CN220399687U - Single-fiber bidirectional 100G LR4 optical module - Google Patents

Abstract

The utility model relates to the technical field of single-fiber bidirectional optical modules, and discloses a single-fiber bidirectional 100GLR4 optical module, which comprises an optical module, wherein the left side of the optical module is connected with a sealing mechanism, and the right side of the optical module is connected with a dustproof clamping mechanism; the sealing mechanism comprises a sealing plate, the side surface of the sealing plate is connected with a sealing plug, the sealing plate is connected with a moving rod, and the moving rod is connected with a groove; the dustproof clamping mechanism comprises a sliding plate. This two-way 100G LR4 optical module of single fiber, through connecting sealing mechanism on optical module's shell, can prevent again that sealing mechanism from losing when realizing sealing ability protection to optical module's inserted hole, the use of optical module produces the influence, through dustproof fixture, utilizes sliding plate and spring to carry out the centre gripping fastening to the optic fibre jumper wire of inserting, and the elasticity gasket protects the optic fibre jumper wire simultaneously, avoids causing the harm to the optic fibre jumper wire.

Description

Single-fiber bidirectional 100G LR4 optical module

Technical Field

The utility model relates to the technical field of single-fiber bidirectional optical modules, in particular to a single-fiber bidirectional 100G LR4 optical module.

Background

The optical module is composed of an optoelectronic device, a functional circuit, an optical interface and the like, and is used for converting an electric signal into an optical signal at a transmitting end, receiving the optical signal, converting the optical signal into the electric signal and completing subsequent processing.

The single-fiber bidirectional optical module sealing device in the current market is separated from an optical module body, is easy to lose, is not provided with an optical fiber jumper fixing mechanism, is easy to loose, is used for sealing an interface end through the sealing device, is not easy to enter an inner cavity of the optical module, protects an inner element of the optical module, prolongs the service life of the optical module, is easy to lose due to the fact that the sealing device is separated from the optical module body, and is unstable in optical fiber interface and easy to fall off when the optical module is connected with the optical fiber jumper, and therefore, the single-fiber bidirectional 100G LR4 optical module is provided for solving the problems mentioned in the background.

Disclosure of Invention

(one) solving the technical problems

The present utility model is directed to a single-fiber bidirectional 100g LR4 optical module, so as to solve the above-mentioned problems in the prior art.

(II) technical scheme

In order to solve the technical problems, the utility model provides the following technical scheme: the single-fiber bidirectional 100G LR4 optical module comprises an optical module, wherein the left side of the optical module is connected with a sealing mechanism, and the right side of the optical module is connected with a dustproof clamping mechanism;

the sealing mechanism comprises a sealing plate, the side surface of the sealing plate is connected with a sealing plug, the sealing plate is connected with a moving rod, and the moving rod is connected with a groove;

the dustproof clamping mechanism comprises a sliding plate, an elastic gasket is connected to the side face of the sliding plate, a protrusion is arranged on the surface of the sliding plate, a sliding groove is formed in the outer portion of the protrusion, a baffle is connected to the side face of the sliding plate, a spring is connected to the baffle, and a round rod is connected to the spring.

Preferably, the optical module comprises a shell, an insertion port is formed in the left side of the shell, a plug wire port is formed in the right side of the shell, a circuit board is connected to the inside of the shell, and an optical transceiver component is connected to the circuit board.

The structure can realize the conversion between the optical signal and the electric signal by the optical module, and the optical data is transmitted.

Preferably, the sealing plate is connected to the insertion opening by a magnet.

The sealing plate is adsorbed on the insertion opening through the attraction force of the magnet on the sealing plate, so that the sealing plate is prevented from being easily separated from the insertion opening under the action of external force, and the sealing effect is ensured.

Preferably, the grooves and the sliding grooves are formed in the surface of the shell.

The sealing mechanism and the dustproof clamping mechanism can slide on the surface of the shell through the grooves and the sliding grooves.

Preferably, the sealing plug is engaged with the circuit board.

The sealing plug is clamped on the circuit board, so that the part of the circuit board which extends out and is not supported can be supported and protected when the circuit board is not used, and the circuit board is prevented from being damaged.

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

1. according to the single-fiber bidirectional 100G LR4 optical module, the sealing mechanism is connected to the shell of the optical module, so that the sealing can be protected while the insertion port of the optical module is sealed, the sealing mechanism is prevented from being lost, and the use of the optical module is influenced.

2. This two-way 100G LR4 optical module of single fiber utilizes sliding plate and spring to carry out the centre gripping fastening to the optic fibre jumper wire of inserting through dustproof fixture, and the elasticity gasket protects the optic fibre jumper wire simultaneously, avoids causing the harm to the optic fibre jumper wire.

Drawings

FIG. 1 is a schematic top view of the present utility model;

FIG. 2 is an enlarged schematic view of portion A of FIG. 1 in accordance with the present utility model;

FIG. 3 is a schematic top view of the present utility model;

fig. 4 is a schematic side sectional view of the present utility model.

