Double-station mouse wheel and key automatic testing mechanism

By designing a dual-station automatic testing mechanism for mouse scroll wheel and buttons, simultaneous testing of mouse scroll wheel and buttons is achieved, solving the problem that existing technologies can only test the scroll wheel separately, improving testing efficiency and reducing costs.

CN224398957UActive Publication Date: 2026-06-23DONGGUAN PRIMAX ELECTRONIC & TEKLECOM PROD LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN PRIMAX ELECTRONIC & TEKLECOM PROD LTD
Filing Date
2025-05-08
Publication Date
2026-06-23

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  • Figure CN224398957U_ABST
    Figure CN224398957U_ABST
Patent Text Reader

Abstract

The utility model discloses a double position mouse scroll wheel and key automatic test mechanism, it includes: lift module and install in the lower extreme of lift module and by lift module drive to realize the lift lift seat, install in the lower extreme of lift seat and be used for the detection of mouse's scroll wheel scroll wheel detection module, the lower extreme of lift seat still is provided with the key detection module for the detection of mouse's key, and this key detection module includes the test head of installation in the lower extreme of lift seat and is used for the telescopic drive device of driving test head telescopic, and test head is located scroll wheel detection module side. The utility model can also detect the key of mouse while detecting the scroll wheel of mouse, reaches dual -purpose function, has very high work efficiency, can also reduce the key of mouse to be detected with the additional machine, reaches the detection cost of reducing, can also improve the detection efficiency, also very convenient to use, make the utility model have very strong market competitiveness.
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Description

Technical fields:

[0001] This utility model relates to the field of mouse testing technology, and specifically to an automatic testing mechanism for a dual-station mouse scroll wheel and buttons. Background technology:

[0002] A mouse is short for computer input device. There are wired and wireless types. It is also an indicator for positioning the horizontal and vertical coordinates of a computer display system. The purpose of using a mouse is to make computer operation more convenient and replace the cumbersome commands of the keyboard.

[0003] Existing mice all require factory testing after production to ensure quality. For example, Chinese utility model patent CN220583751U discloses a mouse scroll wheel testing platform, which includes a frame. A support frame is fixedly connected to the rear side of the upper end of the frame. A hydraulic cylinder is fixedly connected to the upper end of the support frame. The lower end of the hydraulic cylinder passes through the support frame and is fixedly connected to a fixing plate. A connecting plate is fixedly connected to the front side of the fixing plate by a fixing bolt. A motor is fixedly connected to the front side of the connecting plate, and a test wheel is fixedly connected to the output shaft of the motor.

[0004] The aforementioned mouse wheel test bench can only test the mouse wheel, but cannot test the left and right mouse buttons simultaneously. This necessitates the use of other testing equipment to test the left and right mouse buttons, and it does not meet the usage requirements.

[0005] In view of the above, the inventors propose the following technical solution. Utility model content:

[0006] The purpose of this invention is to overcome the shortcomings of the existing technology and provide a dual-station automatic testing mechanism for mouse scroll wheel and buttons.

[0007] To solve the above-mentioned technical problems, the present invention adopts the following technical solution: The dual-station automatic testing mechanism for mouse scroll wheel and buttons includes: a lifting module and a lifting base installed at the lower end of the lifting module and driven by the lifting module to achieve lifting; a scroll wheel detection module installed at the lower end of the lifting base for detecting the scroll wheel of the mouse; the lower end of the lifting base is also provided with a button detection module for detecting the buttons of the mouse; the button detection module includes a test head installed at the lower end of the lifting base and a telescopic drive device for driving the test head to extend and retract; the test head is located next to the scroll wheel detection module.

[0008] Furthermore, in the above technical solution, the telescopic drive device is installed at the lower end of the lifting seat via an angle adjustment module.

