CN219737832U - Optical fiber connector disassembling device - Google Patents

Abstract

The utility model relates to the technical field of optical fiber connectors, and provides an optical fiber connector disassembling device, wherein when an optical fiber connector is required to be installed, a clamping part clamps one movable optical fiber connector to align with the other optical fiber connector through a clamping space and moves along the horizontal direction so as to enable the two optical fiber connectors to be clamped with each other; when the optical fiber connector needs to be pulled out, the clamping part clamps the optical fiber connector through the clamping space, and the abutting part abuts against the connector to press the connector to deform the connector by pressing the pressing rod downwards, so that the optical fiber connector can be moved to be separated from the clamping connection. The utility model has smaller space in the process of deployment operation, can realize the plug of the optical fiber connector in the high-density wiring box with small space, and is not easy to touch other optical fiber channels in the high-density wiring box; in addition, this fiber connector dismounting device's simple structure, use convenient, promoted fiber connector's efficiency in disassembling and installation.

Description

Optical fiber connector disassembling device

Technical Field

The utility model relates to the technical field of optical fiber connectors, in particular to an optical fiber connector disassembling device.

Background

In the existing wiring system in the optical communication industry, the ferrules of two optical fiber connectors are inserted into an adapter for butt joint, and optical signals can be transmitted after butt joint. The conventional optical fiber connector adopts a push-type connecting structure, the clamping part is required to be manually pushed by conventional plug-in, and a finger is inserted into the front side of the adapter to pull out the optical fiber connector, but because a dense wiring environment in the connector cannot reserve enough space for the finger to move, the optical fiber connector can be damaged by forced pull-out, and the plug-in angle between the surrounding connectors and the corresponding adapter can be changed to influence data transmission. Therefore, people often resort to other auxiliary operating tools.

Currently, people combine optical fiber connectors by designing a push-pull type disassembling or installing device, such as a Chinese patent utility model patent with publication number of CN214067445U and publication number of 2021, 8 and 27, and a patent name of push-pull rod type LC optical fiber connector, which realizes push-pull effect through movement of a push-pull rod, and can easily pull or install the whole connector from an equipment interface, thereby realizing the installation and the disassembly of the optical fiber connector, however, in a high-density wiring box, the operation space for plugging and unplugging the optical fiber connector is smaller, the installation of the connector is easy to interfere with other optical fiber channels through push-pull movement, and meanwhile, when encountering the high-density wiring box with smaller size, the deployment space of the push-pull structure is smaller, thereby resulting in lower installation or disassembly efficiency, so the device has limitations.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide a disassembling device which is convenient for unfolding in a narrow space and improves the installation or disassembly efficiency of an optical fiber connector.

In order to solve the problems, the utility model provides the following technical scheme:

an optical fiber connector disassembly device, the optical fiber connector comprising a connector press buckle, the optical fiber connector disassembly device comprising:

the pressing main body comprises a supporting part, a connecting part integrally connected with the supporting part and a clamping part arranged at the end part of the connecting part, wherein a clamping space for the optical fiber connector to enter and a wire containing groove for the cable of the optical fiber connector to pass through are concavely arranged on the clamping part;

the elastic component is movably connected with the pressing main body; the elastic component comprises a pressing rod penetrating through the supporting part and an abutting part arranged at the end part of the pressing rod and penetrating through the connecting part, and the abutting part penetrates through the connecting part and then enters the clamping space;

when the optical fiber connectors are required to be installed, the clamping part clamps one movable optical fiber connector to align with the other optical fiber connector through the clamping space and moves along the horizontal direction so as to enable the two optical fiber connectors to be clamped with each other;

when the optical fiber connector is required to be pulled out, the clamping part clamps one optical fiber connector through the clamping space, the abutting part is pressed against the connector pressing buckle by pressing down the pressing rod so as to deform the connector pressing buckle, and therefore one optical fiber connector can be moved to be separated from the clamping connection.

Further, the support part is arranged along a first direction, and the compression bar is arranged along a second direction;

the elastic component further comprises a first limiting part and a second limiting part which are respectively arranged at two ends of the compression bar along a second direction, the second limiting part is close to the clamping part, and the abutting part is arranged at the end part of the second limiting part along the second direction;

the first direction is perpendicular to the second direction.

Further, the second limiting portion is arranged at intervals with the supporting portion and the engagement portion along the second direction.

Further, the pressing body further includes a connecting portion connecting the supporting portion and the engaging portion;

the supporting part, the connecting part and the connecting part are arranged into an integrated structure.

Further, the pressing main body further comprises a spring sleeved on the pressing rod, and the spring is arranged between the first limiting part and the supporting part;

the first limiting part and the second limiting part are both arranged to be of cylindrical structures, and the diameter of the spring is smaller than that of the first limiting part.

