CN221010122U - Heat dissipation type optical fiber transceiver - Google Patents

Abstract

The utility model discloses a heat dissipation type optical fiber transceiver, which relates to the technical field of optical fiber transceivers, in particular to a heat dissipation type optical fiber transceiver. Through buffer unit and radiator unit's setting, radiator fan starts during the use, radiator fan blows the cooling tube into later, then blows to the optical fiber transceiver body from the cooling tube from the mouth of blowing again, and then dispel the heat cooling to the heat that the optical fiber transceiver body produced to protect the optical fiber transceiver body, improve life, later when the optical fiber transceiver body accident drops, buffer board compression buffer spring, buffer spring and A blotter and B blotter cooperation are buffered the impact force to having prevented that the optical fiber transceiver from bumping and causing the damage.

Description

Heat dissipation type optical fiber transceiver

Technical Field

The utility model relates to the technical field of optical fiber transceivers, in particular to a heat dissipation type optical fiber transceiver.

Background

An optical fiber transceiver is an ethernet transmission medium conversion unit that exchanges short-distance twisted pair electrical signals with long-distance optical signals, and is also called an optical-to-electrical converter in many places, and the optical fiber transceiver is generally used in a practical network environment where an ethernet cable cannot cover and an optical fiber must be used to extend a transmission distance, and is generally positioned in an access layer application of a broadband metropolitan area network;

The existing optical fiber transceiver has the defects that the heat dissipation is only carried out by a single hole, the heat dissipation effect is not ideal, the heat dissipation efficiency is low, if the heat cannot be timely dissipated, the electronic element inside the optical fiber transceiver can work in a high-temperature state easily, the aging degree of the electronic element is quickened, the service life is shortened, meanwhile, the phenomenon that the optical fiber transceiver is collided when a user works easily occurs due to the fact that the placed position of the optical fiber transceiver is not unique, the problem that the internal parts of the optical fiber transceiver are damaged and fall off easily is caused, and the use of the optical fiber transceiver is affected.

Disclosure of utility model

The utility model aims to provide a heat dissipation type optical fiber transceiver, which solves the problems that the heat dissipation effect is not ideal, the heat dissipation efficiency is low, if the heat cannot be timely dissipated, the electronic element in the optical fiber transceiver can work at a high temperature, the ageing degree of the electronic element is quickened, the service life is shortened, meanwhile, the optical fiber transceiver is easy to fall down when a user works because the placed position of the optical fiber transceiver is not the only position, the internal parts of the optical fiber transceiver are easy to damage and fall off, and the use of the optical fiber transceiver is influenced by the user.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: the heat dissipation type optical fiber transceiver comprises an upper shell, a lower shell and an optical fiber transceiver body, wherein the surfaces of one side of the upper shell and one side of the lower shell are fixedly connected with a buffer assembly, and the middle part of the surface of one side of the lower shell is fixedly connected with a heat dissipation assembly;

The buffer assembly comprises a buffer plate, support columns are fixedly connected to four corners of one side of the buffer plate, an A buffer cushion is fixedly connected to the bottom of each support column, a buffer spring is fixedly connected to the other end of each A buffer cushion, a B buffer cushion is fixedly connected to the other end of each buffer spring, a support cylinder is sleeved on the surface of each support column, and the inner bottom wall of each support cylinder is connected with the corresponding B buffer cushion.

Further, the radiating component comprises a radiating cylinder, a radiating fan is arranged in the radiating cylinder, a dust screen is fixedly connected to the top of the radiating cylinder, a radiating pipe is fixedly connected to the bottom of the radiating cylinder, one end of the radiating pipe is communicated with the bottom of the radiating cylinder, and a blowing hole is formed in the surface of the radiating pipe.

Further, the middle threads on two sides of the lower shell are provided with A threaded rods in a penetrating mode, the other ends of the A threaded rods are rotatably connected with clamping plates through A bearings, and the bottom inside the lower shell is fixedly connected with a screen plate.

