CN216253684U - Optical communication device - Google Patents

Abstract

The utility model provides an optical communication device, which comprises a communication device body, wherein a heat dissipation panel is arranged on one side of the communication device body, a plurality of heat dissipation holes are formed in the heat dissipation panel, a first sliding groove is formed above the heat dissipation panel, a movable heat dissipation assembly is arranged in the first sliding groove, and the movable heat dissipation assembly is connected with the plurality of heat dissipation holes in a sliding manner; the communication device is characterized in that a rectangular through hole is formed in the upper portion of the communication device body, a supporting plate is embedded in the rectangular through hole, and a second heat dissipation assembly is detachably connected to the supporting plate. According to the utility model, the movable heat dissipation assembly is arranged, the movable heat dissipation assembly can be used for selective installation and position adjustment type heat dissipation, and meanwhile, the second heat dissipation assembly is used for reinforcing heat dissipation.

Description

Optical communication device

Technical Field

The utility model relates to the technical field of optical communication devices, in particular to an optical communication device.

Background

Optical communication is a communication mode using light waves as carriers, and there are two methods for increasing the bandwidth of an optical path: firstly, the single channel transmission rate of the optical fiber is improved; and the other is to increase the number of wavelengths transmitted in a single optical fiber, namely, the wavelength division multiplexing technology.

The existing optical communication device is provided with a plurality of heat dissipation holes on one side of the device, and the heat dissipation holes are used for realizing the exchange of internal and external air flows of the communication device so as to achieve the effect of cooling.

However, because the whole comparatively long of communication device, its rear end is mostly the interface to the thermovent is mostly the setting in both sides, thereby the single technical problem that utilizes the thermovent to cool down the effect relatively poor.

SUMMERY OF THE UTILITY MODEL

The present invention provides an optical communication device for solving the above-mentioned problems, and aims to solve the technical problem in the prior art that the communication device is long in its entirety and the rear end is mostly an interface, so that the heat dissipation ports are mostly arranged on both sides, and the cooling effect is poor by using the heat dissipation holes singly.

In order to achieve the purpose, the utility model provides the following technical scheme: an optical communication device comprises a communication device body, wherein a heat dissipation panel is arranged on one side of the communication device body, a plurality of heat dissipation holes are formed in the heat dissipation panel, a first sliding groove is formed above the heat dissipation panel, a movable heat dissipation assembly is arranged in the first sliding groove, and the movable heat dissipation assembly is connected with the plurality of heat dissipation holes in a sliding mode;

the communication device is characterized in that a rectangular through hole is formed in the upper portion of the communication device body, a supporting plate is embedded in the rectangular through hole, and a second heat dissipation assembly is detachably connected to the supporting plate.

Further, portable radiator unit includes the L template, L template upper end below is equipped with spacing subassembly, spacing subassembly can dismantle connect in the first spout, L template one side symmetry is equipped with two first fans.

Further, spacing subassembly includes the slide, L template top is equipped with the second spout, slide sliding connection in the second spout, be equipped with first slide bar in the second spout, first slide bar runs through the slide, just be equipped with the spring on the first slide bar, the connection can be dismantled to the spring other end the slide, slide below one side is equipped with the limiting plate, be equipped with spacing in the first spout, limiting plate sliding connection in spacing below.

Furthermore, the second heat dissipation assembly comprises a first connecting plate, air inlet grooves and air exhaust grooves are formed in two sides of the first connecting plate, two third sliding grooves are symmetrically formed in the supporting plate, two second fans are arranged in the two third sliding grooves respectively, one side of each second fan is used for sucking air, the other side of each second fan is used for exhausting air, and the four second fans are correspondingly connected with the air inlet grooves and the air exhaust grooves.

Further, the air inlet groove and the inner opening of the air exhaust groove are connected with the honeycomb plate through bolts.

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

1. the utility model is provided with the heat dissipation panel on one side of the communication device body, the heat dissipation panel is provided with a plurality of heat dissipation holes, the heat dissipation inside the communication device body is realized by utilizing the plurality of heat dissipation holes, and the movable heat dissipation component is arranged on the heat dissipation surface and is used for continuously blowing in external air, thereby increasing the air heat exchange;

2. according to the utility model, the supporting plate is arranged above the communication device body, and the second heat dissipation assembly is arranged on the supporting plate, so that the second heat dissipation assembly is utilized to carry out corresponding secondary heat dissipation, and the integral heat dissipation effect is better.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural diagram of a mobile heat sink assembly according to the present invention;

fig. 3 is a schematic structural diagram of a second heat dissipation assembly according to the present invention.

In the figure: 1. a communication device body; 2. a heat dissipation panel; 21. heat dissipation holes; 22. a first chute; 3. a movable heat dissipation assembly; 31. an L-shaped plate; 32. a limiting component; 321. a slide plate; 322. a first slide bar; 323. a spring; 324. a limiting plate; 325. a limiting strip; 33. a first fan; 34. a second chute; 4. a support plate; 41. a third chute; 5. a second heat dissipation assembly; 51. a first connecting plate; 52. an air inlet groove; 53. an exhaust groove; 54. a second fan; 55. a honeycomb panel.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the utility model, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the utility model.

