CN215345667U - Power-saving control device for communication engineering - Google Patents

Abstract

A power-saving control device for communication engineering comprises components, a shell, a cover plate, a heat conducting plate and a fan, wherein a placing cavity and a heat dissipation cavity are arranged in the shell; the cover plate is detachably arranged on the shell and covers the placing cavity and the heat dissipation cavity, and an air inlet communicated with the heat dissipation cavity is formed in the cover plate; the heat conducting plate is arranged between the placing cavity and the heat radiating cavity to isolate the placing cavity from the heat radiating cavity, a heat absorbing strip extending into the placing cavity is arranged on one side of the heat conducting plate, and a heat conducting strip extending into the heat radiating cavity is arranged on the other side of the heat conducting plate; the fan is arranged on the cover plate and is correspondingly communicated with the air inlet; when the heat dissipation device is used, heat generated by the components is transferred into the placement cavity, the heat absorption strips on the heat conduction plate absorb the heat and conduct the heat to the heat conduction strips, and the fan is started to generate air flow to take the heat on the heat conduction strips out of the heat dissipation cavity from the air outlets; and because the heat-conducting plate keeps apart and places chamber and heat dissipation chamber, the dust can not get into and place the intracavity at the radiating in-process.

Description

Power-saving control device for communication engineering

Technical Field

The utility model relates to the technical field of communication engineering, in particular to a power-saving control device for communication engineering.

Background

Communication engineering is a basic subject of electronic engineering, and the subject focuses on the principle and application of information transmission and signal processing in the communication process, and various components are generally installed in communication equipment for conveniently processing signal information, and the components can generate heat when working to cause electric energy damage; in order to reduce the power consumption of components, power saving control devices are generally used in the prior art.

The existing power-saving control device for communication engineering generally adopts a single radiating hole to radiate heat, and has the following problems in the actual use process:

firstly, heat is dispersed only by means of heat dissipation holes, and the heat dissipation effect is poor;

secondly, do not possess dustproof performance, the dust in the outside air gets into equipment inside and is infected with and on the components and parts through the louvre easily, reduces the life of components and parts.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

The utility model provides a power-saving control device for communication engineering, which solves the problems in the background technology.

(II) technical scheme

In order to achieve the purpose, the utility model provides the following technical scheme:

an electricity-saving control device for communication engineering comprises components, a shell, a cover plate, a heat conducting plate and a fan, wherein a placing cavity with an outward opening and a heat dissipation cavity with an outward opening are arranged in the shell; the cover plate is detachably arranged on the shell to cover the placing cavity and the heat dissipation cavity, and an air inlet communicated with the heat dissipation cavity is formed in the cover plate; the heat conducting plate is arranged between the placing cavity and the heat radiating cavity to isolate the placing cavity from the heat radiating cavity, a heat absorbing strip extending into the placing cavity is arranged on one side of the heat conducting plate, and a heat conducting strip extending into the heat radiating cavity is arranged on the other side of the heat conducting plate; the fan is installed on the cover plate and is correspondingly communicated with the air inlet.

Preferably, a placing opening communicated with the heat dissipation cavity is formed in the side wall of the placing cavity, and clamping grooves with upward openings are formed in two sides of the placing opening respectively; the both ends of heat-conducting plate are equipped with the fixture block respectively, the fixture block with draw-in groove slidable ground cooperation, so that the heat-conducting plate detachably install place in the mouth, and keep apart place the chamber with the heat dissipation chamber.

Preferably, the component comprises a control board and a heat sink, the control board is mounted in the placing cavity, the heat sink is mounted on the control board, and the heat absorbing strip on the heat conducting plate is in contact with the heat sink.

Preferably, the heat dissipation device further comprises a brush plate and a driving mechanism, wherein bristles are arranged on the periphery of the brush plate, and the brush plate is movably arranged in the heat dissipation cavity so that the bristles can be in contact with the side wall of the heat dissipation cavity and the heat conduction strip on the heat conduction plate; the driving mechanism is installed on the shell and is in driving connection with the brush plate.

Preferably, a sliding rod is arranged in the heat dissipation cavity, a sliding hole is formed in the brush plate, and the sliding hole is in sliding connection with the sliding rod, so that the brush plate can be movably installed in the heat dissipation cavity.

Preferably, the driving mechanism comprises a motor and a screw rod, the screw rod is rotatably arranged in the heat dissipation cavity and is parallel to the slide rod, and a screw hole in threaded connection with the screw rod is formed in the brush plate; the motor is installed on the shell and is in driving connection with the screw rod so as to drive the screw rod to rotate.

Preferably, the heat conducting plate, the heat absorbing strips and the heat conducting strips are integrally formed, and the heat conducting plate, the heat absorbing strips and the heat conducting strips are all made of aluminum materials.