Further, the four corners department of last casing bottom all fixedly connected with inserted block, the assembly groove has all been seted up to one side of inserted block, one side fixedly connected with compression spring of assembly groove inner wall, compression spring's the other end fixedly connected with is spacing turn round, the recess with the inserted block looks adaptation has all been seted up to the four corners department of casing upper surface, one side of recess has been seted up and has been spacing hole with spacing turn round looks adaptation.

Further, the two sides at the middle part of the upper surface of the upper shell are respectively provided with a B threaded rod in a penetrating way, and the bottoms of the two B threaded rods are rotatably connected with a pressing plate through a B bearing.

Further, an optical fiber transceiver connecting hole is formed in one side of the front face of the optical fiber transceiver body, and an indicator lamp is arranged in the middle of the front face of the optical fiber transceiver body.

The utility model provides a heat dissipation type optical fiber transceiver, which has the following beneficial effects:

Through buffer unit and radiator unit's setting, radiator fan starts during the use, radiator fan blows the cooling tube into later, then blows to the optical fiber transceiver body from the cooling tube from the mouth of blowing again, and then dispel the heat cooling to the heat that the optical fiber transceiver body produced to protect the optical fiber transceiver body, improve life, later when the optical fiber transceiver body accident drops, buffer board compression buffer spring, buffer spring and A blotter and B blotter cooperation are buffered the impact force to having prevented that the optical fiber transceiver from bumping and causing the damage.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It will be apparent to those skilled in the art from this disclosure that the drawings described below are merely exemplary and that other embodiments may be derived from the drawings provided without undue effort.

FIG. 1 is a schematic view of a three-dimensional splitting structure of the present utility model;

FIG. 2 is a schematic view of a three-dimensional structure of the present utility model;

FIG. 3 is a schematic view of a buffer assembly according to the present utility model;

fig. 4 is a schematic structural diagram of a heat dissipating assembly according to the present utility model.

The figures indicate:

1. An upper housing;

2. A lower housing;

3. An optical fiber transceiver body;

4. A buffer assembly; 401. a buffer plate; 402. a support column; 403. a, cushion pad; 404. a buffer spring; 405. a buffer pad B; 406. a support cylinder;

5. A heat dissipation assembly; 501. a heat dissipation cylinder; 502. a heat radiation fan; 503. a dust screen; 504. a heat radiating pipe;

6. a, a threaded rod;

7. A clamping plate;

8. B, a threaded rod;

9. a pressing plate;

10. inserting blocks;

11. a compression spring;

12. Limiting torsion;

13. An optical fiber transceiver connection hole;

14. an indicator light.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples are not representative of all implementations consistent with the present disclosure. Rather, they are merely examples of apparatus consistent with some aspects of the disclosure as detailed in the accompanying claims.

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. 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.

Example 1:

As shown in fig. 1, 2, 3 and 4, the present embodiment proposes a heat dissipation type optical fiber transceiver, which includes an upper housing 1, a lower housing 2 and an optical fiber transceiver body 3, wherein the surfaces of one side of the upper housing 1 and one side of the lower housing 2 are fixedly connected with a buffer component 4, and the middle of the surface of one side of the lower housing 2 is fixedly connected with a heat dissipation component 5;

The buffer component 4 includes buffer plate 401, the equal fixedly connected with support column 402 in four corners department of buffer plate 401 one side, the bottom fixedly connected with A blotter 403 of support column 402, the other end fixedly connected with buffer spring 404 of A blotter 403, buffer spring 404's the other end fixedly connected with B blotter 405, support tube 406 has been cup jointed on the surface of support column 402, the interior diapire of support tube 406 is connected with B blotter 405, through the setting of buffer component 4 and radiator component 5, radiator fan 502 starts during the use, radiator fan 502 blows the wind into in the cooling tube 504 afterwards, then blow to fiber transceiver body 3 from the cooling tube 504 from the mouth of blowing, and then carry out the heat dissipation cooling to fiber transceiver body 3 heat production, thereby protect fiber transceiver body 3, improve life, then when fiber transceiver body 3 accident drops, buffer plate 401 compresses buffer spring 404, buffer spring 404 and A blotter 403 and B blotter 405 cooperate and cushion the impact force, thereby damage has been prevented to the fiber transceiver from taking place the collision.

