CN213028891U - Novel optical communication case structure - Google Patents

Abstract

The utility model belongs to the field of optical communication cabinets, in particular to a novel optical communication cabinet structure, which comprises a shell, wherein the shell is provided with three slots, the shell is fixedly connected with three positioning parts, and each positioning part comprises two connecting blocks, two baffles and two connecting plates; insert the back with the optical communication device among the interlude groove, the optical communication device body gets into between two movable blocks with the extrusion of second pressure spring messenger second pressure spring shrink this moment the direction that receives the movable block inclined plane, thereby be applicable to the optical communication device body of different width, later continue to promote the slider along the spout to the inboard of mounting bracket and make first pressure spring pressurized shrink, the shrink through first pressure spring makes the optical communication device body that can insert different length in the mounting bracket, reaction force through first pressure spring promotes the optical communication device end and realizes the location between the outer wall of baffle and casing, installation easy operation, it is applicable in not unidimensional optical communication device body.

Description

Novel optical communication case structure

Technical Field

The utility model belongs to optical communication machine case field specifically is a novel optical communication machine case structure.

Background

The optical communication equipment is transmission equipment in a communication mode taking light waves as carriers, the optical communication mode based on the infrared LED is point-to-point, and the optical communication equipment has the characteristics of high price ratio, simplicity in implementation, electromagnetic interference resistance, convenience for high-speed application, flexibility in space access and economy, can be used for realizing point-to-point and wireless infrared LAN communication and military infrared fuzes indoors and outdoors, and is widely applied to equipment for mobile computing and mobile communication.

The existing optical communication equipment case is not convenient for adjusting the length of the mounting frame, and cannot be adjusted and installed according to optical communication device bodies with different sizes during installation, so that the applicability of the case is affected, the application range is reduced, and the practicability is lowered.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel optical communication machine case structure to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

a novel optical communication case structure comprises a shell, wherein the shell is provided with three insertion slots, the shell is fixedly connected with three positioning parts, the positioning component comprises two connecting blocks, two baffle plates and two connecting plates, the two connecting blocks are fixedly connected with the outer wall of the shell, the two baffle plates respectively penetrate through the two connecting blocks and are in sliding connection with the connecting blocks, the two connecting plates are respectively fixedly connected with the two baffle plates, the shell is fixedly connected with three mounting frames, the mounting frames are internally and slidably connected with sliding blocks, two movable blocks are arranged in the mounting frames, two ends of each sliding block respectively penetrate through the two movable blocks, and two the movable block all with slider sliding connection, the inner wall fixedly connected with first pressure spring of mounting bracket, the one end of first pressure spring with slider fixed connection.

As a further aspect of the present invention: the slider fixedly connected with two fixed plates that are the symmetric distribution, the fixed plate with fixedly connected with second pressure spring between the movable block.

As a further aspect of the present invention: the movable block is provided with a through hole, and the sliding block penetrates through the movable block and is connected with the through hole in a sliding manner.

As a further aspect of the present invention: two sliding grooves are formed in the inner side of the mounting frame, and two ends of the sliding block are connected with the two sliding grooves in a sliding mode respectively.

As a further aspect of the present invention: the outer wall of the mounting rack is provided with three dustproof nets.

As a further aspect of the present invention: and a tension spring is fixedly connected between the connecting plate and the connecting block.

As a further aspect of the present invention: the connecting block is provided with a through groove, and the baffle penetrates through the through groove and is in sliding connection with the through groove.

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

when the optical communication device is installed, an operator pulls the baffle on the inner side of the connecting block to enable the tension spring to extend, then inserts the optical communication device into the inserting groove, at the moment, the optical communication device body enters between the two movable blocks under the guidance of the inclined surfaces of the movable blocks to extrude the second pressure spring to enable the second pressure spring to contract, so that the optical communication device is suitable for optical communication device bodies with different widths, then the sliding block is continuously pushed towards the inner side of the mounting frame along the sliding groove to enable the first pressure spring to be compressed and contracted, the optical communication device bodies with different lengths can be inserted into the mounting frame through the contraction of the first pressure spring, after the optical communication device end is pushed until the optical communication device end is contacted with the outer wall of the shell, the pulling on the baffle is released, at the moment, the tension spring rebounds to drive the baffle to slide to separate and block the optical communication device end, and the optical communication device end, the installation easy operation of this scheme, applicable in the not unidimensional optical communication device body, effectively improved whole suitability and application scope to the practicality has been improved.

