CN220043419U - Anti-offset device for optical module test - Google Patents

Abstract

The utility model discloses an anti-offset device for optical module test, which comprises a wiring device shell, wherein a wire inlet groove is formed in the wiring device shell, a wire clamping plate is arranged in the wire inlet groove, a rubber round tube is arranged in the wire clamping plate, a rubber piston is arranged in the rubber round tube, a connecting plate is arranged on one side of the wiring device shell, four screw nails are arranged on one side of the connecting plate, an optical module connecting shell is arranged on one side of the connecting plate, and two clamping blocks are arranged on one side of the connecting plate. This anti-migration device for optical module test through income wire casing and income line board, the rubber pipe that set up, when making the optical module test connecting wire head, can be with connecting wire fixed column, make connecting wire line head static motionless, can make the optical module fix in a position through optical module coupling shell and the connecting plate that set up, make the optical module static motionless, can effectively avoid having the fluctuation that external factor brought to the test result when testing.

Description

Anti-offset device for optical module test

Technical Field

The utility model relates to the technical field of optical module testing, in particular to an anti-offset device for optical module testing.

Background

The optical module is composed of an optoelectronic device, a functional circuit, an optical interface and the like, wherein the optoelectronic device comprises a transmitting part and a receiving part, the optical module is an optoelectronic device for photoelectric and electro-optical conversion, the transmitting end of the optical module converts an electric signal into an optical signal, and the receiving end converts the optical signal into an electric signal. Optical modules are classified according to packaging forms, and commonly include SFP, SFP+, SFF, gigabit Ethernet interface converter (GBIC) and the like, and the optical modules need to be tested in the use process.

When testing the performance of the optical module, most of the optical modules are directly connected with the wire head, the test seeds are possibly affected by the outside, the optical module and the accessed optical fiber wire head are possibly offset due to the external influence, and the test results possibly fluctuate.

Disclosure of Invention

The utility model aims to provide an inspection well liquid level monitoring sensor which is used for solving the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an optical module test is with preventing skew device, includes the termination shell, the wire casing has been seted up to termination shell inside, wire casing inside is provided with the card line board to go into, the inside rubber pipe that is provided with of card line board, the inside rubber piston that is provided with of rubber pipe, rubber pipe and rubber piston fixed connection, termination shell one side is provided with the connecting plate, termination shell and connecting plate fixed connection, connecting plate one side is provided with four screw nails, connecting plate one side is provided with optical module connection shell, connecting plate one side is provided with two fixture blocks, termination shell bottom is provided with first rubber slab.

Preferably, a wire inlet hole is formed in one side of the wire clamping plate, the wire inlet hole is movably connected with the rubber round tube, four first threaded holes are formed in one side of the connecting plate, and the threaded nails are in threaded connection with the first threaded holes.

Preferably, the optical module clamping groove is formed in the optical module connecting shell, two clamping grooves are formed in one side of the optical module connecting shell, the clamping blocks are movably connected with the clamping grooves, four second threaded holes are formed in one side of the optical module connecting shell, the threaded nails are in threaded connection with the second threaded holes, a left spring plate is arranged in the optical module clamping groove, and a second rubber plate is arranged at the bottom of the optical module connecting shell.

Preferably, the screw is in threaded connection with the connecting plate and the optical module connecting shell.

Preferably, the left side spring groove has been seted up to optical module draw-in groove one side, left side spring groove one side is provided with left side spring, left side spring plate and left side spring fixed connection, optical module draw-in groove one side is provided with right side spring plate, right side spring groove has been seted up to optical module draw-in groove one side, right side spring groove one side is provided with right side spring, right side spring plate and right side spring fixed connection, optical module draw-in groove top is provided with the top surface spring plate, top surface spring groove has been seted up to optical module draw-in groove top surface, top surface spring groove top surface is provided with top surface spring, top surface spring plate and top surface spring fixed connection.

Preferably, the bottom surfaces of the first rubber plate and the second rubber plate are wavy, the first rubber plate is fixedly connected with the wiring device shell, and the second rubber plate is fixedly connected with the optical module connecting shell.