Further, the clamping parts are respectively arranged at two sides of the connecting part along a third direction;

the third direction is perpendicular to the first direction and the second direction;

the clamping portion comprises a first clamping arm fixed with the connecting portion along a second direction and a second clamping arm connected with the first clamping arm along the first direction.

Further, the engagement portion and the second clamping arm form an opening facing the optical fiber connector along a first direction, and a first sliding groove is concavely formed in the side edge of the engagement portion, which is positioned at the opening, facing the clamping space;

the end part of the second clamping arm, which is positioned at the opening, is concavely provided with a second sliding groove facing the clamping space.

Further, the connecting part is provided with a through groove for the abutting part to penetrate;

under the elastic natural state of the spring, the part of the abutting part in the through groove is flush with the first chute along a first direction;

the distance between the second limiting part and the supporting part along the second direction is greater than or equal to the depth of the through groove along the second direction.

Further, the supporting portion protrudes from the connecting portion along the first direction and exceeds the clamping space.

Further, the wire containing groove is communicated with the outside along the first direction.

The beneficial effects of the utility model are as follows: by arranging the elastic component on the pressing main body, the pressing rod can press the connector to press the buckle so as to separate the optical fiber connector after being stressed, and the structure ensures that the optical fiber connector can be plugged and pulled even in a high-density wiring box with a narrow space, and other optical fiber channels in the high-density wiring box are not easily touched; in addition, this fiber connector dismounting device's simple structure, use convenient, the required space in the operation in-process of performing is less, has promoted fiber connector's efficiency in dismantling and installation.

Drawings

FIG. 1 is a schematic view of an embodiment of an optical fiber connector disassembly device according to the present utility model;

FIG. 2 is a cross-sectional view of one embodiment of a fiber optic connector disassembly apparatus according to the present utility model;

fig. 3 is a schematic view of an embodiment of a fiber optic connector disassembly device according to the present utility model.

Reference numerals:

100. an optical fiber connector disassembling device; 200. an optical fiber connector; 201. pressing and buckling the connector; 110. pressing the main body; 120. an elastic component; 111. a support part; 112. a joint portion; 113. a clamping part; 121. a compression bar; 122. an abutting portion; 123. a first limit part; 124. a second limit part; 114. a connection part; 125. a spring; 12a, a clamping space; 126. rong Xiancao; 131. a first clamping arm; 132. a second clamping arm; 141. an opening; 142. a first chute; 143. a second chute; 144. a through groove; 150. a high-density wiring box.

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.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

For convenience in description of the first direction and the second direction in the embodiment of the present utility model, the first direction is a left-right direction in the drawing, the second direction is an up-down direction in the drawing, and the third direction is a front-back direction in the drawing. The x-axis arrow direction is referred to as the "right" direction, the y-axis arrow direction is referred to as the "up" direction, and the z-axis arrow direction is referred to as the "back" direction.

Referring to fig. 1-3, the present embodiment provides an optical fiber connector disassembling device 100 for installing or disassembling an optical fiber connector in a high-density wiring box 150, wherein the optical fiber connector 200 includes a connector press buckle 201, and the optical fiber connector disassembling device 100 further includes a pressing body 110 and an elastic component 120 movably connected to the pressing body 110; the pressing body 110 includes a supporting portion 111, a connecting portion 112 integrally connected with the supporting portion 111, and a clamping portion 113 disposed at an end of the connecting portion 112, where the clamping portion 113 is concavely provided with a clamping space 12a for the optical fiber connector 200 to enter and a wire containing slot 126 for a cable of the optical fiber connector 200 to pass through; the elastic component 120 includes a pressing rod 121 penetrating the supporting portion 111, and an abutting portion 122 disposed at an end of the pressing rod 121 and penetrating the engaging portion 112, wherein the abutting portion 122 penetrates the engaging portion 112 and then enters the engaging space 12a.

In the above-described aspect, it can be understood that, when the optical fiber connectors 200 need to be installed, the clamping portion 113 clamps one movable optical fiber connector 200 by the clamping space 12a to move in the horizontal direction in alignment with the other optical fiber connector so as to clamp the two optical fiber connectors to each other;

when the optical fiber connector 200 needs to be pulled out, the clamping portion 113 clamps one optical fiber connector 200 through the clamping space 12a, and the abutting portion 122 abuts against the connector pressing buckle 201 by pressing the pressing rod 121, so that the connector pressing buckle 201 is deformed, and one optical fiber connector can be moved to be separated from the clamping connection.

