CN219301518U - Inside shell fragment check out test set of high-speed connector - Google Patents

Abstract

The utility model discloses high-speed connector internal spring piece detection equipment which comprises a device main body, wherein a telescopic cylinder is arranged on the device main body, a lifting plate is arranged at the action output end of the telescopic cylinder, an industrial camera is arranged on the lifting plate, and through the mutual matching of structures such as a fixed clamping block, a movable clamping block, a supporting table, a first servo motor and a second servo motor, products can be sequentially placed between the movable clamping block and the fixed clamping block on the supporting table through a mechanical arm or manually during use, an internal rotating disc is driven to rotate through the second servo motor so as to enable the movable clamping block to approach the fixed clamping block and clamp and fix the products, meanwhile, the supporting table can be driven to rotate through the first servo motor, and further, the products clamped by the movable clamping block and the fixed clamping block sequentially pass through the position under the industrial camera for size detection, so that the device detection speed block is high in efficiency and low in cost.

Description

Inside shell fragment check out test set of high-speed connector

Technical Field

The utility model relates to the technical field of size detection equipment, in particular to high-speed connector internal spring piece detection equipment.

Background

MPO connectors are one type of optical fiber connectors, commonly used as a connector type for high-speed transmission standards, such as the ieee802.3bm standard for 40G/100G transmission, and the like, and may be used in a data center, where the high-speed connector needs to detect an elastic sheet inside the high-speed connector during the production process, so as to detect whether the size of a product is within a tolerance range.

In the prior art, most of equipment for detecting the elastic sheet in the high-speed connector is provided with a clamp through a sliding rail, so that the equipment clamps and fixes a product and sequentially performs size detection through the bottom of an industrial camera, but the detection equipment needs to stop for loading and unloading, and has general detection efficiency.

Disclosure of Invention

The present utility model is directed to a device for detecting an inner spring of a high-speed connector, so as to solve the problems set forth in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an inside shell fragment check out test set of high-speed connector, includes the device main part, install flexible cylinder in the device main part, the lifter plate is installed to flexible cylinder's action output, installs the industry camera on the lifter plate, install first servo motor in the device main part, install the brace table on first servo motor's the output shaft, evenly arranged a plurality of fixed clamp splice along the circumferencial direction on the brace table, seted up the transmission chamber on the brace table, install the second servo motor on the bottom inner wall of transmission chamber, install the rolling disc on the action output shaft of second servo motor, evenly arranged a plurality of sliding blocks along the circumferencial direction on the rolling disc, evenly offered a plurality of arc spacing groove along the circumferencial direction on the brace table, a plurality of sliding block respectively slidable mounting is in a plurality of arc spacing groove, movable clamp splice is installed at the top of sliding block, a plurality of support columns are installed to the bottom of device main part.

Preferably, a plurality of buffer grooves are uniformly formed in the rotating disc along the circumferential direction, and the sliding blocks are slidably arranged in the buffer grooves.

Preferably, a guide sliding rod is arranged in the buffer groove, a sliding hole matched with the guide sliding rod is formed in the sliding block, and the sliding block is slidably mounted on the guide sliding rod through the sliding hole.

Preferably, the guide sliding rod is sleeved with a buffer spring in a sliding manner, one end of the buffer spring is arranged on the inner wall of the buffer groove, and the other end of the buffer spring is arranged on the sliding block.

Preferably, a sliding groove is formed in the movable clamping block, and a rubber block is arranged in the sliding groove in a sliding mode.

Preferably, two mutually symmetrical horizontal limiting sliding grooves are formed in the inner wall of the sliding groove, a horizontal limiting sliding block is arranged in the horizontal limiting sliding groove in a sliding mode, and the horizontal limiting sliding block is arranged on the rubber block.

Preferably, a compression spring is arranged in the sliding groove, one end of the compression spring is arranged on the inner wall of the sliding groove, and the other end of the compression spring is arranged on the rubber block.

The beneficial effects of the utility model are as follows:

according to the utility model, through the mutual matching of the structures such as the fixed clamping blocks, the movable clamping blocks, the supporting table, the first servo motor and the second servo motor, products can be sequentially placed between the movable clamping blocks and the fixed clamping blocks on the supporting table through a mechanical arm or manually during use, the second servo motor drives the internal rotating disc to rotate, so that the movable clamping blocks approach the fixed clamping blocks and clamp and fix the products, and meanwhile, the first servo motor can drive the supporting table to rotate, so that the products clamped by the movable clamping blocks and the fixed clamping blocks sequentially pass through the position right below the industrial camera to perform size detection, and the device is high in detection speed block, high in efficiency and low in cost.

