock attenuation subassembly, the guide plate provides the sliding basis, the sliding plate slides along its slot, drives the top fixed block, fixed block passes through rotary rod, rotating block, linkage lifting plate slips along telescopic post, when being shocked, each component will convert the vibration into mechanical movement and consume energy, effectively buffer, attenuation vibration, provide shock attenuation protection for the article in the collection box, promote stability.
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Description

Technical Field

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

[0002] Blood sample collection kits are used for the standardized collection and preservation of blood samples. They include a sampling needle, blood collection tubes, and other accessories. The blood collection tubes contain anticoagulants and other additives to prevent blood clotting and ensure sample stability. Their airtight design prevents sample contamination and leakage, facilitates transportation and storage, and provides qualified blood samples for clinical testing and disease diagnosis, ensuring accurate test results.

[0003] Existing blood sample collection kits are prone to shaking during use, which can damage the internal materials. Specifically, bumps during transportation can cause the sample tubes to collide with the box walls, resulting in labels falling off or the tubes breaking. The design of the fixing structure is insufficient and cannot accommodate sample tubes of different sizes, exacerbating the shaking. The uneven distribution of cushioning material does not provide comprehensive protection for the samples, and the lack of a dynamic shock absorption mechanism makes it difficult to effectively buffer the samples during severe vibrations, thus affecting sample quality and testing accuracy.

[0004] Therefore, this application provides a blood sample collection box with shock absorption and cushioning function to meet the needs. Utility Model Content

[0005] The purpose of this invention is to address the shortcomings of existing technologies by proposing a blood sample collection box with shock absorption and buffering functions.

[0006] To achieve the above objectives, this utility model adopts the following technical solution: a blood sample collection box with shock absorption and buffering function, comprising a collection box and a box cover placed on top of the collection box, and further comprising:

[0007] A shock-absorbing assembly includes a guide plate disposed at the bottom of a collection box. The guide plate is provided with slots. A sliding plate is slidably disposed on the guide plate through the slots. A telescopic column is disposed at the top of the guide plate. A lifting plate is slidably disposed on the telescopic column. A fixing block is disposed at the top of the sliding plate. A rotating rod is disposed at the top of the fixing block. A rotating block is disposed at the other end of the rotating rod. The rotating block is rotatably connected to the lifting plate.

[0008] The reinforcement component includes a drive power supply disposed on the top of the box cover, a telescopic rod disposed at the bottom of the drive power supply, a cover plate disposed at the bottom of the telescopic rod, and a damage-proof pad disposed at the bottom of the cover plate.

[0009] Furthermore, each of the collection boxes has a shock-absorbing groove on its top, and a damping spring is installed inside the shock-absorbing groove. Each of the collection boxes also has a first guide groove on its inner wall.

[0010] The beneficial effects of adopting the above-mentioned further solution are: the damping spring in the shock-absorbing slot at the top of the collection box compresses and rebounds to buffer energy when subjected to shock, and the first guide groove on the inner wall guides the positioning component. The two work together to improve shock absorption and structural stability.

[0011] Furthermore, the positioning component includes a shelf disposed inside the collection box, the top of the shelf being provided with a second guide groove, a rotating shaft being disposed inside the second guide groove, a rotating plate being rotatably disposed on the rotating shaft, and a clamping wheel being disposed on the rotating plate.

[0012] The beneficial effects of adopting the above-mentioned further solution are: when the positioning component is used, the sample is placed on the placement plate, and the sample pushes the rotating plate to rotate around the rotating shaft in the second guide groove, so that the clamping wheel fits against the sample. Through the elastic action of the rotating plate and the second spring, the sample is stably clamped in multiple directions, preventing it from shaking and shifting during transportation.

[0013] Furthermore, a slot is provided on the top of the shelf, a first spring is provided inside the slot, and a dust cover is provided on the top of the slot.

[0014] The beneficial effects of adopting the above-mentioned further solution are: the first spring piece in the groove of the shelf can elastically support the items, and the dust cover closes the groove to prevent dust and other foreign objects from entering. The two work together to protect the items and keep the shelf clean.

[0015] Furthermore, a second spring is provided on one side of the rotating plate.

[0016] The beneficial effect of adopting the above-mentioned further solution is that the second spring provides elastic force to the rotating plate, which firmly clamps the sample.

[0017] Furthermore, each of the collection boxes is equipped with a handle on its outer side.

[0018] The beneficial effect of adopting the above-mentioned further solution is that the handle is located on the outside of the collection box, making it easier for users to lift and move the collection box.

[0019] Compared with the prior art, the advantages and positive effects of this utility model are as follows:

[0020] 1. In the shock absorption assembly, the guide plate provides a sliding base. The sliding plate slides along its slot, driving the top fixed block. The fixed block, through the rotating rod and the rotating block, links the lifting plate to slide along the telescopic column. When subjected to vibration, each component converts the vibration into mechanical motion to consume energy, effectively buffering and attenuating the vibration, providing shock absorption protection for the items in the collection box, and improving stability.

