Notebook computer rubber ring detection device

By designing a laptop rubber ring detection device, a synchronous detection and automated feeding and unloading of multiple rubber rings is achieved using components such as a sleeve, a detection top plate, and a motor. This solves the problems of low detection efficiency and poor convenience in existing technologies, and improves the stability and efficiency of the detection.

CN224354199UActive Publication Date: 2026-06-12DONGGUAN CENTURY CREATION INSULATION

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN CENTURY CREATION INSULATION
Filing Date
2025-06-18
Publication Date
2026-06-12

AI Technical Summary

Technical Problem

Existing testing equipment can only test one rubber ring at a time, which affects testing efficiency and cannot achieve automatic feeding and unloading of rubber rings, affecting the convenience of testing.

Method used

A device for detecting rubber rings in laptop computers has been designed, including a detection component and a feeding component. Through the cooperation of components such as a sleeve post, a detection top plate, a limiting post, a bevel gear, and a motor, multiple rubber rings can be detected and flipped simultaneously, achieving automated feeding and unloading.

Benefits of technology

This improved the stability and efficiency of the inspection, enabling simultaneous inspection and flipping of multiple rubber rings, and enhancing the convenience of the inspection.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224354199U_ABST
    Figure CN224354199U_ABST
Patent Text Reader

Abstract

The utility model provides notebook computer rubber ring detection device belongs to detection device field, including base, the base upside is provided with detection subassembly, detection subassembly front end downside is provided with feeding assembly, when needing to detect notebook computer rubber ring, through the clamping body clamping multiple rubber ring suitings outside the sleeve column after, control detection top plate is between the vertical stable sliding down between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between the vertical stable between
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Description

Technical Field

[0001] This utility model relates to the field of testing devices, and more specifically, to a testing device for rubber seals in laptop computers. Background Technology

[0002] Laptops require rubber rings for shock absorption and noise reduction during the manufacturing process. The production of these rubber rings requires separate pressure resistance testing, which necessitates the use of a dedicated rubber ring testing device.

[0003] A search revealed that Chinese patent CN222231979U discloses a "Rubber Sealing Ring Finished Product Testing Device," comprising a support base and a support top plate. A support cylinder is sealed in the center of the top of the support base, and a lower mold cylinder is sealed inside the support cylinder. An electric cylinder is located in the center of the top of the support top plate, with its bottom extension power end extending to a lifting plate below the support top plate. An upper mold cylinder is sealed in the center of the bottom of the lifting plate. An air pump is located inside the support base, with an air extraction pipe and an air outlet pipe. The air outlet pipe has an air inlet pipe extending into the lower sealing groove, and an exhaust pipe is located in the lower sealing groove. A pressure sensor is located in the lower sealing groove. The advantages of this invention compared to existing technologies are: this invention, through the upper and lower mold cylinders, and by pressing down, combined with air supply and pressure sensor sensing, can accurately monitor the sealing performance of the rubber sealing ring, resulting in high efficiency and high testing quality. However, it still has the following drawbacks:

[0004] (1) The existing testing equipment can only test one rubber ring individually, while rubber rings are mass-produced in the production of laptops. If they are tested one by one, it will affect the efficiency of the testing.

[0005] (2) The existing testing device cannot enable the automatic loading and unloading of the rubber rings to be tested. The entire process requires manual loading and unloading of the rubber rings, which affects the convenience of testing.

[0006] Therefore, we made improvements and proposed a laptop rubber ring detection device. Utility Model Content

[0007] The purpose of this invention is to address the problem that existing testing devices can only test one rubber ring at a time, while rubber rings are mass-produced in laptop manufacturing. Testing them one by one affects the efficiency of the testing, and existing testing devices cannot automatically load and unload the rubber rings to be tested. The entire process requires manual loading and unloading of the rubber rings, which affects the convenience of the testing.

[0008] To achieve the above-mentioned objectives, this utility model provides the following technical solution:

[0009] A laptop computer rubber seal detection device to improve the above-mentioned problems.