[0009] Furthermore, in the above technical solution, the angle adjustment module includes a support frame installed at the lower end of the lifting seat and an angle adjustment plate rotatably installed inside the support frame. The outer side of the angle adjustment plate is provided with a first pivot hole and a first locking hole located next to the first pivot hole. The lower end of the support frame is provided with a second pivot hole corresponding to the first pivot hole and an arc-shaped adjustment hole located next to the second pivot hole. The pivot member passes through the second pivot hole and the first pivot hole, so that the angle adjustment plate and the support frame form a rotatable assembly. The first screw passes through the arc-shaped adjustment hole and is screwed to the first locking hole. The telescopic drive device is installed on the angle adjustment plate.

[0010] Furthermore, in the above technical solution, there are two of each of the angle adjustment module, telescopic drive device, and test head, which correspond to the left and right buttons of the mouse, respectively.

[0011] Furthermore, in the above technical solution, the telescopic drive device is any one of a cylinder, a hydraulic cylinder, or an electric push rod.

[0012] Furthermore, in the above technical solution, both the roller detection module and the button detection module are in two sets, symmetrically distributed at the lower end of the lifting seat.

[0013] Furthermore, in the above technical solution, a conductive probe module is also provided at the lower end of the lifting seat; the lifting module includes a bracket and sliding seats installed on both sides of the bracket and a Z-axis electric cylinder installed on the bracket. Vertically distributed slide rails are provided on both sides of the lifting seat, and the sides of the sliding seats are installed on the slide rails by sliders to form a slidable assembly. The lower end of the Z-axis electric cylinder is connected to the middle of the upper end of the lifting seat.

[0014] Furthermore, in the above technical solution, the roller detection module includes a test arm installed at the lower end of the lifting base, a first pulley installed at the upper end of the test arm, a second pulley installed at the lower end of the test arm, a belt connected between the first pulley and the second pulley for driving the mouse roller to rotate, and a motor installed at the lower end of the lifting base for driving the first pulley to rotate.

[0015] Furthermore, in the above technical solution, the test arm includes a main arm and an extension arm installed at the end of the main arm and whose relative position can be adjusted relative to the main arm to achieve extension or shortening. The first pulley is rotatably installed on the inner side of the main arm, and the second pulley is rotatably installed on the inner side of the extension arm.

[0016] Furthermore, in the above technical solution, the lower end of the lifting seat is also provided with a first buffer and a second buffer to prevent the test arm from swinging excessively. The first buffer and the second buffer are respectively located outside the upper and lower sides of the test arm.

[0017] After adopting the above technical solution, the present invention has the following beneficial effects compared with the prior art: When the present invention is working, when the lifting module drives the lifting seat and the roller detection module set at its lower end to descend, the roller detection module contacts the mouse roller, and the roller detection module drives the mouse roller to rotate, thereby realizing the detection of the mouse roller, the button detection module can work at the same time to detect the mouse buttons. Specifically, the telescopic drive device drives the test head to extend to click the mouse button, thereby realizing the detection of the mouse button. The present invention can detect the mouse roller and the mouse button at the same time, achieving dual-function and extremely high working efficiency. At the same time, it can reduce the need for additional machines to detect the mouse buttons, thereby reducing detection costs and improving detection efficiency. It is also extremely convenient to use, making the present invention highly competitive in the market. Attached image description:

[0018] Figure 1 This is a perspective view of the present invention;

[0019] Figure 2 This is a perspective view of the present invention from another angle;

[0020] Figure 3 This is an assembly diagram of the roller detection module and the button detection module in this utility model;

[0021] Figure 4 This is an assembly diagram of the roller detection module and the button detection module from another perspective in this utility model. Detailed implementation method:

[0022] The present invention will be further described below with reference to specific embodiments and accompanying drawings.