Compared with the prior art, the utility model has the beneficial effects that:

this anti-migration device for optical module test through income wire casing and income line board, the rubber pipe that set up, when making the optical module test connecting wire head, can be with connecting wire fixed column, make connecting wire line head static motionless, can make the optical module fix in a position through optical module coupling shell and the connecting plate that set up, make the optical module static motionless, can effectively avoid having the fluctuation that external factor brought to the test result when testing.

This anti-migration device for optical module test through the first rubber slab and the second rubber slab that set up, can effectually increase anti-migration device's bottom surface frictional force, can effectively avoid the damage that drops and bring because of the improper operation drives optical module in the test.

Drawings

FIG. 1 is an exploded perspective view of the present utility model;

FIG. 2 is an exploded perspective view of the housing of the wiring device of the present utility model;

FIG. 3 is an exploded perspective view of the optical module connection housing of the present utility model;

fig. 4 is an exploded view of the optical module connection housing of the present utility model.

In the figure: 1. a wiring device housing; 2. wire slot; 3. a wire clamping plate; 4. a rubber round tube; 5. a rubber piston; 6. a screw thread nail; 7. a clamping block; 8. the optical module is connected with the shell; 9. a connecting plate; 10. a first rubber plate; 11. a wire inlet hole; 12. a first threaded hole; 13. an optical module clamping groove; 14. a clamping groove; 15. a second threaded hole; 16. a left spring plate; 17. a left spring groove; 18. a left side spring; 19. a right spring plate; 20. a right side spring; 21. a right spring slot; 22. a top spring plate; 23. a top spring; 24. a top spring slot; 25. and a second rubber plate.

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. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-4, the present utility model provides a technical solution: the utility model provides an anti-deflection device for optical module test, including termination shell 1, termination shell 1 is inside to be seted up into wire casing 2, go into wire casing 2 and be used for placing the connecting wire end, ensure connecting wire and optical module at its internal test simultaneously, go into wire casing 2 inside to be provided with card line board 3, card line board 3 is used for the line of fixed connecting wire, ensure that the connecting wire is static, card line board 3 inside is provided with rubber pipe 4, rubber pipe 4 is used for placing rubber piston 5, protect the connecting wire from being damaged by dragging simultaneously, rubber pipe 4 is inside to be provided with rubber piston 5, rubber piston 5 is used for fixed connecting wire, protect the connecting wire for rubber material simultaneously and avoid damaging, rubber pipe 4 and rubber piston 5 fixed connection ensure that rubber pipe 4 and rubber piston 5 are as an organic whole, ensure that the connecting wire is static, termination shell 1 one side is provided with connecting plate 9, the connecting plate 9 is used for connecting the wiring device housing 1, ensure that the wiring device housing 1 and the connecting plate 9 are integrated, ensure that the test is not influenced by external force, the wiring device housing 1 and the connecting plate 9 are fixedly connected, ensure that the wiring device housing 1 and the connecting plate 9 are integrated, ensure that the test is not influenced by external force, one side of the connecting plate 9 is provided with four screw nails 6, the screw nails 6 are used for connecting the optical module connecting housing 8, ensure that the connecting plate 9 and the optical module connecting housing 8 are integrated, one side of the connecting plate 9 is provided with the optical module connecting housing 8, the optical module connecting housing 8 is used for protecting the optical module, one side of the connecting plate 9 is provided with two clamping blocks 7, the clamping blocks 7 are used for connecting the optical module connecting housing 8, ensure that the connecting plate 9 and the optical connecting housing 8 are integrated, simultaneously play an auxiliary role in connection, the bottom of the wiring device housing 1 is provided with a first rubber plate 10, the first rubber plate 10 is used for protecting the rectifying and anti-deviation device, the connecting wire inside the device is protected, the wire inlet hole 11 is formed in one side of the wire clamping plate 3, the wire inlet hole 11 is used for preventing the rubber round tube 4, the rubber round tube 4 is ensured to be static, the wire inlet hole 11 is movably connected with the rubber round tube 4, the wire inlet hole 11 is ensured to be integrated with the rubber round tube 4, the connecting wire is ensured to be static, four first threaded holes 12 are formed in one side of the connecting plate 9, the first threaded holes 12 are used for connecting the threaded nails 6, the threaded nails 6 are in threaded connection with the first threaded holes 12, the threaded nails 6 are ensured to be in threaded connection with the connecting plate 9, the optical module connecting shell 8 is internally provided with the optical module clamping groove 13, the optical module clamping groove 13 is used for placing the optical module, the optical module is protected from being influenced by external force, the two clamping grooves 14 are formed in one side of the optical module connecting shell 8, the clamping groove 14 is used for connecting the optical module connecting shell 8 with the connecting plate 9, ensure that the optical module connecting shell 8 and the connecting plate 9 are integrated, the clamping block 7 is movably connected with the clamping groove 14, ensure that the optical module connecting shell 8 and the connecting plate 9 are integrated, simultaneously play the role of auxiliary connection, four second threaded holes 15 are formed in one side of the optical module connecting shell 8, the second threaded holes 12 are used for connecting threaded nails 6, a left elastic plate 16 is arranged in the optical module clamping groove 13, the left elastic plate 16 is used for fixing the optical module, ensure that the optical module is stationary during connection, a second rubber plate 25 is arranged at the bottom of the optical module connecting shell 8, the second rubber plate 25 is used for protecting the rectifying and deviation preventing device, protecting the optical module inside, the threaded nails 6 are in threaded connection with the connecting plate 9 and the optical module connecting shell 8, ensure that the connecting plate 9 and the optical module connecting shell 8 are integrated, ensuring that the optical module and the connection line are in a stationary state when internally connected.

