A cervical cancer vaccine reagent tube stacking device
By combining the placement base, electric telescopic rod, and clamping plate, the problem of existing devices being unable to adapt to reagent tubes of different diameters is solved, achieving stable clamping and stable stacking of multiple devices, thus improving the applicability and safety of the cervical cancer vaccine reagent tube stacking device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 高阳
- Filing Date
- 2025-06-16
- Publication Date
- 2026-07-14
AI Technical Summary
Existing cervical cancer vaccine test tube stacking devices are not suitable for storing test tubes of different diameters, and multiple devices are prone to collapse when stacked.
The device employs a combination design of a placement base, an electric telescopic rod, a clamping plate, a pressure sensor, and an intelligent controller. The electric telescopic rod pushes the clamping plate to hold the reagent tubes, and the pressure sensor and pressure-sensing spring detect the force to automatically clamp reagent tubes of different diameters. At the same time, multiple devices are stabilized by a stacking assembly.
It enables stable clamping of reagent tubes of different diameters and stable stacking of multiple devices, improving the applicability and safety of the device.
Smart Images

Figure CN224491986U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a reagent tube stacking device, specifically a cervical cancer vaccine reagent tube stacking device, belonging to the field of medical device technology. Background Technology
[0002] Vaccines are preventive biological products used for human immunization to prevent and control the occurrence and spread of infectious diseases. In the storage and management of cervical cancer vaccines, stacking racks are required to store the test tubes.
[0003] Chinese Patent Publication CN213995980U discloses a stacking structure for cervical cancer vaccine test tubes. Due to the foldability of the folded cloth and the telescopic nature of the miniature telescopic rod, it is very convenient to stretch and takes up little space, making it easy to store. When dust protection or sun protection is not required, the folded cloth and miniature telescopic rod can be retracted into the handle, and the connecting seat can also be fastened into the handle, allowing the handle to be lowered.
[0004] The aforementioned patented technology is not applicable to the storage of test tubes of different diameters in practical use. When storing cervical cancer vaccine test tubes of different specifications, different stacking devices are often required, and multiple devices are prone to collapse when stacked, reducing the applicability of the cervical cancer vaccine test tube stacking device. Therefore, a cervical cancer vaccine test tube stacking device is proposed here. Utility Model Content
[0005] This invention proposes a stacking device for cervical cancer vaccine test tubes to solve the problems in the prior art that it cannot be used to store test tubes of different diameters and that multiple devices are prone to collapse when stacked.
[0006] This utility model is achieved through the following technical solution: a cervical cancer vaccine reagent tube stacking device, including a placement seat, wherein an auxiliary mechanism is provided inside the placement seat;
[0007] The auxiliary mechanism includes six placement holes, each of which is located on the upper surface of the placement base. The placement base contains six sets of electrically operated telescopic rods. Each set of telescopic rods has a connecting block fixedly connected to its telescopic end. Each set of connecting blocks has a clamping plate slidably connected inside. Each set of connecting blocks has a pressure sensor fixedly connected to its inner wall. Each set of pressure sensors has a pressure-sensing spring fixedly connected to one end close to the other. Each set of pressure-sensing springs has a fixed end close to the other side of the clamping plate. The upper surface of the placement base is fixedly connected to six intelligent controllers. Each intelligent controller is electrically connected to the pressure sensor and the electrically operated telescopic rod via a wire.
[0008] The outer surface of the placement base is provided with a stacking assembly.
[0009] The front and back of the placement base are fixedly connected to auxiliary handles, and the outer surface of each auxiliary handle is fixedly connected to an anti-slip sleeve.
[0010] Each of the auxiliary handles has two fixed rings on its outer surface, and the ends of the two sets of fixed rings that are close to each other are fixedly connected to the front and back of the base.
[0011] Each set of clamping plates has a first sponge pad fixedly connected to one side of each other, and a second sponge pad fixedly connected to the inner bottom wall of each placement hole.
[0012] Each set of clamping plates has a stabilizing block fixedly connected to its front side, and each set of stabilizing blocks is slidably connected to the inside of the connecting block.