Referring to fig. 1-2, in the above-mentioned scheme, the supporting portion 111 is disposed along the first direction, and the compression bar 121 is disposed along the second direction; in addition, the elastic component 120 includes a first limiting portion 123 and a second limiting portion 124 that are disposed at two ends along the second direction, the second limiting portion 124 is close to the clamping portion 113, and the abutting portion 122 is disposed at an end of the second limiting portion 124 along the second direction; in this embodiment, the first limiting portion 123 and the compression bar 121 are integrally formed, the second limiting portion 124 is in threaded connection with the compression bar 121, and the abutting portion 122 and the second limiting portion 124 are integrally formed.

As shown in fig. 1-2, preferably, the pressing body 110 further includes a connecting portion 114 connecting the supporting portion 111 and the engaging portion 112, wherein the connecting portion 114 is disposed along the second direction, and the supporting portion 111, the connecting portion 114 and the engaging portion 112 are disposed as an integrally formed structure, which stabilizes the overall structure of the pressing body 110 and has a long service life; further, the second limiting portion 124 is disposed at intervals from the supporting portion 111 and the engaging portion 112 along the second direction, and the second limiting portion 124 limits the moving range of the compression bar 121 along the second direction; further, the pressing body 110 further includes a spring 125 sleeved on the pressing rod 121, the spring 125 is installed between the first limiting portion 123 and the supporting portion 111, and in this embodiment, the first limiting portion 123 and the second limiting portion 124 are both provided with a cylindrical structure, the diameter of the spring 125 is smaller than that of the first limiting portion 123, and this structure is to prevent the user from scratching the hand during the expansion and contraction of the spring 125 when pressing the first limiting portion 123, so as to play a role in safety protection; in addition, the clamping portions 113 are respectively disposed on two sides of the engagement portion 112 along the third direction, in this embodiment, the clamping portions 113 are configured as an "L" structure, and a clamping space 12a for clamping the optical fiber connector 200 is formed between the two clamping portions 113 and the engagement portion 112, and the wire containing slot 126 is communicated with the outside along the first direction, so as to facilitate routing; further, in the present embodiment, the supporting portion 111 protrudes from the connecting portion 114 along the first direction and exceeds the engaging space 12a, so that the user can support the first limiting portion 123 through the supporting plate 111 while balancing the force applied by the pressing body 110.

Referring to fig. 1-2, specifically, the clamping portion 113 includes a first clamping arm 131 fixed to the engaging portion 112 along a second direction and a second clamping arm 132 connected to the first clamping arm 131 along the first direction, in this embodiment, the first clamping arm 131 and the second clamping arm 132 are integrally formed, in addition, the engaging portion 112 and the second clamping arm 132 form an opening 141 facing the optical fiber connector 200 along the first direction, and a first chute 142 is concavely disposed on a side edge of the engaging portion 112 located at the opening 141 facing the clamping space 12 a; the end part of the second clamping arm 132, which is positioned at the opening 141, is concavely provided with a second sliding groove 143 facing the clamping space 12 a; this structure is such that the opening 141 of the clamping space 12a can be easily aligned with another optical fiber connector when the optical fiber connector 200 is mounted by the first and second sliding grooves 142 and 143, thereby facilitating the clamping.

Referring to fig. 2-3, preferably, the engagement portion 112 is provided with a through slot 144 through which the abutment portion 122 can pass; when the elasticity of the spring 125 is in the natural state, the portion of the abutting portion 122 in the through groove 144 is flush with the first chute 142 along the first direction, and at this time, the distance between the second limiting portion 124 and the supporting portion 111 along the second direction is greater than or equal to the depth of the through groove 144 along the second direction; this structure is such that when the second limiting portion 124 and the abutting portion 122 move in the second direction and abut against the supporting portion 111, the sum of the heights of the second limiting portion 124 and the abutting portion 122 in the second direction is less than or equal to the linear distance between the engaging portion 112 and the supporting portion 111, thereby facilitating the installation and removal of the second limiting portion 124 and the abutting portion 122.

Referring to fig. 1-3, in the implementation process, when a user needs to clamp one of the movable optical fiber connectors 200 onto another fixed optical fiber connector, first, by aligning the opening 141 of the clamping space 12a with the movable optical fiber connector 200, the pressing body 110 is moved along the first direction so that the optical fiber connector 200 enters the clamping space 12a and is clamped by the clamping portion 113; at this time, the other fiber connector is aligned to move in the horizontal direction so that the two fiber connectors are clamped with each other; when a user needs to pull one of the extractable fiber optic connectors 200 out of the other fixed fiber optic connector, the movable fiber optic connector 200 is aligned through the opening 141 of the clamping space 12a, the pressing body 110 is moved along the first direction to enable the fiber optic connector 200 to enter the clamping space 12a and be clamped by the clamping portion 113, then the pressing rod 121 is pressed down by pressing the first limiting portion 123 to enable the abutting portion 122 to be separated from the through groove 144 and to abut against the connector pressing buckle 201 to enable the connector pressing buckle 201 to deform, so that the movable fiber optic connector 200 is separated from the clamping, at the moment, the first limiting portion 123 is released, and the spring 125 returns to the natural state and drives the pressing rod 121 to return to the original height.