As shown in fig. 1, 2 and 4, the heat dissipation assembly 5 includes a heat dissipation barrel 501, a heat dissipation fan 502 is disposed in the heat dissipation barrel 501, a dust screen 503 is fixedly connected to the top of the heat dissipation barrel 501, a heat dissipation pipe 504 is fixedly connected to the bottom of the heat dissipation barrel 501, one end of the heat dissipation pipe 504 is communicated with the bottom of the heat dissipation barrel 501, a blowing hole is formed in the surface of the heat dissipation pipe 504, the heat dissipation fan 502 blows air into the heat dissipation pipe 504, and then the air is blown to the optical fiber transceiver body 3 through the blowing hole to dissipate heat emitted by the optical fiber transceiver body 3.

Example 2:

The scheme of example 1 is further described in conjunction with the specific operation described below:

As shown in fig. 1, the four corners of the bottom of the upper housing 1 are fixedly connected with an insert 10, one side of the insert 10 is provided with an assembly groove, one side of the inner wall of the assembly groove is fixedly connected with a compression spring 11, the other end of the compression spring 11 is fixedly connected with a limiting button 12, the four corners of the upper surface of the housing 2 are provided with grooves matched with the insert 10, one side of each groove is provided with a limiting hole matched with the limiting button 12, the limiting button 12 is pressed, the compression spring 11 is compressed by the limiting button 12, the insert 10 can be pulled out, and the upper housing 1 and the lower housing 2 are detached and installed.

As shown in fig. 1, the middle threads on two sides of the lower casing 2 are threaded with a threaded rod 6, the other end of the threaded rod 6 is rotatably connected with a clamping plate 7 through a bearing a, the bottom of the lower casing 2 is fixedly connected with a screen plate, the threaded rod 6 is rotated to drive the clamping plate 7 to move, and then the clamping plate 7 clamps two sides of the optical fiber transceiver body 3, so that the optical fiber transceiver body 3 is fixed.

As shown in fig. 2, an optical fiber transceiver connecting hole 13 is formed on one side of the front surface of the optical fiber transceiver body 3, and an indicator lamp 14 is arranged in the middle of the front surface of the optical fiber transceiver body 3.

As shown in fig. 1, two sides in the middle of the upper surface of the upper casing 1 are respectively provided with a B threaded rod 8, bottoms of the two B threaded rods 8 are rotatably connected with a pressing plate 9 through a B bearing, the B threaded rods 8 are rotated, then the B threaded rods 8 rotate to drive the pressing plate 9 to descend, then the pressing plate 9 is used for pressing the optical fiber transceiver body 3 downwards, and further the optical fiber transceiver body 3 is reinforced and fixed.

Example 3:

The schemes of examples 1 and 2 are further described below in conjunction with specific modes of operation, as described below:

Specifically, this heat dissipation formula optical fiber transceiver is during operation/during the use: firstly, the optical fiber transceiver body 3 is placed on a screen plate, then the A threaded rod 6 is rotated to drive the clamping plate 7 to move, then the clamping plate 7 clamps two sides of the optical fiber transceiver body 3, then the optical fiber transceiver body 3 is fixed, then the inserting block 10 is inserted into the groove, then the upper shell 1 and the lower shell 2 are combined, then the B threaded rod 8 is rotated to drive the pressing plate 9 to descend, then the pressing plate 9 is used for pressing the optical fiber transceiver body 3 downwards, further the optical fiber transceiver body 3 is fixed, then when the optical fiber transceiver body 3 is used, the heat dissipation fan 502 is started, then the heat dissipation fan 502 blows wind into the heat dissipation pipe 504, then the heat generated by the optical fiber transceiver body 3 is dissipated from the heat dissipation pipe 504 to the optical fiber transceiver body 3, then when the buffer plate 401 collides, the buffer plate 401 compresses the buffer spring 404, then the buffer spring 404 is matched with the A buffer pad 403 and the B buffer pad 405, and the impact force is buffered for protecting the optical fiber transceiver body 3.