[0023] See Figure 1-4 As shown, this is a dual-station automatic testing mechanism for mouse scroll wheel and buttons. It includes: a lifting module 1 and a lifting base 2 installed at the lower end of the lifting module 1 and driven by the lifting module 1 to achieve lifting and lowering; and a scroll wheel detection module 3 installed at the lower end of the lifting base 2 for detecting the mouse scroll wheel. During operation, the lifting module 1 drives the lifting base 2 and the scroll wheel detection module 3 installed at its lower end to descend, so that the scroll wheel detection module 3 contacts the mouse scroll wheel, and the scroll wheel detection module 3 drives the mouse scroll wheel to rotate, thereby realizing the detection of the mouse scroll wheel. This is a conventional technical method.

[0024] To improve work efficiency and achieve dual functionality, this utility model not only detects the mouse scroll wheel but also the mouse buttons. The following design is also made: The lower end of the lifting base 2 is provided with a button detection module 4 for detecting the mouse buttons. The button detection module 4 includes a test head 41 installed at the lower end of the lifting base 2 and a telescopic drive device 42 for driving the test head 41 to extend and retract. The test head 41 is located next to the scroll wheel detection module 3. During operation, when the lifting module 1 drives the lifting base 2 and the roller detection module 3 at its lower end to descend, the roller detection module 3 contacts the mouse wheel, and the roller detection module 3 drives the mouse wheel to rotate, thereby detecting the mouse wheel. At the same time, the button detection module 4 can work simultaneously to detect the mouse buttons. Specifically, the telescopic drive device 42 drives the test head 41 to extend and click the mouse button, thereby detecting the mouse button. This invention can detect the mouse wheel and the mouse buttons simultaneously, achieving dual functionality and extremely high work efficiency. At the same time, it can reduce the need for additional machines to detect the mouse buttons, thereby reducing detection costs and improving detection efficiency. It is also extremely convenient to use, giving this invention a strong market competitiveness.

[0025] The telescopic drive device 42 can be any one of a cylinder, a hydraulic cylinder, or an electric push rod. In this embodiment, the telescopic drive device 42 is a cylinder, and in particular, a needle cylinder is used, which is small in size and very convenient to install and use.

[0026] The telescopic drive device 42 is installed at the lower end of the lifting base 2 via the angle adjustment module 43. This allows the angle of the telescopic drive device 42 to be adjusted via the angle adjustment module 43, thereby adjusting the angle of the test head 41. This enables the test head 41 to be adjusted to the optimal position for more stable mouse button clicks and improved test quality.

[0027] Specifically, the angle adjustment module 43 includes a support frame 431 installed at the lower end of the lifting seat 2 and an angle adjustment plate 432 rotatably installed inside the support frame 431. The angle adjustment plate 432 has a first pivot hole 401 and a first locking hole 402 located beside the first pivot hole 401 on its outer side. The lower end of the support frame 431 has a second pivot hole 403 corresponding to the first pivot hole 401 and an arc-shaped adjustment hole 404 located beside the second pivot hole 403. The pivot member passes through the second pivot hole 403 and the first pivot hole 401, so that the angle adjustment plate 432 and the support frame 431 form a rotatable assembly. The first screw passes through the arc-shaped adjustment hole 404 and is screwed to the first locking hole 402. When the angle needs to be adjusted, the first screw is loosened and rotated relative to the first screw through the arc-shaped adjustment hole 404 to adjust the position of the angle adjustment plate 432. After the adjustment is completed, the first screw is tightened again. Its structure is simple and extremely convenient to operate. The telescopic drive device 42 is mounted on the angle adjustment plate 432.

[0028] There are two of each of the angle adjustment module 43, telescopic drive device 42, and test head 41, corresponding to the left and right buttons on the mouse, respectively. In other words, one button detection module 4 can perform click detection / testing on both buttons on the left and right sides of the mouse, making it more convenient and efficient to use.

[0029] The scroll wheel detection module 3 and the button detection module 4 are both in two sets, symmetrically distributed at the lower end of the lifting base 2, enabling the present invention to simultaneously detect the buttons and scroll wheels of two mice, achieving the purpose of dual-station operation, making it more convenient to use and more efficient.