The left spring groove 17 is arranged on one side of the optical module clamping groove 13, the left spring groove 17 is used for fixing the positions of the left spring plate 16 and the left spring 18 to ensure the normal operation of the optical module, the left spring 18 is arranged on one side of the left spring groove 17, the left spring 18 is used for pushing the left spring plate 16 to ensure the static and fixed state of the optical template in the optical module clamping groove, the left spring plate 16 is fixedly connected with the left spring 18 to ensure the left spring plate 16 and the left spring 18 to be integrated, the static and fixed state of the optical template in the optical module clamping groove is ensured, the right spring plate 19 is arranged on one side of the optical module clamping groove 13, the right spring plate 19 is used for fixing the optical module to ensure the static and fixed state of the optical module during the connection, the right spring groove 21 is arranged on one side of the optical module clamping groove 13, the right spring groove 21 is used for fixing the positions of the right spring plate 19 and the right spring 20 to ensure the normal operation of the optical module clamping groove, the right spring 20 is arranged on one side of the right spring groove 21, the right side spring 20 is used for pushing the right side spring plate 19 to ensure that the optical template is static in the optical template clamping groove, the right side spring plate 19 is fixedly connected with the right side spring 20 to ensure that the right side spring plate 19 and the right side spring 20 are integrated, the optical template is static in the optical template clamping groove, the top surface of the optical module clamping groove 13 is provided with a top surface spring plate 22, the top surface spring plate 22 is used for fixing the optical module to ensure that the optical module is static in connection, the top surface of the optical module clamping groove 13 is provided with a top surface spring groove 24, the top surface spring groove 24 is used for fixing the positions of the top surface spring plate 22 and the top surface spring 23 to ensure that the optical template works normally, the top surface spring groove 24 is provided with a top surface spring 23, the top surface spring 23 is used for pushing the top surface spring plate 22 to ensure that the optical template is static in the optical template clamping groove, the top surface spring plate 22 is fixedly connected with the top surface spring 23 to ensure that the top surface spring plate 22 is integrated, ensure that the optical template is static in optical template draw-in groove, first rubber slab 10 and second rubber slab 25 bottom surface set up to the wave for increase the frictional force of rubber slab bottom surface, increase the whole frictional force of anti-migration device bottom surface, first rubber slab 10 and termination shell 1 fixed connection ensure that first rubber 10 and termination shell 1 are as an organic whole, protect its inside connecting wire and optical module, second rubber slab 25 and optical module connect shell 8 fixed connection, ensure that second rubber 25 and optical module connect shell 8 are as an organic whole, protect its inside connecting wire and optical module.