[0010] The present invention is as follows:

[0011] Includes a base, with a detection component on the upper side of the base and a feeding component on the lower front side of the detection component;

[0012] The detection assembly includes a detection base plate disposed on the upper side of the center of the base, a sleeve column fixedly installed on the upper side of the center of the detection base plate, and limit posts disposed on the edge of the detection base plate;

[0013] The feeding assembly includes a sliding groove on the upper surface of the front and rear sides of the base, a screw is provided inside the sliding groove, and a sleeve plate is fitted on the outer wall of the screw.

[0014] As a preferred technical solution of this utility model, the detection component further includes upright plates installed on the upper outer side of the front and rear sides of the base, and a detection top plate that can be lifted and lowered between the front and rear upright plates. A pressure groove that cooperates with the sleeve column is opened on the lower side of the center of the detection top plate, and a limiting hole that cooperates with the limiting column is opened on the lower side of the edge of the detection top plate.

[0015] As a preferred technical solution of this utility model, an inner groove is provided inside the base at the right end of the slide groove. A first bevel gear is provided on the inner wall of the inner groove near the screw. A second bevel gear that cooperates with the first bevel gear is provided on the inner wall of the front end of the inner groove. A first motor is connected to the front end of the second bevel gear.

[0016] As a preferred technical solution of this utility model, lifting plates are movably provided on the side walls of both the front and rear sleeve plates, electric shafts are installed on the side walls of the lifting plates, and a rotating plate is installed between the front and rear electric shafts.

[0017] As a preferred technical solution of this utility model, the rotating plate has a clamping groove inside, and clamping bodies are telescopically provided on the inner walls of both sides of the clamping groove. An electric hydraulic rod is installed on the outer side of the clamping body.

[0018] As a preferred technical solution of this utility model, the outer wall of the lifting plate at the left side of the electric shaft at the rear side of the rotating plate is provided with an outer plate, the outer plate has a groove inside, a locking plate is movably arranged inside the groove, the groove has side grooves on the upper and lower sides, and the locking plate has side plates on the upper and lower sides that cooperate with the side grooves.

[0019] As a preferred technical solution of this utility model, a toothed roller is provided on the transverse side wall of the locking plate, and a second motor is connected to the upper end of the toothed roller. A side groove is opened on the inner wall of the groove near the toothed roller, and a toothed plate that cooperates with the toothed roller is provided inside the side groove.

[0020] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0021] In the solution of this utility model:

[0022] 1. By setting up a detection base plate, sleeve posts, and detection top plate, when it is necessary to test the rubber rings of a laptop computer, multiple sets of rubber rings are clamped and fitted onto the outside of the sleeve posts. The detection top plate is controlled to slide vertically and stably downward between the upright plates. The rubber rings fitted onto the outside of the sleeve posts are squeezed by the relative pressure grooves of the sleeve posts to achieve performance testing. Under the limitation of the edge limiting post inserting into the limiting hole, the testing process is more stable, and the testing process of the rubber rings outside the sleeve posts is not affected by external forces. At the same time, multiple rubber rings are pressed down for testing, which improves the stability and efficiency of the testing.

[0023] 2. By setting up a first bevel gear, a second bevel gear, a screw, an electric shaft, a rotating plate, a clamping body, and a locking plate, when it is necessary to flip the rubber ring, the first motor is controlled to drive the connected second bevel gear to rotate, which in turn drives the first bevel gear to rotate, driving the screw to rotate. This meshing causes the sleeve plate to slide to the left in the slide groove, aligning the clamping slot of the rotating plate with a set of sleeve columns. The lifting plate is then controlled to move downwards, causing the rotating plate to move downwards, so that the sleeve columns are inserted into the clamping slots. The electric hydraulic rod is controlled to drive the clamping body to clamp the rubber ring fitted on the outside of the sleeve columns. The lifting plate is then controlled to move upwards, and the clamping body, holding the rubber ring, moves upwards. The rotation of the electric shaft drives the rotating plate to flip, which in turn flips the clamped rubber ring. After flipping, the second motor is controlled to rotate the toothed roller, so that they mesh with each other on the toothed plate surface. With the side plate embedded in the side groove limit, the locking plate slides towards the electric shaft and is embedded in the surface of the electric shaft through the toothed groove. After the clamping body holds the flipped rubber ring, it is aligned with the sleeve post. The lifting plate is controlled to move down, so that the clamped and flipped rubber ring is put on the outside of the sleeve post. This can realize the synchronous flipping of multiple rubber rings. Through the above steps, the subsequent rubber rings are flipped in sequence, which improves the convenience of rubber ring flipping detection. Attached Figure Description