[0030] The lower end of the lifting seat 2 is also provided with a conductive probe module 5, which is used to connect the mouse and power the mouse so as to realize detection.

[0031] The lifting module 1 includes a bracket 11, sliding seats 12 mounted on both sides of the bracket 11, and a Z-axis electric cylinder 13 mounted on the bracket 11. The lifting seat 2 has vertically distributed slide rails 21 on both sides. The sliding seats 12 are mounted on the slide rails 21 by sliders to form a slidable assembly. The lower end of the Z-axis electric cylinder 13 is connected to the middle of the upper end of the lifting seat 2. Its structure is simple and stable, and the lifting module 1 can drive the lifting seat 2 to move up and down smoothly and stably, improving the quality of testing.

[0032] The scroll wheel detection module 3 includes a test arm 31 mounted on the lower end of the lifting base 2, a first pulley 32 mounted on the upper end of the test arm 31, a second pulley 33 mounted on the lower end of the test arm 31, a belt 34 connected between the first pulley 32 and the second pulley 33 for driving the mouse scroll wheel to rotate, and a motor 35 mounted on the lower end of the lifting base 2 for driving the first pulley 32 to rotate. During operation, the lifting module 1 drives the scroll wheel detection module 3 downwards, causing the portion of the belt 34 that contacts the second pulley 33 to contact the mouse scroll wheel. Then, the motor 35 operates, driving the first pulley 32 to rotate, and simultaneously driving the second pulley 33 to rotate via the belt 34, thus enabling the belt 34 to operate stably. The belt 34 drives the mouse scroll wheel to rotate through friction, thereby achieving the test of the mouse scroll wheel.

[0033] The test arm 31 includes a main arm 311 and an extension arm 312 mounted at the end of the main arm 311 and adjustable in position relative to the main arm 311 to achieve extension or shortening. A first pulley 32 is rotatably mounted inside the main arm 311, and a second pulley 33 is rotatably mounted inside the extension arm 312. The extension arm 312 has two screw holes, and the main arm 311 has a corresponding slotted hole. Screws pass through the slotted hole and are screwed into the screw holes to fix the extension arm 312 to the lower end of the main arm 311. When the length needs to be adjusted, the screws are loosened, and the extension arm 312 moves relative to the screw through the slotted hole, thereby adjusting the position of the extension arm 312 relative to the main arm 311, thus achieving the purpose of adjusting the entire test arm 31. Its structure is simple and its operation is easy.

[0034] The lower end of the lifting seat 2 is also provided with a first buffer 22 and a second buffer 23 to prevent the test arm 31 from swinging excessively. The first buffer 22 and the second buffer 23 are respectively located outside the upper and lower sides of the test arm 31. The first buffer 22 and the second buffer 23 are used to prevent the test arm 31 from swinging excessively.

[0035] In summary, when this utility model is in operation, the lifting module 1 drives the lifting base 2 and the roller detection module 3 at its lower end to descend, causing the roller detection module 3 to contact the mouse wheel. The roller detection module 3 then drives the mouse wheel to rotate, thereby detecting the mouse wheel. Simultaneously, the button detection module 4 can work to detect the mouse buttons. Specifically, the telescopic drive device 42 drives the test head 41 to extend and click the mouse button, thereby detecting the mouse button. This utility model can detect both the mouse wheel and the mouse buttons at the same time, achieving dual functionality and extremely high work efficiency. Furthermore, it reduces the need for additional machines to detect the mouse buttons, thus lowering detection costs and improving detection efficiency. It is also extremely convenient to use, giving this utility model a strong market competitiveness.

[0036] Of course, the above description is only a specific embodiment of the present utility model and is not intended to limit the scope of the present utility model. All equivalent changes or modifications made to the structure, features and principles described in the claims of the present utility model should be included in the scope of the claims of the present utility model.