Wherein: 1. an optical module; 11. a housing; 12. an insertion port; 13. a wire insertion opening; 14. a circuit board; 15. an optical transceiver module; 2. a sealing mechanism; 21. a sealing plate; 22. a sealing plug; 23. a moving rod; 24. a groove; 3. a dust-proof clamping mechanism; 31. a sliding plate; 32. an elastic pad; 33. a protrusion; 34. a chute; 35. a baffle; 36. a spring; 37. a round rod.

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.

Referring to fig. 1-4, a single-fiber bidirectional 100g LR4 optical module includes an optical module 1, a sealing mechanism 2 is connected to the left side of the optical module 1, and a dustproof clamping mechanism 3 is connected to the right side of the optical module 1;

the sealing mechanism 2 comprises a sealing plate 21, a sealing plug 22 is connected to the side surface of the sealing plate 21, a moving rod 23 is connected to the sealing plate 21, and a groove 24 is connected to the moving rod 23;

the dustproof clamping mechanism 3 comprises a sliding plate 31, an elastic gasket 32 is connected to the side face of the sliding plate 31, a protrusion 33 is arranged on the surface of the sliding plate 31, a sliding groove 34 is connected to the outside of the protrusion 33, a baffle 35 is connected to the side face of the sliding plate 31, a spring 36 is connected to the baffle 35, and a round rod 37 is connected to the spring 36.

Specifically, the optical module 1 includes a housing 11, an insertion port 12 is provided on the left side of the housing 11, a plug wire port 13 is provided on the right side of the housing 11, a circuit board 14 is connected to the interior of the housing 11, and an optical transceiver component 15 is connected to the circuit board 14.

Through the technical scheme, the optical module 1 enables the structure to realize the conversion between the optical signal and the electric signal of the optical module and transmit the photoelectric data.

Specifically, the sealing plate 21 is connected to the insertion port 12 via a magnet.

By the above technical scheme, the attraction force of the magnet on the sealing plate 21 adsorbs the sealing plate 21 on the insertion port 12, so that the sealing plate 21 is prevented from being easily separated from the insertion port 12 under the action of external force, and the sealing effect is ensured.

Specifically, the groove 24 and the chute 34 are provided on the surface of the housing 11.

By the technical scheme, the grooves 24 and the sliding grooves 34 are formed in the surface of the shell 11, so that the sealing mechanism 2 and the dustproof clamping mechanism 3 can slide on the surface of the shell 11.

Specifically, the sealing plug 22 engages the circuit board 14.

Through the above technical scheme, the sealing plug 22 is clamped on the circuit board 14, so that the part of the circuit board 14 which extends out of the support is supported and protected when the circuit board 14 is not used, and the circuit board 14 is prevented from being damaged.

When the optical fiber patch is used, the movable rod 23 moves leftwards along the groove 24 to drive the sealing plug 22 and the sealing plate 21 to leave the insertion port 12 leftwards, the movable rod 23 rotates in the groove 24 to enable the sealing plate 21 and the sealing plug 22 to rotate upwards or downwards to expose the insertion port 12, the insertion port 12 is inserted into an external machine, the sliding plate 31 moves towards two sides of the patch cord port 13 to drive the baffle 35 to compress the spring 36 to expose the patch cord port 13, the optical fiber patch cord is inserted into the patch cord port 13, the elastic force of the spring 36 is utilized to push the baffle 35, the sliding plate 31 and the elastic gasket 32 to clamp and fix the optical fiber patch cord, and the single-fiber bidirectional 100G LR4 optical module is ensured to be stably transmitted at the transmission rate of 100G and the transmission distance of ten kilometers.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. A single fiber bi-directional 100g LR4 optical module comprising an optical module (1), characterized in that: the left side of the optical module (1) is connected with a sealing mechanism (2), and the right side of the optical module (1) is connected with a dustproof clamping mechanism (3);

the sealing mechanism (2) comprises a sealing plate (21), a sealing plug (22) is connected to the side face of the sealing plate (21), the sealing plate (21) is connected with a moving rod (23), and the moving rod (23) is connected with a groove (24);

the dustproof clamping mechanism (3) comprises a sliding plate (31), an elastic gasket (32) is connected to the side face of the sliding plate (31), a protrusion (33) is arranged on the surface of the sliding plate (31), a sliding groove (34) is formed in the outer portion of the protrusion (33), a baffle (35) is connected to the side face of the sliding plate (31), a spring (36) is connected to the baffle (35), and a round rod (37) is connected to the spring (36).

2. The single fiber bi-directional 100g LR4 optical module as claimed in claim 1, wherein: the optical module (1) comprises a shell (11), an inserting port (12) is formed in the left side of the shell (11), a plug wire port (13) is formed in the right side of the shell (11), a circuit board (14) is connected to the inside of the shell (11), and an optical receiving and transmitting assembly (15) is connected to the circuit board (14).

3. The single fiber bi-directional 100g LR4 optical module as claimed in claim 2, wherein: the sealing plate (21) is connected to the insertion opening (12) through a magnet.

4. The single fiber bi-directional 100g LR4 optical module as claimed in claim 2, wherein: the groove (24) and the chute (34) are arranged on the surface of the shell (11).

5. The single fiber bi-directional 100g LR4 optical module as claimed in claim 1, wherein: the sealing plug (22) is clamped with the circuit board (14).