[0024] Figure 1 A frontal view of the overall structure of the notebook computer rubber ring detection device provided by this utility model;

[0025] Figure 2 A side view schematic diagram of the overall structure of the notebook computer rubber ring detection device provided by this utility model;

[0026] Figure 3 A partial cross-sectional structural diagram of the feeding component of the notebook computer rubber ring detection device provided by this utility model;

[0027] Figure 4 A schematic diagram of the rotating plate structure of the notebook computer rubber ring detection device provided by this utility model;

[0028] Figure 5 A schematic diagram of the locking plate structure of the notebook computer rubber ring detection device provided by this utility model.

[0029] The image shows:

[0030] 1. Base; 201. Detection base plate; 202. Sleeve column; 203. Limiting column; 204. Vertical plate; 205. Detection top plate; 206. Pressure groove; 207. Limiting hole; 301. Sliding groove; 302. Screw; 303. Sleeve plate; 304. Inner groove; 305. First bevel gear; 306. Second bevel gear; 307. First motor; 308. Lifting plate; 309. Electric shaft; 310. Rotating plate; 311. Clamping groove; 312. Clamping body; 313. Electro-hydraulic rod; 314. Outer plate; 315. Embedded groove; 316. Locking plate; 317. Side groove; 318. Side plate; 319. Toothed roller; 320. Second motor; 321. Side groove; 322. Toothed plate. Detailed Implementation

[0031] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this utility model.

[0032] Therefore, the following detailed description of the embodiments of this utility model is not intended to limit the scope of the claimed utility model, but merely to illustrate some embodiments of the utility model. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without inventive effort are within the scope of protection of this utility model.

[0033] It should be noted that, unless otherwise specified, the embodiments and features and technical solutions in the present invention can be combined with each other.

[0034] It should be noted that similar labels and letters in the following figures indicate similar items. Therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.

[0035] like Figure 1-5 As shown, this embodiment proposes a notebook computer rubber ring detection device, including a base 1, a detection component is provided on the upper side of the base 1, and a feeding component is provided on the lower side of the front end of the detection component.

[0036] The detection assembly includes a detection base plate 201 located on the upper center of the base 1, a sleeve post 202 fixedly installed on the upper center of the detection base plate 201, and a limit post 203 located on the edge of the detection base plate 201;

[0037] The feeding assembly includes a slide groove 301 on the upper surface of the front and rear sides of the base 1, a screw 302 is provided inside the slide groove 301, and a sleeve plate 303 is fitted on the outer wall of the screw 302.

[0038] like Figure 3 As shown, the detection assembly also includes upright plates 204 mounted on the upper front and rear sides of the base 1. A detection top plate 205 is installed between the front and rear upright plates 204 and can be raised and lowered. A pressure groove 206 that cooperates with the sleeve post 202 is opened on the lower center side of the detection top plate 205. A limiting hole 207 that cooperates with the limiting post 203 is opened on the lower edge side of the detection top plate 205. Under the limiting of the edge limiting post 203 inserted into the limiting hole 207, the detection process is more stable, the detection process of the outer rubber ring of the sleeve post 202 is not affected by external force, and multiple rubber rings are pressed down and detected at the same time, which improves the detection stability and efficiency.

[0039] like Figure 3 As shown, an inner groove 304 is provided inside the base 1 at the right end of the slide groove 301. A first bevel gear 305 is provided on the inner wall of the inner groove 304 near the screw 302. A second bevel gear 306 is provided on the inner wall of the front end of the inner groove 304, which cooperates with the first bevel gear 305. A first motor 307 is connected to the front end of the second bevel gear 306. The first motor 307 is controlled to drive the second bevel gear 306 connected to it to rotate. The meshing drives the first bevel gear 305 to rotate, which drives the screw 302 to rotate. The meshing drives the sleeve plate 303 to slide to the left in the slide groove 301, so that the clamping groove 311 opened on the rotating plate 310 is aligned with a set of sleeve posts 202.