As shown in fig. 1-3, the present embodiment provides an optical communication device, including a communication device body 1, a heat dissipation panel 2 is disposed on one side of the communication device body 1, a plurality of heat dissipation holes 21 are disposed on the heat dissipation panel 2, a first sliding slot 22 is disposed above the heat dissipation panel 2, a movable heat dissipation assembly 3 is disposed in the first sliding slot 22, and the movable heat dissipation assembly 3 is slidably connected to the outer sides of the plurality of heat dissipation holes 21.

Preferably, a rectangular through hole is formed above the communication device body 1, a support plate 4 is embedded in the rectangular through hole, and the second heat dissipation assembly 5 is detachably connected to the support plate 4.

Preferably, as shown in fig. 2, the movable heat dissipation assembly 3 includes an L-shaped plate 31, a limiting assembly 32 is disposed below an upper end of the L-shaped plate 31, the limiting assembly 32 is detachably connected to the first sliding groove 22, and two first fans 33 are symmetrically disposed on one side of the L-shaped plate 31.

Spacing subassembly 32 includes slide 321, L template 31 top is equipped with second spout 34, slide 321 sliding connection in the second spout 34, be equipped with two first slide bars 322 in the second spout 34, two first slide bar 322 runs through slide 321, and two all be equipped with spring 323 on the first slide bar 322, the connection can be dismantled to the spring 323 other end slide 321, slide 321 below one side is equipped with limiting plate 324, be equipped with limiting strip 325 in the first spout 22, limiting plate 324 sliding connection in limiting strip 325 below, when not using, through promoting slide 321, the slide that corresponds is carried out on two first slide bars 322 to extrude spring 323, thereby limiting plate 324 shrink breaks away from limiting strip 325, and then can carry out the ascending pulling out of L template 31.

As shown in fig. 3, the second heat dissipation assembly 5 includes a first connection plate 51, an air inlet 52 and an air outlet 53 are disposed on two sides of the first connection plate 51, two third sliding slots 41 are symmetrically disposed on the support plate 4, two second fans 54 are disposed in the two third sliding slots 41, wherein two second fans 54 on one side draw air and two second fans 54 on the other side exhaust air, the four second fans 54 are correspondingly connected to the air inlet 52 and the air outlet 53, and inner openings of the air inlet 52 and the air outlet 53 are bolted to a honeycomb panel 55.

The operation principle is as follows: when the temperature needs to be reduced, firstly, a heat dissipation panel 2 is arranged on one side of a communication device body 1, a plurality of heat dissipation holes 21 are formed in the heat dissipation panel 2, and the plurality of heat dissipation holes 21 are utilized for carrying out corresponding heat dissipation;

meanwhile, four fans in the second heat dissipation assembly 5 correspondingly rotate, so that external air is introduced while air is absorbed at the other side, and heat exchange is realized;

when the temperature is higher, the L-shaped plate 31 is pushed manually by a person to adjust the position, and then the two first fans 33 are electrified, so that the two first fans 33 on the L-shaped plate 31 rotate to introduce outside air;

when not in use, the corresponding sliding plate 321 slides correspondingly on the two first sliding rods 322 by pushing the sliding plate 321, and presses the spring 323, so that the limiting plate 324 contracts and disengages from the limiting strip 325, and the L-shaped plate 31 can be pulled out upwards.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments 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. An optical communication device comprising a communication device body (1), characterized in that: a heat dissipation panel (2) is arranged on one side of the communication device body (1), a plurality of heat dissipation holes (21) are formed in the heat dissipation panel (2), a first sliding groove (22) is formed above the heat dissipation panel (2), a movable heat dissipation assembly (3) is arranged in the first sliding groove (22) in a sliding mode, and the movable heat dissipation assembly (3) is connected with the plurality of heat dissipation holes (21) in a sliding mode;

the communication device is characterized in that a rectangular through hole is formed in the upper portion of the communication device body (1), a supporting plate (4) is embedded in the rectangular through hole, and a second heat dissipation assembly (5) is detachably connected to the supporting plate (4).

2. An optical communication device according to claim 1, wherein: portable radiator unit (3) include L template (31), spacing subassembly (32), first fan (33), L template (31) upper end is equipped with spacing subassembly (32), spacing subassembly (32) can dismantle connect in first spout (22), it is equipped with two first fan (33) still to symmetry on L template (31).

3. An optical communication device according to claim 2, wherein: spacing subassembly (32) includes slide (321), L template (31) top is equipped with second spout (34), slide (321) sliding connection is in second spout (34), be equipped with first slide bar (322) in second spout (34), first slide bar (322) run through slide (321), just be equipped with spring (323) on first slide bar (322), the connection can be dismantled to spring (323) other end slide (321), slide (321) below one side is equipped with limiting plate (324), be equipped with limiting strip (325) in first spout (22), limiting plate (324) sliding connection in limiting strip (325) below.

4. An optical communication device according to claim 1, wherein: the second heat dissipation assembly (5) comprises a first connecting plate (51), and an air inlet groove (52) and an air outlet groove (53) are formed in two sides of the first connecting plate (51).

5. An optical communication device according to claim 4, wherein: two third sliding grooves (41) are symmetrically formed in the supporting plate (4), two second fans (54) are arranged in the two third sliding grooves (41) respectively, air suction is performed on the two second fans (54), air exhaust is performed on the two second fans (54) on the other side, and the four second fans (54) are correspondingly connected with the air inlet groove (52) and the air exhaust groove (53).

6. An optical communication device according to claim 4, wherein: the inlet duct (52) and the outlet duct (53) are bolted to a honeycomb panel (55).

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