A quality detection device for instrument movement processing

Abstract

The utility model relates to quality detection technical field discloses a kind of quality detection devices of instrument movement processing, including base, the upper end middle part of base is rotatably connected with damping pivot, the upper end of the damping pivot is fixedly connected with two support blocks, rotatably connected with rotating shaft between two the support blocks, the outside middle part of the rotating shaft is equipped with gear, the upper end of the gear is engagedly connected with half gear, the upper end of the half gear is fixedly connected support seat, the upper end middle part of the support seat is fixedly connected with first support box.In the utility model, when the device is used, the first threaded rod is rotated, so that the two sides of the support plate move, and the second threaded rod is rotated, so that the two sides of the clamping block move, thereby the movement of different sizes can be clamped and fixed, greatly improving the applicability and versatility of the equipment, so that it can flexibly cope with various detection requirements.

Description

Technical Field

[0001] This utility model relates to the field of quality inspection technology, and in particular to a quality inspection device for the processing of instrument movement. Background Technology

[0002] Instruments are a general term for devices that display numerical values, used to detect, measure, observe, and calculate various physical quantities, material composition, and physical property parameters. The instrument movement, as the core component of an instrument, directly determines its accuracy and stability. Therefore, after the movement is manufactured, it must undergo detailed performance testing. During testing, staff will first carefully observe the movement's appearance to ensure there are no breaks, cracks, or other physical damage, as these external defects can affect the movement's normal operation or reduce its lifespan.

[0003] However, most existing instrument movement processing and inspection usually rely on manual clamping and rotation observation. But existing clamping equipment can only clamp movements of a specific size. This limitation makes it impossible to meet the inspection needs of movements of different sizes and specifications, thus severely restricting the equipment's versatility and flexibility, and making it difficult to adapt to diverse production environments.

[0004] Therefore, those skilled in the art have provided a quality inspection device for the machining of instrument movement to solve the problems mentioned in the background art. Utility Model Content

[0005] The purpose of this utility model is to address the shortcomings of existing technologies by proposing a quality inspection device for instrument movement processing. When in use, the device rotates by rotating a first threaded rod, causing the support plates on both sides to move. Simultaneously, the device rotates by rotating a second threaded rod, causing the clamping blocks on both sides to move. This allows for the clamping and fixing of movements of different sizes, greatly improving the applicability and versatility of the equipment and enabling it to flexibly meet various testing needs.

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

[0007] A quality inspection device for instrument movement processing includes a base. A damping shaft is rotatably connected to the upper center of the base. Two support blocks are fixedly connected to the upper end of the damping shaft. A rotating shaft is rotatably connected between the two support blocks. A gear is sleeved on the outer center of the rotating shaft. A half gear is meshed with the upper end of the gear. A support seat is fixedly connected to the upper center of the support seat. A first support box is fixedly connected to the upper center of the support box. A first bidirectional threaded rod is rotatably connected inside the first support box. First threaded cylinders are threaded on both sides of the outer side of the first bidirectional threaded rod. Support plates are fixedly connected to the upper ends of the two first threaded cylinders. Second support boxes are rotatably connected to one side of the two support plates. Second bidirectional threaded rods are rotatably connected inside the two second support boxes. Second threaded cylinders are threaded on both sides of the outer side of the two second bidirectional threaded rods. Clamping blocks are fixedly connected to one side of the two second threaded cylinders.

[0008] With the above technical solution, when the device is in use, the rotation of the first threaded rod causes the support plates on both sides to move, and the rotation of the second threaded rod causes the clamping blocks on both sides to move, thereby clamping and fixing the movement of different sizes, which greatly improves the applicability and versatility of the equipment and enables it to flexibly meet various testing needs.

[0009] Furthermore, a spring is provided in the middle of the interior of one side of the support block, and a limit block is fixedly connected to the lower end of the spring. One end of the rotating shaft extends to the outside of the support block and is fitted with a limit gear. The limit gear meshes with the limit teeth at the lower end of the limit block.