[0040] like Figure 4 As shown, lifting plates 308 are movably installed on the side walls of the front and rear sleeve plates 303. Electric shafts 309 are installed on the side walls of the lifting plates 308. A rotating plate 310 is installed between the front and rear electric shafts 309. Controlling the lifting plates 308 to move downwards causes the rotating plate 310 to move downwards, so that the sleeve 202 is inserted into the clamping groove 311. Controlling the electric hydraulic rod 313 causes the clamping body 312 to clamp the rubber ring on the outside of the sleeve 202. Controlling the lifting plates 308 to move upwards causes the clamping body 312 to move upwards while holding the rubber ring. Controlling the electric shaft 309 to rotate causes the rotating plate 310 to flip, which can cause the clamped rubber ring to flip.

[0041] like Figure 4 As shown, the rotating plate 310 has a clamping groove 311 inside. The inner walls on both sides of the clamping groove 311 are provided with a clamping body 312 that can be extended and retracted. An electric hydraulic rod 313 is installed on the outside of the clamping body 312. The electric hydraulic rod 313 is controlled to drive the clamping body 312 to clamp the rubber ring on the outside of the sleeve column 202. The lifting plate 308 is controlled to move upward, and the clamping body 312 clamps the rubber ring and moves upward.

[0042] like Figure 5As shown, an outer plate 314 is provided on the outer wall of the lifting plate 308 located on the left side of the electric shaft 309 at the rear of the rotating plate 310. A groove 315 is provided inside the outer plate 314, and a locking plate 316 is movably installed inside the groove 315. Side grooves 317 are provided on the upper and lower sides of the groove 315. Side plates 318 that cooperate with the side grooves 317 are provided on the upper and lower sides of the locking plate 316. With the side plates 318 embedded in the side grooves 317 and limited, the locking plate 316 slides towards the electric shaft 309 and is engaged with the surface of the electric shaft 309 by the toothed grooves. This causes the clamping body 312 to hold the rubber ring and flip it so that it aligns with the sleeve post 202. The lifting plate 308 is controlled to move down, causing the held and flipped rubber ring to be fitted onto the outside of the sleeve post 202, thus realizing the synchronous flipping of multiple rubber rings.

[0043] like Figure 5 As shown, a toothed roller 319 is provided on the transverse side wall of the locking plate 316. A second motor 320 is connected to the upper end of the toothed roller 319. A side groove 321 is provided on the inner wall of the groove 315 near the toothed roller 319. A toothed plate 322 that cooperates with the toothed roller 319 is provided inside the side groove 321. By controlling the rotation of the electric shaft 309 to drive the rotating plate 310 to flip, the clamped rubber ring can be flipped. After flipping, the second motor 320 is controlled to run and drive the toothed roller 319 to rotate, so that they mesh with each other on the surface of the toothed plate 322.

[0044] Specifically, when using this testing device: When testing the rubber rings of a laptop computer, multiple sets of rubber rings are clamped by the clamp 312 and fitted onto the outside of the sleeve post 202. The testing top plate 205 is controlled to slide vertically and stably downwards between the upright plates 204. Performance testing is achieved by pressing the rubber rings fitted onto the outside of the sleeve post 202 against the pressure groove 206. The edge limiting post 203, inserted into the limiting hole 207, makes the testing process more stable, ensuring that the testing process of the rubber rings outside the sleeve post 202 is not affected by external forces. Simultaneous pressing and testing of multiple rubber rings improves testing stability and efficiency. When it is necessary to flip the rubber rings, the first motor 307 drives the connected second bevel gear 306 to rotate, meshing and driving the first bevel gear 305 to rotate, which in turn drives the screw 302 to rotate. This meshes and drives the sleeve plate 303 to slide to the left within the slide groove 301, aligning the clamping groove 311 of the rotating plate 310 with a set of sleeve posts 202. The lifting plate 3... 08 moves downward, causing the rotating plate 310 to move downward, so that the sleeve 202 is inserted into the clamping groove 311. The electric hydraulic rod 313 is controlled to drive the clamping body 312 to clamp the rubber ring on the outside of the sleeve 202. The lifting plate 308 is controlled to move upward, and the clamping body 312 clamps the rubber ring and moves upward. The electric shaft 309 is controlled to rotate, causing the rotating plate 310 to flip, which can cause the clamped rubber ring to flip. After flipping, the second motor 320 is controlled to run, driving the toothed roller 319 to rotate, so that it is positioned relative to the surface of the toothed plate 322. Engaging, with the side plate 318 embedded in the side groove 317 for limiting, the locking plate 316 slides towards the electric shaft 309 and is engaged with the surface of the electric shaft 309 through the toothed groove. This causes the clamping body 312 to hold the rubber ring and flip it, aligning it with the sleeve post 202. The lifting plate 308 is then controlled to move downward, causing the held and flipped rubber ring to be fitted onto the outside of the sleeve post 202. This allows for the synchronous flipping of multiple rubber rings. By following the above steps, subsequent rubber rings can be flipped sequentially, improving the convenience of rubber ring flipping detection.