Drawings

Fig. 1 is a schematic structural diagram of a novel optical communication chassis structure;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is a diagram illustrating a state of a novel optical communication chassis structure after an optical communication device is installed;

fig. 4 is a schematic structural diagram of a housing, a positioning component, and a mounting rack in a novel optical communication chassis structure.

In the figure: 1. a housing; 11. inserting the slot; 2. a positioning member; 21. connecting blocks; 211. a through groove; 22. a baffle plate; 23. a connecting plate; 231. a tension spring; 3. a mounting frame; 31. a chute; 32. a dust screen; 33. a first pressure spring; 4. a slider; 41. a fixing plate; 5. a movable block; 501. a through hole; 51. and the second pressure spring.

Detailed Description

Referring to fig. 1-4, in the embodiment of the present invention, a novel optical communication case structure comprises a housing 1, the housing 1 is provided with three insertion slots 11, the housing 1 is fixedly connected with three positioning members 2, the positioning members 2 comprise two connecting blocks 21, two baffles 22 and two connecting plates 23, the two connecting blocks 21 are both fixedly connected with the outer wall of the housing 1, the two baffles 22 respectively penetrate through the two connecting blocks 21 and are slidably connected with the connecting blocks 21, the two connecting plates 23 are respectively fixedly connected with the two baffles 22, the housing 1 is fixedly connected with three mounting frames 3, the mounting frames 3 are slidably connected with a slider 4, two movable blocks 5 are arranged in the mounting frames 3, two ends of the slider 4 respectively penetrate through the two movable blocks 5, the two movable blocks 5 are connected with the sliding block 4 in a sliding mode, the inner wall of the mounting frame 3 is fixedly connected with a first pressure spring 33, and one end of the first pressure spring 33 is fixedly connected with the sliding block 4; when the optical communication device body is installed, an operator pulls the baffles 22 on the inner sides of the two connecting blocks 21 to enable the tension spring 231 to extend, at the moment, the distance between the two baffles 22 is increased, then the optical communication device is inserted into the insertion groove 11 formed in the shell 1, at the moment, the optical communication device body is guided by the inclined planes at one ends of the two movable blocks 5, the optical communication device body slides into the space between the two movable blocks 5 to extrude the movable blocks 5 to enable the second compression spring 51 to contract, so that the optical communication device body is suitable for optical communication device bodies with different widths, then the sliding block 4 is continuously pushed towards the inner side of the mounting frame 3 along the sliding groove 31 to enable the first compression spring 33 to be compressed and contracted, the optical communication device bodies with different lengths can be inserted into the mounting frame 3 through contraction of the first compression spring 33, after the optical communication device bodies are pushed until the end of the optical communication device is contacted with the outer wall of the shell 1, the pulling of the, the elasticity through first pressure spring 33 promotes the optical communication device end and realizes the location between the outer wall of baffle 22 and casing 1, and the installation easy operation of this scheme is applicable in not unidimensional optical communication device body, has effectively improved whole suitability and application scope to the practicality has been improved.

In fig. 1 and 3: the sliding block 4 is fixedly connected with two fixed plates 41 which are symmetrically distributed, a second pressure spring 51 is fixedly connected between the fixed plate 41 and the movable block 5, the movable block 5 is provided with a through hole 501, and the sliding block 4 penetrates through the movable block 5 and is in sliding connection with the through hole 501; the through hole 501 is arranged to limit the sliding of the movable block 5, so that the second pressure spring 51 is compressed by pressure to drive the movable block 5 to slide along the sliding block 4 to the fixed plate 41, thereby improving the stability.

In fig. 1 and 3: two sliding grooves 31 are formed in the inner side of the mounting frame 3, and two ends of the sliding block 4 are respectively in sliding connection with the two sliding grooves 31; the sliding limiting effect on the sliding block 4 is achieved by the arrangement of the sliding groove 31, so that the stability when the first pressure spring 33 extends or contracts to drive the sliding block 4 to slide is improved.

In fig. 4: the outer wall of the mounting rack 3 is provided with three dustproof nets 32; the dust screen 32 is arranged to dissipate heat and reduce dust from entering the mounting frame 3.