[0013] The stacking assembly includes two auxiliary blocks. The sides of the two auxiliary blocks that are close to each other are fixedly connected to the left and right sides of the placement base. Each auxiliary block has two sliding blocks slidably connected inside. Each set of sliding blocks has a positioning rod fixedly connected to the sides that are close to each other. The left and right sides of the placement base are fixedly connected to combination blocks. Each combination block has a limit hole inside.
[0014] Each set of sliding blocks has a return spring fixedly connected to one side that is far apart from each other, and the one end of each set of return springs that is far apart from each other is fixedly connected to the inner wall of the auxiliary block.
[0015] Each set of sliding blocks has a push handle fixedly connected to its bottom surface, and each push handle is slidably connected to the inside of the auxiliary block.
[0016] This invention provides a device for stacking cervical cancer vaccine test tubes, which has the following beneficial effects:
[0017] This cervical cancer vaccine test tube stacking device, comprising a placement seat, placement holes, an electric telescopic rod, a connecting block, a clamping plate, a pressure sensor, a pressure-measuring spring, an intelligent controller, and a stacking assembly, allows for the storage of test tubes via the placement holes. The electric telescopic rod pushes the connecting block and clamping plate closer together, clamping the test tubes within the placement holes. This enables the placement of test tubes of different diameters. During clamping, the clamping plate, under pressure, causes the pressure-measuring spring to contract. The pressure sensor detects the current pressure value of the spring and, when the pressure reaches a suitable level, sends an electrical signal to the intelligent controller via a wire. The intelligent controller then stops the electric telescopic rod, completing the automatic clamping process. The device also allows for control of the clamping force and the stable stacking of multiple units via the stacking assembly. This solves the problems of not being suitable for storing test tubes of different diameters, requiring different stacking devices when storing cervical cancer vaccine test tubes of different specifications, and the risk of collapse when stacking multiple units. This device significantly improves the applicability of the cervical cancer vaccine test tube stacking device. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0019] Figure 2 This is a cross-sectional view of the placement hole structure of this utility model;
[0020] Figure 3 This is a cross-sectional view of the connecting block of this utility model;
[0021] Figure 4 This is a cross-sectional view of the auxiliary block of this utility model.
[0022] Explanation of reference numerals in the attached figures
[0023] 1. Placement base;
[0024] 2. Auxiliary mechanism; 201. Placement hole; 202. Electric telescopic rod; 203. Connecting block; 204. Clamping plate; 205. Pressure sensor; 206. Pressure measuring spring; 207. Intelligent controller;
[0025] 3. Stacking components; 301. Auxiliary block; 302. Sliding block; 303. Positioning rod; 304. Combination block; 305. Limiting hole;
[0026] 4. Auxiliary handle; 5. Anti-slip sleeve; 6. Retaining ring; 7. First sponge pad; 8. Second sponge pad; 9. Stabilizing block; 10. Return spring; 11. Push handle. Detailed Implementation
[0027] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this application, and not all of the embodiments. Based on the embodiments of this application, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of this application.
[0028] Please see Figures 1-4 This utility model provides a cervical cancer vaccine reagent tube stacking device, including a placement seat 1, and an auxiliary mechanism 2 is provided inside the placement seat 1;
[0029] The auxiliary mechanism 2 includes six placement holes 201, each of which is opened on the upper surface of the placement seat 1. The front and back of the placement seat 1 are fixedly connected to auxiliary handles 4, and the outer surface of each auxiliary handle 4 is fixedly connected to an anti-slip sleeve 5. By using the cooperation of the auxiliary handles 4 and the anti-slip sleeves 5, a good force point can be provided for the placement seat 1, increasing the ease of pushing the placement seat 1 when needed. The anti-slip sleeves 5 can increase the firmness when gripping the auxiliary handles 4.
[0030] The interior of the placement base 1 is equipped with six sets of electric telescopic rods 202. Each set of electric telescopic rods 202 has a connecting block 203 fixedly connected to its telescopic end. Each auxiliary handle 4 has two fixed rings 6 fixedly connected to its outer surface. The ends of the two sets of fixed rings 6 that are close to each other are fixedly connected to the front and back of the placement base 1. The fixed rings 6 can increase the fixed connection area between the auxiliary handle 4 and the placement base 1, thereby making the connection between the two more secure and preventing the possibility of breakage at the connection after long-term use, thus increasing the robustness of the device.