Working principle: when the optical module testing device is used, a worker firstly takes down the screw 6, separates the connecting plate 9 from the optical module connecting shell 8, passes the connecting wire head through the rubber piston 5 from the rubber round tube 4 from the side without the connecting plate 9, places the connecting wire head in the wire inlet groove 2, then inserts the optical module into the optical module clamping groove 13 from the side without the clamping groove 14, pushes the left elastic plate 16, the right elastic plate 19 and the top elastic plate 22 to clamp the optical module in the optical module clamping groove 13 by the spring thrust of the left elastic plate 18, the right elastic plate 20 and the top elastic plate 23, then connects the connecting wire with the optical module, pushes the connecting plate 9 to clamp the clamping block 7 in the clamping groove 14, and then twists the screw 6 to pass through the left threaded hole 12 and the second threaded hole 15 to complete the assembly of the anti-offset device, so that the optical module testing device can be started.

Although the utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the arrangement of the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the utility model.

Claims (6)

1. The utility model provides an optical module test is with preventing skew device, includes termination shell (1), its characterized in that: wire casing (2) have been seted up to termination shell (1) inside, wire casing (2) inside is provided with card line board (3), card line board (3) inside is provided with rubber pipe (4), rubber pipe (4) inside is provided with rubber piston (5), rubber pipe (4) and rubber piston (5) fixed connection, termination shell (1) one side is provided with connecting plate (9), termination shell (1) and connecting plate (9) fixed connection, connecting plate (9) one side is provided with four screw nails (6), connecting plate (9) one side is provided with optical module connection shell (8), connecting plate (9) one side is provided with two fixture blocks (7), termination shell (1) bottom is provided with first rubber plate (10).

2. The anti-offset device for optical module testing according to claim 1, wherein: wire inlet holes (11) are formed in one side of the wire clamping plate (3), the wire inlet holes (11) are movably connected with the rubber round tubes (4), four first threaded holes (12) are formed in one side of the connecting plate (9), and the threaded nails (6) are in threaded connection with the first threaded holes (12).

3. The anti-offset device for optical module testing according to claim 1, wherein: optical module draw-in groove (13) have been seted up to optical module connection shell (8) inside, two draw-in grooves (14) have been seted up to optical module connection shell (8) one side, fixture block (7) and draw-in groove (14) swing joint, four second screw holes (15) have been seted up to optical module connection shell (8) one side, screw nail (6) and second screw hole (15) threaded connection, optical module draw-in groove (13) inside is provided with left side spring plate (16), optical module connection shell (8) bottom is provided with second rubber slab (25).

4. The anti-offset device for optical module testing according to claim 1, wherein: the screw nail (6) is in threaded connection with the connecting plate (9) and the optical module connecting shell (8).

5. An anti-migration device for optical module testing according to claim 3, wherein: the optical module is characterized in that a left spring groove (17) is formed in one side of the optical module clamping groove (13), a left spring (18) is arranged on one side of the left spring groove (17), the left spring plate (16) is fixedly connected with the left spring (18), a right spring plate (19) is arranged on one side of the optical module clamping groove (13), a right spring groove (21) is formed in one side of the optical module clamping groove (13), a right spring (20) is arranged on one side of the right spring groove (21), the right spring plate (19) is fixedly connected with the right spring (20), a top spring plate (22) is arranged on the top surface of the optical module clamping groove (13), a top spring groove (24) is formed in the top surface of the optical module clamping groove (13), and a top spring (23) is arranged on the top surface of the top spring groove (24), and the top spring plate (22) is fixedly connected with the top spring (23).

6. The anti-offset device for optical module testing according to claim 1, wherein: the bottom surfaces of the first rubber plate (10) and the second rubber plate (25) are wavy, the first rubber plate (10) is fixedly connected with the wiring device shell (1), and the second rubber plate (25) is fixedly connected with the optical module connecting shell (8).