[0010] Through the above technical solution, the meshing of the two components enables the rotating shaft to be stably limited after rotation, thereby keeping the support stable after rotating to a certain angle. This avoids angular deviation of the support due to accidental collision or operational errors, ensuring the accuracy and reliability of the testing process.

[0011] Furthermore, guide blocks are fixedly connected to the upper end of one side of each of the two support blocks, and guide grooves are provided on both sides of the half gear. The two guide blocks are located inside the guide grooves and are slidably connected to them.

[0012] Through the above technical solution, the sliding connection between the guide block and the guide groove constrains the rotation of the support block within a fixed track, avoiding shaking or deviation during rotation, and ensuring the stability of the movement clamping and the accuracy of detection.

[0013] Furthermore, guide boxes are fixedly connected to the four corners of the upper end of the support base, and sliders are fixedly connected to both sides of the lower end of the two support plates. The lower ends of the multiple sliders are located inside the guide boxes and are slidably connected to them.

[0014] Through the above technical solution, the cooperation between the guide box and the slider restricts the movement of the support plate within a fixed track, ensuring smooth and accurate movement. This facilitates precise clamping and positioning according to the size of the movement, thereby improving testing efficiency.

[0015] Furthermore, rubber pads are provided inside each of the clamping blocks;

[0016] Through the above technical solution, the elastic cushioning effect of the rubber pad can avoid scratches or wear caused by direct contact between the metal clamp and the movement, while increasing the stability of the clamping and preventing the movement from sliding or falling off during the testing process.

[0017] Furthermore, mounting holes are provided at all four corners of the base;

[0018] The above technical solution allows the device to be easily fixed on a workbench or other equipment, enhancing its stability, facilitating various testing operations, and also making the integration and use of the equipment easier.

[0019] Furthermore, a throttle is fixedly connected to the middle of the second support box on one side, and one end of the rotating shaft extends to the outside of the support block on one side and is fixedly connected to the throttle.

[0020] Through the above technical solution, the throttle setting provides a simple and intuitive operating interface, allowing operators to easily adjust the rotating shaft and support block by turning the throttle, reducing the difficulty of operation and improving work efficiency.

[0021] This utility model has the following beneficial effects:

[0022] 1. The present invention proposes a quality inspection device for the processing of instrument movement. When in use, the device rotates by rotating the first threaded rod, causing the support plates on both sides to move. At the same time, the device rotates by rotating the second threaded rod, causing the clamping blocks on both sides to move. This allows for clamping and fixing of movements of different sizes, greatly improving the applicability and versatility of the equipment, enabling it to flexibly meet various inspection needs.

[0023] 2. This utility model proposes a quality inspection device for instrument movement processing. When in use, the device allows the support base to rotate through a damping shaft, and drives the half gear to rotate through a gear to precisely adjust the angle of the support base. This helps the operator adjust the observation angle of the movement as needed, allowing the operator to observe the details of the movement from different angles. This ensures that no potential problems are missed during the inspection process, thereby enabling better comprehensive inspection, avoiding omissions or blind spots, and improving the accuracy and comprehensiveness of the inspection, thus guaranteeing the quality of the movement. Attached Figure Description

[0024] Figure 1 This is an isometric drawing of a quality inspection device for the machining of an instrument mechanism proposed in this utility model;

[0025] Figure 2 This is a schematic diagram of the support base and support plate of a quality inspection device for instrument mechanism processing proposed in this utility model;

[0026] Figure 3 This is a schematic diagram of the base and support of a quality inspection device for instrument mechanism processing proposed in this utility model;

[0027] Figure 4 This is an isometric view of the base of a quality inspection device for instrument mechanism processing proposed in this utility model;

[0028] Figure 5 This is a schematic diagram of the second support box and the second bidirectional threaded rod of a quality inspection device for instrument movement processing proposed in this utility model.