[0031] Each set of connecting blocks 203 has a clamping plate 204 slidably connected inside. Each set of connecting blocks 203 has a pressure sensor 205 fixedly connected to its inner wall. Each set of pressure sensors 205 has a pressure measuring spring 206 fixedly connected to one end close to the other. Each set of pressure measuring springs 206 has a fixed end close to the other side of the clamping plate 204. Each set of clamping plates 204 has a first sponge pad 7 fixedly connected to one side close to the other. Each placement hole 201 has a second sponge pad 8 fixedly connected to its inner bottom wall. The cooperation of the first sponge pad 7 and the second sponge pad 8 can effectively improve the safety of the reagent tube during placement and clamping, increase the protection of the reagent tube, and improve the effectiveness of the device.
[0032] Six intelligent controllers 207 are fixedly connected to the upper surface of the placement base 1. Each intelligent controller 207 is electrically connected to the pressure sensor 205 and the electric telescopic rod 202 through wires. A stabilizing block 9 is fixedly connected to the front of each set of clamping plates 204. Each set of stabilizing blocks 9 is slidably connected to the inside of the connecting block 203. The stabilizing block 9 can move simultaneously with the clamping plate 204 and use the friction force generated by itself on the connecting block 203 during the movement to improve the stability of the clamping plate 204 when it moves, thereby increasing the stability of the device.
[0033] The outer surface of the placement base 1 is provided with a stacking assembly 3, which includes two auxiliary blocks 301. The two auxiliary blocks 301 are fixedly connected to the left and right sides of the placement base 1 on their respective sides. Each auxiliary block 301 has two sliding blocks 302 slidably connected inside. Each set of sliding blocks 302 has a positioning rod 303 fixedly connected to the side of its respective sides. The left and right sides of the placement base 1 are fixedly connected with a combination block 304. Each combination block 304 has a limiting hole 305 inside. When the auxiliary blocks 301 and combination blocks 304 of two identical devices are inserted, the positioning rod 303 will move into the auxiliary block 301 due to the pressure of the combination block 304, and quickly insert into the limiting hole 305 after the combination is completed, thereby locking the position of the combination block 304 and completing the combination of the reagent tube stacking device.
[0034] Each set of sliding blocks 302 has a return spring 10 fixedly connected to the side of each other that is far apart from each other. The end of each set of return springs 10 that is far apart from each other is fixedly connected to the inner wall of the auxiliary block 301. The return spring 10 can use its own extension and contraction ability to continuously apply pressure to the sliding block 302, so that the sliding block 302 has the ability to automatically reset, which increases the convenience when limiting, and also improves the firmness of the positioning rod 303 when limiting.
[0035] Each set of sliding blocks 302 has a push handle 11 fixedly connected to its bottom surface. Each push handle 11 is slidably connected to the inside of the auxiliary block 301. With the cooperation of the push handle 11, a good force point can be provided for the sliding block 302, increasing the ease of pulling the sliding block 302 and improving the convenience of the device in use.
[0036] In use, the electric telescopic rod 202, pressure sensor 205, and intelligent controller 207 are first connected to the power supply. When it is necessary to fix reagent tubes of different diameters, the reagent tube is placed into the placement hole 201. Then, the intelligent controller 207 is pressed, which starts the two electric telescopic rods 202, thereby driving the two connecting blocks 203 and the clamping plate 204 to move closer to each other, thus fixing the reagent tube in the placement hole 201. When the clamping plate 204 contacts the reagent tube, it will move into the connecting block 203 due to pressure, and the pressure measuring spring 206 will contract. At this time, the pressure sensor 205 can continuously monitor the pressure, and when the pressure reaches the appropriate level, it sends an electrical signal to the intelligent controller 207 through the wire, thereby stopping the electric telescopic rod 202. This completes the automatic clamping capability of reagent tubes of different diameters and can also control the force during clamping, increasing the effectiveness of the cervical cancer vaccine reagent tube stacking device.