In summary, the present utility model provides an optical fiber connector disassembling device, in which an elastic component is disposed on a pressing body, so that a pressing rod is held by a spring, and then presses down a connector press buckle to separate the optical fiber connector, and the structure enables the optical fiber connector to be plugged into and pulled out of a high-density wiring box with a narrow space, and is not easy to touch other optical fiber channels in the high-density wiring box; in addition, this fiber connector dismounting device's simple structure, use convenient, the required space in the operation in-process of performing is less, has promoted fiber connector's efficiency in dismantling and installation.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be appreciated by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not drive the essence of the corresponding technical solutions to depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. An optical fiber connector disassembly device, the optical fiber connector comprising a connector press buckle, the optical fiber connector disassembly device comprising:

the pressing main body comprises a supporting part, a connecting part integrally connected with the supporting part and a clamping part arranged at the end part of the connecting part, wherein a clamping space for the optical fiber connector to enter and a wire containing groove for the cable of the optical fiber connector to pass through are concavely arranged on the clamping part;

the elastic component is movably connected with the pressing main body; the elastic component comprises a pressing rod penetrating through the supporting part and an abutting part arranged at the end part of the pressing rod and penetrating through the connecting part, and the abutting part penetrates through the connecting part and then enters the clamping space;

when the optical fiber connectors are required to be installed, the clamping part clamps one movable optical fiber connector to align with the other optical fiber connector through the clamping space and moves along the horizontal direction so as to enable the two optical fiber connectors to be clamped with each other;

when the optical fiber connector is required to be pulled out, the clamping part clamps one optical fiber connector through the clamping space, the abutting part is pressed against the connector pressing buckle by pressing down the pressing rod so as to deform the connector pressing buckle, and therefore one optical fiber connector can be moved to be separated from the clamping connection.

2. The fiber optic connector disassembly apparatus of claim 1, wherein: the support part is arranged along a first direction, and the compression bar is arranged along a second direction;

the elastic component further comprises a first limiting part and a second limiting part which are respectively arranged at two ends of the compression bar along a second direction, the second limiting part is close to the clamping part, and the abutting part is arranged at the end part of the second limiting part along the second direction;

the first direction is perpendicular to the second direction.

3. The fiber optic connector disassembly apparatus of claim 2, wherein: the second limiting part is arranged at intervals with the supporting part and the connecting part along the second direction.

4. The fiber optic connector disassembly apparatus of claim 1, wherein: the pressing body further comprises a connecting part for connecting the supporting part and the connecting part;

the supporting part, the connecting part and the connecting part are arranged into an integrated structure.

5. The fiber optic connector disassembly apparatus of claim 2, wherein: the pressing main body further comprises a spring sleeved on the pressing rod, and the spring is arranged between the first limiting part and the supporting part;

the first limiting part and the second limiting part are both arranged to be of cylindrical structures, and the diameter of the spring is smaller than that of the first limiting part.

6. The fiber optic connector disassembly apparatus of claim 5 wherein: the clamping parts are respectively arranged at two sides of the connecting part along a third direction;

the third direction is perpendicular to the first direction and the second direction;

the clamping portion comprises a first clamping arm fixed with the connecting portion along a second direction and a second clamping arm connected with the first clamping arm along the first direction.

7. The fiber optic connector disassembly apparatus of claim 6 wherein: the engagement part and the second clamping arm form an opening facing the optical fiber connector along a first direction, and a first chute is concavely arranged on the side edge of the engagement part, which is positioned at the opening, facing the clamping space;

the end part of the second clamping arm, which is positioned at the opening, is concavely provided with a second sliding groove facing the clamping space.

8. The fiber optic connector disassembly apparatus of claim 7 wherein: the connecting part is provided with a through groove for the abutting part to penetrate through;

under the elastic natural state of the spring, the part of the abutting part in the through groove is flush with the first chute along a first direction;

the distance between the second limiting part and the supporting part along the second direction is greater than or equal to the depth of the through groove along the second direction.

9. The fiber optic connector disassembly apparatus of claim 4 wherein: the supporting part protrudes out of the connecting part along the first direction and exceeds the clamping space.

10. The fiber optic connector disassembly apparatus of claim 1, wherein: the wire containing groove is communicated with the outside along a first direction.