[0029] Legend:

[0030] 1. Base; 2. Damping shaft; 3. Support block; 4. Rotating shaft; 5. Gear; 6. Half gear; 7. Support seat; 8. First support box; 9. First double-threaded rod; 10. First threaded cylinder; 11. Support plate; 12. Second support box; 13. Second double-threaded rod; 14. Second threaded cylinder; 15. Clamping block; 16. Spring; 17. Limiting block; 18. Limiting gear; 19. Guide block; 20. Guide groove; 21. Guide box; 22. Slider; 23. Mounting hole. Detailed Implementation

[0031] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of specific embodiments. Obviously, the described specific embodiments are only a part of the specific embodiments of the present invention, and not all of them. Based on the specific embodiments of the present invention, all other specific embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0032] Reference Figure 1-5The present invention provides a specific embodiment of a quality inspection device for instrument mechanism processing, comprising a base 1, a damping shaft 2 rotatably connected to the upper middle of the base 1, two support blocks 3 fixedly connected to the upper end of the damping shaft 2, a rotating shaft 4 rotatably connected between the two support blocks 3, a gear 5 sleeved on the outer middle of the rotating shaft 4, a half gear 6 meshing with the upper end of the gear 5, a support seat 7 fixedly connected to the upper end of the half gear 6, a first support box 8 fixedly connected to the upper middle of the support seat 7, a first bidirectional threaded rod 9 rotatably connected inside the first support box 8, a first threaded cylinder 10 threaded on both sides of the outer side of the first bidirectional threaded rod 9, a support plate 11 fixedly connected to the upper end of each of the two first threaded cylinders 10, a second support box 12 rotatably connected to one side of each of the two support plates 11, a second bidirectional threaded rod 13 rotatably connected inside each of the two second bidirectional threaded rods 13, a second threaded cylinder 14 threaded on both sides of the outer side of each of the two second threaded cylinders 14, and a clamping block 15 fixedly connected to one side of each of the two second threaded cylinders 14.

[0033] When in use, the device rotates by rotating the first threaded rod, causing the support plates 11 on both sides to move. At the same time, it rotates by rotating the second threaded rod, causing the clamping blocks 15 on both sides to move. This allows the device to clamp and fix mechanisms of different sizes, greatly improving its applicability and versatility, and enabling it to flexibly meet various testing needs.

[0034] A spring 16 is installed in the center of the interior of one side support block 3. The lower end of the spring 16 is fixedly connected to a limit block 17. One end of the rotating shaft 4 extends to the outside of one side support block 3 and is fitted with a limit gear 18. The limit gear 18 meshes with the limit teeth at the lower end of the limit block 17. The meshing of the two makes the rotating shaft 4 stably limited after rotation, so that the support seat 7 remains stable after rotating to a certain angle, avoiding the angle displacement of the support seat 7 due to accidental collision or operation error, and ensuring the accuracy and reliability of the detection process. On one side end face of the two support blocks 3 Guide blocks 19 are fixedly connected to both ends of the half gear 6. Guide grooves 20 are opened on both end faces of the half gear 6. The two guide blocks 19 are located inside the guide grooves 20 and are slidably connected to them. The sliding connection between the guide blocks 19 and the guide grooves 20 constrains the rotation of the support block 3 within a fixed track, avoiding shaking or offset during rotation, and ensuring the stability of the movement clamping and the accuracy of detection. Guide boxes 21 are fixedly connected to the four corners of the upper end of the support base 7. Slider blocks 22 are fixedly connected to both sides of the lower end of the two support plates 11. The lower ends of the multiple sliders 22 are all located inside the guide grooves 20. The guide box 21 is slidably connected to the inside of the guide box 21. The cooperation between the guide box 21 and the slider 22 restricts the movement of the support plate 11 within a fixed track, ensuring smooth and accurate movement. This facilitates precise clamping and positioning according to the size of the movement, improving testing efficiency. Rubber pads are provided inside the multiple clamping blocks 15. The elastic cushioning effect of the rubber pads can prevent scratches or wear caused by direct contact between the metal clamping blocks 15 and the movement, while increasing the stability of clamping and preventing the movement from sliding or falling off during testing. Mounting holes 23 are provided at the four corners of the base 1. The design of the mounting holes 23 allows the device to be easily fixed on the workbench or other equipment, enhancing the stability of the device and facilitating various testing operations. It also facilitates the integration and use of the equipment. A throttle is fixedly connected to the middle of the second support box 12 on one side. One end of the rotating shaft 4 extends to the outside of the support block 3 on one side and is fixedly connected to the throttle. The throttle provides a simple and intuitive operating interface. The operator can easily adjust the rotating shaft 4 and the support block 3 by rotating the throttle, reducing the difficulty of operation and improving work efficiency.