[0021] 2. The drive power provides power to the telescopic rod, causing it to extend downwards and move the cover plate downwards. The anti-damage pad at the bottom of the cover plate comes into contact with the positioning components and internal items. Through uniform pressure, the blood sample is firmly fixed, preventing damage to the sample due to shaking during transportation. Attached Figure Description

[0022] Figure 1 This is a front view of a blood sample collection box with shock absorption and buffering function according to this utility model;

[0023] Figure 2 This is a cross-sectional view of a blood sample collection box with shock absorption and buffering function according to the present invention;

[0024] Figure 3 This is a structural diagram of a shock-absorbing component in a blood sample collection box with shock-absorbing and buffering function according to the present invention;

[0025] Figure 4 This is a structural diagram of a reinforcement component in a blood sample collection box with shock absorption and buffering function according to the present invention;

[0026] Figure 5 This is a structural diagram of the positioning component in a blood sample collection box with shock absorption and buffering function according to the present invention.

[0027] Figure label:

[0028] 1. Collection box; 2. Box lid;

[0029] 3. Reinforcing components; 31. Drive power supply; 32. Telescopic rod; 33. Cover plate; 34. Damage-proof mat;

[0030] 4. Handle;

[0031] 5. Vibration damping assembly; 51. Vibration damping slot; 52. Damping spring; 53. First guide slot; 54. Guide plate; 55. Sliding plate; 56. Telescopic column; 57. Rotating rod; 58. Fixed block; 59. Rotating block; 510. Lifting plate;

[0032] 6. Positioning component; 61. Shelf plate; 62. Second guide groove; 63. Dust cover; 64. First spring; 65. Rotating shaft; 66. Rotating plate; 67. Second spring; 68. Clamping wheel. Detailed Implementation

[0033] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0034] like Figure 1 - Figure 4 As shown, this utility model provides a technical solution: a blood sample collection box with shock absorption and buffering function, including a collection box 1 and a box cover 2 placed on top of the collection box 1, and further including:

[0035] The shock absorption assembly 5 includes a guide plate 54 located at the bottom of the collection box 1. Each guide plate 54 has slots, and a sliding plate 55 is slidably mounted on the guide plate 54 through these slots. A telescopic column 56 is located at the top of the guide plate 54, and a lifting plate 510 is slidably mounted on the telescopic column 56. A fixing block 58 is located at the top of the sliding plate 55, and a rotating rod 57 is located at the top of the fixing block 58. A rotating block 59 is located at the other end of the rotating rod 57, and the rotating block 59 is rotatably connected to the lifting plate 510. In the shock absorption assembly 5, the guide plate 54 provides a sliding base, and the sliding plate 55 slides along its slots, driving the top fixing block 58. The fixing block 58, through the rotating rod 57 and the rotating block 59, links the lifting plate 510 to slide along the telescopic column 56. When subjected to vibration, each component converts the vibration into mechanical motion to dissipate energy, effectively buffering and attenuating the vibration, providing shock absorption protection for the items inside the collection box 1, and improving stability.

[0036] The reinforcement component 3 includes a drive power supply 31 located on top of the box cover 2. A telescopic rod 32 is located at the bottom of the drive power supply 31, and a cover plate 33 is located at the bottom of the telescopic rod 32. A damage-proof pad 34 is located at the bottom of the cover plate 33. The drive power supply 31 provides power to the telescopic rod 32, causing it to extend downward and move the cover plate 33 downward. The damage-proof pad 34 at the bottom of the cover plate 33 contacts the positioning component 6 and the internal items. By applying uniform pressure, the blood sample is firmly fixed, preventing damage to the sample due to shaking during transportation.

[0037] Furthermore, such as Figure 1 - Figure 3 As shown: The top of the collection box 1 is provided with a shock-absorbing slot 51, and a damping spring 52 is installed inside the shock-absorbing slot 51. The inner wall of the collection box 1 is provided with a first guide groove 53. The damping spring 52 in the shock-absorbing slot 51 at the top of the collection box 1 is compressed and rebounded to buffer the energy when subjected to shock. The first guide groove 53 on the inner wall is used to guide the positioning component 6. The two work together to improve shock absorption and structural stability.