Claims

1. A dual-station automatic testing mechanism for mouse scroll wheel and buttons, comprising: The lifting module (1), the lifting base (2) installed at the lower end of the lifting module (1) and driven by the lifting module (1) to achieve lifting, and the scroll wheel detection module (3) installed at the lower end of the lifting base (2) for detecting the scroll wheel of the mouse, are characterized in that: The lower end of the lifting seat (2) is also provided with a button detection module (4) for detecting the buttons of the mouse. The button detection module (4) includes a test head (41) installed at the lower end of the lifting seat (2) and a telescopic drive device (42) for driving the test head (41) to extend and retract. The test head (41) is located next to the roller detection module (3).

2. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to claim 1, characterized in that: The telescopic drive device (42) is installed at the lower end of the lifting seat (2) via the angle adjustment module (43).

3. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to claim 2, characterized in that: The angle adjustment module (43) includes a support frame (431) installed at the lower end of the lifting seat (2) and an angle adjustment plate (432) rotatably installed inside the support frame (431). The outer side of the angle adjustment plate (432) is provided with a first pivot hole (401) and a first locking hole (402) located next to the first pivot hole (401). The lower end of the support frame (431) is provided with a second locking hole (402) corresponding to the first pivot hole (401). The pivot hole (403) and the arc-shaped adjustment hole (404) located next to the second pivot hole (403) are provided. The pivot member passes through the second pivot hole (403) and the first pivot hole (401) so that the angle adjustment plate (432) and the support frame (431) form a rotatable assembly. The first screw passes through the arc-shaped adjustment hole (404) and is screwed to the first locking hole (402). The telescopic drive device (42) is installed on the angle adjustment plate (432).

4. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to claim 3, characterized in that: The angle adjustment module (43), the telescopic drive device (42), and the test head (41) are all in pairs, corresponding to the left and right buttons of the mouse, respectively.

5. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to claim 1, characterized in that: The telescopic drive device (42) can be any one of a cylinder, a hydraulic cylinder, or an electric push rod.

6. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to claim 1, characterized in that: The roller detection module (3) and the button detection module (4) are both two sets, which are symmetrically distributed at the lower end of the lifting seat (2).

7. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to any one of claims 1-6, characterized in that: The lower end of the lifting seat (2) is also provided with a conductive probe module (5); the lifting module (1) includes a bracket (11) and sliding seats (12) installed on both sides of the bracket (11) and a Z-axis electric cylinder (13) installed on the bracket (11). Vertically distributed slide rails (21) are provided on both sides of the lifting seat (2). The sliding seats (12) are mounted on the slide rails (21) by sliders to form a sliding assembly. The lower end of the Z-axis electric cylinder (13) is connected to the middle of the upper end of the lifting seat (2).

8. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to any one of claims 1-6, characterized in that: The roller detection module (3) includes a test arm (31) installed at the lower end of the lifting base (2), a first pulley (32) installed at the upper end of the test arm (31), a second pulley (33) installed at the lower end of the test arm (31), a belt (34) connected between the first pulley (32) and the second pulley (33) and used to drive the mouse roller to rotate, and a motor (35) installed at the lower end of the lifting base (2) and used to drive the first pulley (32) to rotate.

9. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to claim 8, characterized in that: The test arm (31) includes a main arm (311) and an extension arm (312) installed at the end of the main arm (311) and adjustable relative to the main arm (311) to achieve extension or shortening. The first pulley (32) is rotatably installed inside the main arm (311), and the second pulley (33) is rotatably installed inside the extension arm (312).

10. The automatic testing mechanism for a dual-station mouse scroll wheel and buttons according to claim 8, characterized in that: The lower end of the lifting seat (2) is also provided with a first buffer (22) and a second buffer (23) to prevent the test arm (31) from swinging excessively. The first buffer (22) and the second buffer (23) are respectively located outside the upper and lower sides of the test arm (31).