[0045] All technical features in this embodiment can be freely combined according to actual needs.

[0046] The above embodiments are preferred implementations of this utility model. In addition, this utility model can also be implemented in other ways. Any obvious substitutions without departing from the concept of this technical solution are within the protection scope of this utility model.

Claims

1. A notebook computer rubber ring detection device, comprising a base (1), characterized in that: A detection component is provided on the upper side of the base (1), and a feeding component is provided on the lower front side of the detection component; The detection assembly includes a detection base plate (201) provided on the upper center of the base (1), a sleeve column (202) fixedly installed on the upper center of the detection base plate (201), and a limit column (203) provided on the edge of the detection base plate (201). The feeding assembly includes a groove (301) on the upper surface of the front and rear sides of the base (1), a screw (302) is provided inside the groove (301), and a sleeve plate (303) is fitted on the outer wall of the screw (302).

2. The notebook computer rubber ring detection device according to claim 1, characterized in that, The detection assembly also includes a vertical plate (204) installed on the upper front and rear sides of the base (1). A detection top plate (205) is installed between the front and rear vertical plates (204) and can be raised and lowered. A pressure groove (206) that cooperates with the sleeve column (202) is opened on the lower center side of the detection top plate (205). A limiting hole (207) that cooperates with the limiting column (203) is opened on the lower edge of the detection top plate (205).

3. The notebook computer rubber ring detection device according to claim 1, characterized in that, An inner groove (304) is provided inside the base (1) at the right end of the slide (301). A first bevel gear (305) is provided on the inner wall of the inner groove (304) near the screw (302). A second bevel gear (306) is provided on the inner wall of the front end of the inner groove (304) to cooperate with the first bevel gear (305). A first motor (307) is connected to the front end of the second bevel gear (306).

4. The notebook computer rubber ring detection device according to claim 1, characterized in that, Lifting plates (308) are movably provided on the side walls of the front and rear sleeve plates (303). Electric shafts (309) are installed on the side walls of the lifting plates (308). A rotating plate (310) is installed between the front and rear electric shafts (309).

5. The notebook computer rubber ring detection device according to claim 4, characterized in that, The rotating plate (310) has a clamping groove (311) inside. The inner walls on both sides of the clamping groove (311) are provided with clamping bodies (312) that can be extended and retracted. An electric hydraulic rod (313) is installed on the outside of the clamping body (312).

6. The notebook computer rubber ring detection device according to claim 4, characterized in that, The outer wall of the lifting plate (308) located on the left side of the electric shaft (309) at the rear of the rotating plate (310) is provided with an outer plate (314). The outer plate (314) has a groove (315) inside. A locking plate (316) is movably provided inside the groove (315). Side grooves (317) are provided on the upper and lower sides of the groove (315). Side plates (318) that cooperate with the side grooves (317) are provided on the upper and lower sides of the locking plate (316).

7. The notebook computer rubber ring detection device according to claim 6, characterized in that, The locking plate (316) has a toothed roller (319) on its transverse sidewall. The upper end of the toothed roller (319) is connected to a second motor (320). The groove (315) has a side groove (321) on the inner wall near the toothed roller (319). The side groove (321) has a toothed plate (322) that cooperates with the toothed roller (319).