[0037] When multiple devices need to be stacked, two identical devices are taken out and made parallel vertically. Then, the upper device is lowered, causing the auxiliary block 301 to encompass the assembly block 304. As the assembly block 304 moves within the auxiliary block 301, it presses against the positioning rod 303, causing the positioning rod 303 to move into the auxiliary block 301. Simultaneously, the return spring 10 is compressed. When the assembly block 304 is fully inserted into the auxiliary block 301, the return spring 10 pushes the positioning rod 303 to reset and insert it into the limiting hole 305 to limit the assembly block 304, thus completing the stacking of two devices. The positioning rod 303 can also be removed from the assembly block 304 by pulling the push handle 11, facilitating the disassembly of the devices. This effectively increases the applicability of the cervical cancer vaccine reagent tube stacking device.
[0038] 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 illustrative of the 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 claims. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A device for stacking cervical cancer vaccine test tubes, comprising a placement base (1), characterized in that: An auxiliary mechanism (2) is provided inside the placement seat (1); The auxiliary mechanism (2) includes six placement holes (201), each of which is opened on the upper surface of the placement seat (1). The placement seat (1) is provided with six sets of electric telescopic rods (202). Each set of electric telescopic rods (202) has a connecting block (203) fixedly connected to its telescopic end. Each set of connecting blocks (203) has a clamping plate (204) slidably connected inside. Each set of connecting blocks (203) has a pressure sensor (205) fixedly connected to its inner wall. Each set of pressure sensors (205) has a pressure measuring spring (206) fixedly connected to one end close to the other. Each set of pressure measuring springs (206) has a fixed end close to the other side of the clamping plate (204) and a side away from the other. The upper surface of the placement seat (1) is fixedly connected with six intelligent controllers (207). Each intelligent controller (207) is electrically connected to the pressure sensor (205) and the electric telescopic rod (202) through wires. The outer surface of the placement base (1) is provided with a stacking component (3).
2. The cervical cancer vaccine reagent tube stacking device according to claim 1, characterized in that: The front and back of the placement base (1) are fixedly connected with auxiliary handles (4), and the outer surface of each auxiliary handle (4) is fixedly connected with an anti-slip sleeve (5).
3. The cervical cancer vaccine reagent tube stacking device according to claim 2, characterized in that: Two retaining rings (6) are fixedly connected to the outer surface of each of the auxiliary handles (4), and the ends of the two sets of retaining rings (6) that are close to each other are fixedly connected to the front and back of the placement seat (1).
4. The cervical cancer vaccine test tube stacking device according to claim 1, characterized in that: Each set of clamping plates (204) has a first sponge pad (7) fixedly connected to one side of each other, and a second sponge pad (8) fixedly connected to the inner bottom wall of each placement hole (201).
5. The cervical cancer vaccine reagent tube stacking device according to claim 1, characterized in that: Each set of clamping plates (204) has a stabilizing block (9) fixedly connected to its front side, and each set of stabilizing blocks (9) is slidably connected to the inside of the connecting block (203).
6. The cervical cancer vaccine test tube stacking device according to claim 1, characterized in that: The stacking assembly (3) includes two auxiliary blocks (301). The two auxiliary blocks (301) are fixedly connected to the left and right sides of the placement base (1) on their respective sides. Each auxiliary block (301) has two sliding blocks (302) slidably connected inside. Each set of sliding blocks (302) has a positioning rod (303) fixedly connected to the respective sides of their respective sides. The placement base (1) has a combination block (304) fixedly connected to the left and right sides. Each combination block (304) has a limiting hole (305) inside.
7. The cervical cancer vaccine test tube stacking device according to claim 6, characterized in that: Each set of sliding blocks (302) has a return spring (10) fixedly connected to one side away from each other, and the end of each set of return springs (10) is fixedly connected to the inner wall of the auxiliary block (301).
8. The cervical cancer vaccine reagent tube stacking device according to claim 6, characterized in that: Each set of sliding blocks (302) has a push handle (11) fixedly connected to its bottom surface, and each push handle (11) is slidably connected to the inside of the auxiliary block (301).