Drawings

Fig. 1 is a schematic structural diagram of an internal spring plate detection device of a high-speed connector according to the present utility model;

fig. 2 is a schematic side sectional structure of an internal spring piece detection device of a high-speed connector according to the present utility model;

fig. 3 is a schematic top sectional view of a support table and a rotating disc of an internal spring plate detection device of a high-speed connector according to the present utility model;

fig. 4 is a schematic top view partially illustrating a structure of a movable clamping block of an inner spring detection device of a high-speed connector according to the present utility model.

In the figure: 1. a device body; 2. a support column; 3. a telescopic cylinder; 4. a lifting plate; 5. an industrial camera; 6. a support table; 7. a movable clamping block; 8. fixing the clamping blocks; 9. an arc-shaped limit groove; 10. a sliding groove; 11. a first servo motor; 12. a second servo motor; 13. a transmission cavity; 14. a rotating disc; 15. a buffer tank; 16. a sliding block; 17. a buffer spring; 18. a guide slide bar; 19. a slide hole; 20. a horizontal limit chute; 21. a horizontal limit slide block; 22. a rubber block; 23. a compression spring.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1-4, an internal spring sheet detection device of a high-speed connector comprises a device main body 1, wherein a telescopic cylinder 3 is installed on the device main body 1, a lifting plate 4 is installed at the action output end of the telescopic cylinder 3, an industrial camera 5 is installed on the lifting plate 4, a first servo motor 11 is installed on the device main body 1, a supporting table 6 is installed on the output shaft of the first servo motor 11, a plurality of fixed clamping blocks 8 are uniformly arranged on the supporting table 6 along the circumferential direction, a transmission cavity 13 is formed on the supporting table 6, a second servo motor 12 is installed on the inner wall of the bottom of the transmission cavity 13, a rotating disc 14 is installed on the action output shaft of the second servo motor 12, a plurality of sliding blocks 16 are uniformly arranged on the rotating disc 14 along the circumferential direction, a plurality of arc-shaped limiting grooves 9 are uniformly formed on the supporting table 6 along the circumferential direction, a plurality of sliding blocks 16 are respectively and slidably installed in the arc-shaped limiting grooves 9, a movable clamping block 7 is installed on the top of the sliding blocks 16, and a plurality of supporting columns 2 are installed on the bottom of the device main body 1.

Through the mutual cooperation of the fixed clamp splice 8, the movable clamp splice 7, the supporting bench 6, the first servo motor 11 and the second servo motor 12 and other structures arranged, thereby can be when using through manipulator or manual work with the product place in proper order between the movable clamp splice 7 on the supporting bench 6 and the fixed clamp splice 8, thereby drive inside rolling disc 14 rotation through the second servo motor 12 and make movable clamp splice 7 be close to fixed clamp splice 8 and carry out the centre gripping to the product fixedly, simultaneously accessible first servo motor 11 drives supporting bench 6 rotation, and then make by the product under movable clamp splice 7 and the fixed clamp splice 8 centre gripping carry out size detection under the industrial camera 5 in proper order, the device detects the speed piece, and is efficient, and with low costs.

Specifically, in this embodiment, a plurality of buffer grooves 15 are uniformly formed on the rotating disk 14 along the circumferential direction, and the sliding blocks 16 are slidably mounted in the buffer grooves 15.

Through the mutual matching of the arranged buffer groove 15 and the sliding block 16, the sliding block 16 can slide along the buffer groove 15, and the purpose of limiting the moving direction and the moving range of the sliding block 16 is achieved greatly.

Specifically, in this embodiment, a guide sliding rod 18 is disposed in the buffer slot 15, a sliding hole 19 adapted to the guide sliding rod 18 is formed in the sliding block 16, and the sliding block 16 is slidably mounted on the guide sliding rod 18 through the sliding hole 19.

By the mutual matching of the arranged guide slide bars 18 and the slide holes 19, the slide block 16 can slide along the guide slide bars 18 through the slide holes 19, and the moving process of the slide block 16 can be more stable.

Specifically, in this embodiment, the guide slide rod 18 is slidably sleeved with the buffer spring 17, one end of the buffer spring 17 is mounted on the inner wall of the buffer slot 15, and the other end of the buffer spring 17 is mounted on the slide block 16.

Through the buffer spring 17 that arranges to can be when fixed clamp splice 8 and activity clamp splice 7 carry out the centre gripping to the material, the accessible fixed clamp splice 8 drives sliding block 16 and slides along buffer groove 15, and extrudees buffer spring 17, thereby realize reserving partial buffer space to the movable range of clamp splice 7, thereby can avoid the clamping dynamics too big to lead to damaging the material clamp.