The electrical components are all connected with an external main controller and 220V mains supply, the main controller can be conventional known equipment for controlling a computer and the like, detailed description of known functions and known components is omitted in the specific embodiment of the disclosure, and the adopted operation means are consistent with the parameters of the instruments on the market in order to ensure the compatibility of the equipment.

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 (6)

1. The utility model provides a heat dissipation formula optical fiber transceiver, includes casing (1), lower casing (2) and optical fiber transceiver body (3), its characterized in that: the surface of one side of the upper shell (1) and the surface of one side of the lower shell (2) are fixedly connected with a buffer assembly (4), and the middle part of the surface of one side of the lower shell (2) is fixedly connected with a heat dissipation assembly (5);

The buffer assembly (4) comprises a buffer plate (401), support columns (402) are fixedly connected to four corners of one side of the buffer plate (401), A buffer pads (403) are fixedly connected to the bottoms of the support columns (402), buffer springs (404) are fixedly connected to the other ends of the A buffer pads (403), B buffer pads (405) are fixedly connected to the other ends of the buffer springs (404), supporting cylinders (406) are sleeved on the surfaces of the support columns (402), and inner bottom walls of the supporting cylinders (406) are connected with the B buffer pads (405).

2. A heat-dissipating fiber optic transceiver as defined in claim 1, wherein: the heat dissipation assembly (5) comprises a heat dissipation barrel (501), a heat dissipation fan (502) is arranged in the heat dissipation barrel (501), a dust screen (503) is fixedly connected to the top of the heat dissipation barrel (501), a heat dissipation pipe (504) is fixedly connected to the bottom of the heat dissipation barrel (501), one end of the heat dissipation pipe (504) is communicated with the bottom of the heat dissipation barrel (501), and a blowing hole is formed in the surface of the heat dissipation pipe (504).

3. A heat-dissipating fiber optic transceiver as defined in claim 1, wherein: a threaded rod (6) is arranged in the middle of the two sides of the lower shell (2) in a threaded mode, the other end of the threaded rod (6) is rotatably connected with a clamping plate (7) through an installation A bearing, and the bottom of the inside of the lower shell (2) is fixedly connected with a screen plate.

4. A heat-dissipating fiber optic transceiver as defined in claim 1, wherein: the utility model discloses a plug-in type socket, including upper housing (1), plug-in type socket, fixed connection, recess, spacing hole with plug-in type socket (10) looks adaptation is all offered in the four corners department of upper housing (1), the mounting groove has all been offered to one side of plug-in type socket (10), one side fixedly connected with compression spring (11) of mounting groove inner wall, the other end fixedly connected with of compression spring (11) is spacing turn round (12), the recess with plug-in type socket (10) looks adaptation is all offered in the four corners department of casing (2) upper surface, spacing hole with spacing turn round (12) looks adaptation is offered to one side of recess.

5. A heat-dissipating fiber optic transceiver as defined in claim 1, wherein: b threaded rods (8) are respectively arranged on two sides of the middle of the upper surface of the upper shell (1) in a penetrating mode, and pressing plates (9) are connected to the bottoms of the two B threaded rods (8) in a rotating mode through B bearings.

6. A heat-dissipating fiber optic transceiver as defined in claim 1, wherein: an optical fiber transceiver connecting hole (13) is formed in one side of the front face of the optical fiber transceiver body (3), and an indicator lamp (14) is arranged in the middle of the front face of the optical fiber transceiver body (3).