[0038] The above solutions also have the problem of material fixation, such as... Figure 5 As shown: In this solution, the positioning component 6 includes a shelf 61 set inside the collection box 1. The top of each shelf 61 is provided with a second guide groove 62. A rotating shaft 65 is set inside the second guide groove 62. A rotating plate 66 is rotatably mounted on the rotating shaft 65. A clamping wheel 68 is set on the rotating plate 66. When the positioning component 6 is used, the sample is placed on the shelf 61. The sample pushes the rotating plate 66 to rotate around the rotating shaft 65 in the second guide groove 62, so that the clamping wheel 68 fits against the sample. Through the elastic action of the rotating plate 66 and the second spring 67, the sample is stably clamped in multiple directions to prevent it from shaking and shifting during transportation.

[0039] Working principle: such as Figure 1 - Figure 5 As shown, in the shock absorption assembly 5, the guide plate 54 provides a sliding base, and the sliding plate 55 slides along its slot, driving the top fixed block 58. The fixed block 58, through the rotating rod 57 and the rotating block 59, links the lifting plate 510 to slide along the telescopic column 56. When subjected to shock, each component converts the vibration into mechanical motion to consume energy, effectively buffering and attenuating the vibration, providing shock absorption protection for the items in the collection box 1, and improving stability. The damping spring 52 in the shock absorption slot 51 at the top of the collection box 1 compresses and rebounds to buffer energy when subjected to shock. The first guide groove 53 on the inner wall guides the positioning assembly 6. The two work together to improve shock absorption and structural stability. When the positioning assembly 6 is used, the sample is placed on the placement plate 61, and the sample pushes the rotating plate 66 to rotate around the rotating shaft 65 in the second guide groove 62, so that the clamping wheel 68 fits against the sample. The rotating plate 66 and the second spring 67 work together to achieve multi-directional stable clamping of the sample, preventing it from shaking and shifting during transportation. The first spring 64 in the slot of the storage plate 61 can elastically support the item, and the dust cover 63 closes the slot to prevent dust and other foreign objects from entering. The two work together to protect the item and keep the storage plate 61 clean. The second spring 67 provides elastic force to the rotating plate 66 to firmly clamp the sample. The driving power supply 31 provides power to the telescopic rod 32, which extends downward and moves the cover plate 33 downward. The anti-damage pad 34 at the bottom of the cover plate 33 contacts the positioning component 6 and the internal items. Through uniform pressure, the blood sample is firmly fixed, preventing the sample from being damaged due to shaking during transportation. The handle 4 is set on the outside of the collection box 1, making it easy for users to lift and carry the collection box.

[0040] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.

Claims

1. A blood sample collection box with shock-absorbing buffering function, comprising a collection box (1) and a box cover (2) placed on the top of the collection box (1), characterized in that, Also includes: The shock absorption assembly (5) includes a guide plate (54) disposed at the bottom of the collection box (1). The guide plate (54) is provided with slots. A sliding plate (55) is slidably disposed on the guide plate (54) through the slots. A telescopic column (56) is provided on the top of the guide plate (54). A lifting plate (510) is slidably disposed on the telescopic column (56). A fixing block (58) is provided on the top of the sliding plate (55). A rotating rod (57) is provided on the top of the fixing block (58). A rotating block (59) is provided at the other end of the rotating rod (57). The rotating block (59) is rotatably connected to the lifting plate (510). The reinforcement component (3) includes a drive power supply (31) disposed on the top of the box cover (2), a telescopic rod (32) disposed at the bottom of the drive power supply (31), a cover plate (33) disposed at the bottom of the telescopic rod (32), and a damage protection pad (34) disposed at the bottom of the cover plate (33).

2. The blood sample collection box with shock-absorbing and buffering functions according to claim 1, characterized in that, The top of each collection box (1) is provided with a shock-absorbing groove (51), and a damping spring (52) is provided inside the shock-absorbing groove (51). The inner wall of each collection box (1) is provided with a first guide groove (53).

3. The blood sample collection box with shock-absorbing and buffering functions according to claim 1, characterized in that, The collection box (1) is slidably provided with a positioning component (6) via a first guide groove (53).

4. The blood sample collection box with shock-absorbing and buffering functions according to claim 3, characterized in that, The positioning component (6) includes a shelf (61) disposed inside the collection box (1). The top of each shelf (61) is provided with a second guide groove (62). A rotating shaft (65) is disposed inside the second guide groove (62). A rotating plate (66) is rotatably disposed on the rotating shaft (65). A clamping wheel (68) is disposed on the rotating plate (66).

5. The blood sample collection box with shock-absorbing and buffering functions according to claim 4, characterized in that, The top of the shelf (61) is provided with a slot, and a first spring piece (64) is provided inside the slot of the shelf (61). A dust cover (63) is provided on the top of the slot of the shelf (61).

6. The blood sample collection box with shock-absorbing and buffering functions according to claim 4, characterized in that, A second spring (67) is provided on one side of the rotating plate (66).

7. The blood sample collection box with shock-absorbing and buffering functions according to claim 1, characterized in that, Each of the collection boxes (1) is equipped with a handle (4) on its outer side.