Specifically, in this embodiment, the movable clamping block 7 is provided with a sliding groove 10, and a rubber block 22 is slidably mounted in the sliding groove 10.

By the mutual matching of the arranged sliding grooves 10 and the rubber blocks 22, the rubber blocks 22 can slide along the sliding grooves 10, and the purpose of guiding the moving direction of the rubber blocks 22 is achieved.

Specifically, in this embodiment, two symmetrical horizontal limiting sliding grooves 20 are formed on the inner wall of the sliding groove 10, a horizontal limiting sliding block 21 is slidably mounted in the horizontal limiting sliding groove 20, and the horizontal limiting sliding block 21 is mounted on a rubber block 22.

Through the mutual cooperation of the arranged horizontal limiting sliding grooves 20 and the horizontal limiting sliding blocks 21, the horizontal limiting sliding blocks 21 can slide along the horizontal limiting sliding grooves 20, the moving direction of the rubber block 22 is guided, and the moving range of the rubber block 22 is limited.

Specifically, in this embodiment, a compression spring 23 is disposed in the sliding groove 10, one end of the compression spring 23 is mounted on the inner wall of the sliding groove 10, and the other end of the compression spring 23 is mounted on the rubber block 22.

The rubber block 22 can drive the horizontal limiting sliding block 21 to be always abutted against the horizontal limiting sliding groove 20 through the arranged pressure springs 23, and when materials are clamped, the rubber block 22 slides along the sliding groove 10 and extrudes the pressure springs 23, so that the purpose of reserving part of space for the moving range of the rubber block 22 is achieved, and damage to the materials due to overlarge clamping force can be avoided.

The present utility model is not limited to the above-mentioned embodiments, and any person skilled in the art, based on the technical solution of the present utility model and the inventive concept thereof, can be replaced or changed within the scope of the present utility model.

Claims (7)

1. The utility model provides a high-speed connector inside shell fragment check out test set, includes device main part (1), its characterized in that: install telescopic cylinder (3) on device main part (1), lifter plate (4) are installed to the action output of telescopic cylinder (3), install industry camera (5) on lifter plate (4), install first servo motor (11) on device main part (1), install brace table (6) on the output shaft of first servo motor (11), evenly arranged a plurality of fixed clamp splice (8) along the circumferencial direction on brace table (6), set up driving chamber (13) on brace table (6), install second servo motor (12) on the bottom inner wall of driving chamber (13), install rolling disc (14) on the action output shaft of second servo motor (12), evenly arranged a plurality of sliding blocks (16) along the circumferencial direction on rolling disc (14), a plurality of arc spacing groove (9) have been evenly seted up along the circumferencial direction on brace table (6), a plurality of sliding blocks (16) are slidable mounting respectively in a plurality of arc spacing groove (9), movable clamp splice (7) are installed at the top of sliding block (16), a plurality of support columns (2) are installed to the bottom of device main part (1).

2. The high-speed connector internal spring detection apparatus according to claim 1, wherein: a plurality of buffer grooves (15) are uniformly formed in the rotating disc (14) along the circumferential direction, and sliding blocks (16) are slidably mounted in the buffer grooves (15).

3. The high-speed connector internal spring detection apparatus according to claim 2, wherein: the buffer groove (15) is internally provided with a guide slide bar (18), the slide block (16) is provided with a slide hole (19) matched with the guide slide bar (18), and the slide block (16) is slidably arranged on the guide slide bar (18) through the slide hole (19).

4. A high-speed connector internal spring detection apparatus according to claim 3, wherein: the guide slide bar (18) is sleeved with a buffer spring (17) in a sliding manner, one end of the buffer spring (17) is installed on the inner wall of the buffer groove (15), and the other end of the buffer spring (17) is installed on the sliding block (16).

5. The high-speed connector internal spring detection apparatus according to claim 1, wherein: the movable clamping block (7) is provided with a sliding groove (10), and a rubber block (22) is arranged in the sliding groove (10) in a sliding manner.

6. The high-speed connector internal spring detection apparatus according to claim 5, wherein: two mutually symmetrical horizontal limiting sliding grooves (20) are formed in the inner wall of the sliding groove (10), a horizontal limiting sliding block (21) is arranged in the horizontal limiting sliding groove (20) in a sliding mode, and the horizontal limiting sliding block (21) is arranged on the rubber block (22).

7. The high-speed connector internal spring detection apparatus according to claim 5, wherein: a pressure spring (23) is arranged in the sliding groove (10), one end of the pressure spring (23) is arranged on the inner wall of the sliding groove (10), and the other end of the pressure spring (23) is arranged on the rubber block (22).

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