In fig. 2: a tension spring 231 is fixedly connected between the connecting plate 23 and the connecting block 21, a through groove 211 is formed in the connecting block 21, and the baffle 22 penetrates through the through groove 211 and is in sliding connection with the through groove 211; when the inboard of mounting bracket 3 is inserted with the optical communication device body to needs, earlier lead to the inboard baffle 22 pulling of groove 211 for extension spring 231 extends, thereby removes baffle 22 to the block of slot 11, later can pass slot 11 with the optical communication device body and insert mounting bracket 3 in, and the setting that leads to groove 211 has played the slip limiting displacement to baffle 22, has improved the sliding stability of baffle 22.

The utility model discloses a theory of operation is: when the optical communication device body is installed, an operator pulls the baffles 22 on the inner sides of the two connecting blocks 21 to enable the tension spring 231 to extend, at the moment, the distance between the two baffles 22 is increased, then the optical communication device is inserted into the insertion groove 11 formed in the shell 1, at the moment, the optical communication device body is guided by the inclined planes at one ends of the two movable blocks 5, the optical communication device body slides into the space between the two movable blocks 5 to extrude the movable blocks 5 to enable the second compression spring 51 to contract, so that the optical communication device body is suitable for optical communication device bodies with different widths, then the sliding block 4 is continuously pushed towards the inner side of the mounting frame 3 along the sliding groove 31 to enable the first compression spring 33 to be compressed and contracted, the optical communication device bodies with different lengths can be inserted into the mounting frame 3 through contraction of the first compression spring 33, after the optical communication device bodies are pushed until the end of the optical communication device is contacted with the outer wall of the shell 1, the pulling of the, elasticity through first pressure spring 33 promotes the optical communication device end and realizes the location between the outer wall of baffle 22 and casing 1, the installation easy operation of this scheme, it is applicable in not unidimensional optical communication device body, whole suitability and application scope have effectively been improved, thereby the practicality has been improved, and when dismantling, only need once more with baffle 22 pulling, remove the block to passing slot 11, first pressure spring 33 extends to drive slider 4 and slides and release the optical communication device from mounting bracket 3 in and can realize dismantling.

The above-mentioned, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. A novel optical communication case structure comprises a shell (1), wherein the shell (1) is provided with three insertion slots (11), and is characterized in that the shell (1) is fixedly connected with three positioning parts (2), each positioning part (2) comprises two connecting blocks (21), two baffle plates (22) and two connecting plates (23), the two connecting blocks (21) are fixedly connected with the outer wall of the shell (1), the two baffle plates (22) respectively penetrate through the two connecting blocks (21) and are in sliding connection with the connecting blocks (21), the two connecting plates (23) are respectively fixedly connected with the two baffle plates (22), the shell (1) is fixedly connected with three mounting frames (3), the mounting frames (3) are in sliding connection with sliding blocks (4), two movable blocks (5) are arranged in the mounting frames (3), the both ends of slider (4) run through two respectively movable block (5), and two movable block (5) all with slider (4) sliding connection, the first pressure spring (33) of inner wall fixedly connected with of mounting bracket (3), the one end of first pressure spring (33) with slider (4) fixed connection.

2. The novel optical communication cabinet structure of claim 1, wherein two fixed plates (41) are symmetrically connected to the sliding block (4), and a second compression spring (51) is fixedly connected between the fixed plates (41) and the movable block (5).

3. The novel optical communication chassis structure of claim 1, wherein the movable block (5) is provided with a through hole (501), and the sliding block (4) penetrates through the movable block (5) and is slidably connected with the through hole (501).

4. The novel optical communication cabinet structure according to claim 1, wherein two sliding grooves (31) are formed on the inner side of the mounting frame (3), and two ends of the sliding block (4) are respectively connected with the two sliding grooves (31) in a sliding manner.

5. The novel optical communication cabinet structure of claim 1, wherein the outer wall of the mounting rack (3) is provided with three dust screens (32).

6. The novel optical communication cabinet structure of claim 1, wherein a tension spring (231) is fixedly connected between the connection board (23) and the connection block (21).

7. The novel optical communication cabinet structure of claim 1, wherein the connecting block (21) has a through slot (211), and the baffle (22) penetrates through the through slot (211) and is slidably connected to the through slot (211).

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