[0035] Working Principle: During use, the operator first moves the support plates 11 on both sides by rotating the first threaded rod according to the size of the movement to be tested, and at the same time moves the clamping blocks 15 on both sides by rotating the second threaded rod. This achieves stable clamping and fixing of movements of different sizes, greatly improving the applicability and versatility of the equipment and enabling flexible response to various testing needs. After the movement is fixed, the operator performs the test by rotating the handle, and the support seat 7 can be rotated by the damping shaft 2. At the same time, the operator uses the handle to rotate the rotating shaft 4, which drives the gear 5 to drive the half gear 6 to rotate, so as to precisely adjust the angle of the support seat 7. This allows the operator to adjust the observation angle of the movement as needed, observe the details of the movement from different angles, and ensure that no potential problems are missed during the testing process. This allows for better comprehensive testing, avoids missed inspections or blind spots, and improves the accuracy and comprehensiveness of the testing, thus ensuring the quality of the movement.

[0036] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing specific embodiments, those skilled in the art can still modify the technical solutions described in the foregoing specific embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A quality inspection device for instrument movement processing, comprising a base (1), characterized in that: A damping shaft (2) is rotatably connected to the upper middle part of the base (1). Two support blocks (3) are fixedly connected to the upper end of the damping shaft (2). A rotating shaft (4) is rotatably connected between the two support blocks (3). A gear (5) is sleeved on the outer middle part of the rotating shaft (4). A half gear (6) is meshed with the upper end of the gear (5). A support seat (7) is fixedly connected to the upper end of the half gear (6). A first support box (8) is fixedly connected to the upper middle part of the support seat (7). A first bidirectional threaded rod is rotatably connected inside the first support box (8). 9) The first bidirectional threaded rod (9) has a first threaded cylinder (10) threaded on both sides of its outer side. The upper ends of the two first threaded cylinders (10) are fixedly connected to a support plate (11). The two support plates (11) are rotatably connected to one side end face of each of the two support plates (11). The two second support boxes (12) are rotatably connected to the inside of each of the two second support boxes (12). The two second bidirectional threaded rods (13) have a second threaded cylinder (14) threaded on both sides of their outer side. The two second threaded cylinders (14) are fixedly connected to one side end face of each of the two second threaded cylinders (14).

2. The quality inspection device for instrument movement processing according to claim 1, characterized in that: A spring (16) is provided in the middle of the interior of the support block (3) on one side. The lower end of the spring (16) is fixedly connected to a limiting block (17). One end of the rotating shaft (4) extends to the outside of the support block (3) on one side and is fitted with a limiting gear (18). The limiting gear (18) meshes with the limiting teeth at the lower end of the limiting block (17).

3. The quality inspection device for instrument movement processing according to claim 1, characterized in that: Guide blocks (19) are fixedly connected to the upper end of one side of each of the two support blocks (3). Guide grooves (20) are opened on both sides of the half gear (6). The two guide blocks (19) are located inside the guide grooves (20) and are slidably connected to them.

4. The quality inspection device for instrument movement processing according to claim 1, characterized in that: Guide boxes (21) are fixedly connected to the four corners of the upper end of the support base (7), and sliders (22) are fixedly connected to both sides of the lower end of the two support plates (11). The lower ends of the multiple sliders (22) are located inside the guide box (21) and are slidably connected to it.

5. The quality inspection device for instrument movement processing according to claim 1, characterized in that: Each of the clamping blocks (15) has a rubber pad inside.

6. The quality inspection device for instrument movement processing according to claim 1, characterized in that: Mounting holes (23) are provided at all four corners of the base (1).

7. The quality inspection device for instrument movement processing according to claim 1, characterized in that: A throttle is fixedly connected to the middle of the second support box (12) on one side, and one end of the rotating shaft (4) extends to the outside of the support block (3) on one side and is fixedly connected to the throttle.

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