(III) advantageous effects

The utility model provides an electricity-saving control device for communication engineering, which is characterized in that a heat-conducting plate is designed to isolate a placing cavity and a heat dissipation cavity so as to prevent external dust from entering the placing cavity to contaminate components; the heat absorbing strips and the heat conducting strips on the heat conducting plate are designed to absorb heat generated by the components and transfer the heat to the heat dissipation cavity, and finally, the heat in the heat dissipation cavity is discharged outside by the design of the fan; therefore, the device has good heat dissipation effect and dustproof performance, saves energy and prolongs the service life of components.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the principles of the utility model without limiting the utility model in which:

FIG. 1 shows a schematic of the overall structure of the present invention;

FIG. 2 shows a top view of FIG. 1;

FIG. 3 shows a cross-sectional view A-A of FIG. 2;

FIG. 4 shows a cross-sectional view B-B of FIG. 2;

FIG. 5 shows an exploded schematic view of the overall structure of the present invention;

FIG. 6 shows an enlarged view at A in FIG. 5;

FIG. 7 shows a partial block diagram of the present invention;

FIG. 8 shows a second partial structural diagram of the present invention;

fig. 9 shows a schematic view of the structure of the heat-conducting plate of the utility model;

fig. 10 shows a schematic view of the construction of a brush plate according to the utility model.

In the figure: the device comprises a component 1, a heat radiating fin 11, a control panel 12, a shell 2, a placement cavity 21, a placement opening 210, a clamping groove 210k, a heat radiating cavity 22, an air outlet 22p, a slide rod 22h, a cover plate 3, an air inlet 3p, a heat conducting plate 4, a heat absorbing strip 41, a heat conducting strip 42, a clamping block 4k, a fan 5, a brush plate 6, bristles 60, screw holes 61, a slide hole 6h, a driving mechanism 7, a motor 71 and a screw rod 72.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-9, an electricity-saving control device for communication engineering comprises a component 1, a shell 2, a cover plate 3, a heat conducting plate 4 and a fan 5, wherein a placing cavity 21 with an outward opening and a heat dissipation cavity 22 with an outward opening are arranged in the shell 2, the component 1 is arranged in the placing cavity 21, and an air outlet 22p communicated with the heat dissipation cavity 22 is also arranged on the shell 2; the cover plate 3 is detachably arranged on the shell 2 to cover the placing cavity 21 and the heat dissipation cavity 22, and an air inlet 3p communicated with the heat dissipation cavity 22 is formed in the cover plate 3; the heat conducting plate 4 is arranged between the placing cavity 21 and the heat dissipation cavity 22 to isolate the placing cavity 21 and the heat dissipation cavity 22, a heat absorbing strip 41 extending into the placing cavity 21 is arranged on one side of the heat conducting plate 4, and a heat conducting strip 42 extending into the heat dissipation cavity 22 is arranged on the other side of the heat conducting plate 4; the fan 5 is installed on the cover plate 3 and correspondingly communicated with the air inlet 3 p.

When the heat dissipation device is used, heat generated by the component 1 is transferred into the placement cavity, and the heat absorption strips 41 on the heat conduction plate 4 absorb the heat in the heat dissipation cavity 22 and transfer the heat to the heat conduction strips 42; at this time, the fan 5 is started, the generated air flow enters the heat dissipation cavity 22 through the air inlet 3p, and the air flow entering the heat dissipation cavity 22 brings the heat on the heat conduction strip 42 out of the heat dissipation cavity 22 from the air outlet 22 p; in the process, because the heat conducting plate 4 separates the placing cavity 21 and the heat radiating cavity 22, dust cannot enter the placing cavity in the heat radiating process.

In the utility model, the cover plate 3 and the shell 2 are designed to be detachable, and are fixed to the shell 2 through bolts, so that a user can conveniently detach the cover plate 3 to clean dust in the heat dissipation cavity 22 and dust stained on the heat conduction strips 42.

In summary, the heat conducting plate 4 is designed to isolate the placing cavity 21 from the heat dissipation cavity 22, so as to prevent external dust from entering the placing cavity 21 and contaminating the component 1; the heat absorbing strips 41 and the heat conducting strips 42 on the heat conducting plate 4 are designed to absorb the heat generated by the component 1 and transfer the heat to the heat dissipation cavity 22, and finally the heat in the heat dissipation cavity 22 is discharged outside by the fan 5; therefore, the device has good heat dissipation effect and dustproof performance, saves energy and prolongs the service life of the component 1.

Referring to fig. 5-9, in order to facilitate the user to replace the heat conducting plate 4, a placing opening 210 communicating with the heat dissipating chamber 22 is formed on the sidewall of the placing chamber 21, and two sides of the placing opening 210 are respectively provided with a slot 210k with an upward opening; two ends of the heat conducting plate 4 are respectively provided with a fixture block 4k, and the fixture block 4k is slidably matched with the clamping groove 210k, so that the heat conducting plate 4 is detachably installed in the placing opening 210 and separates the placing cavity 21 and the heat dissipation cavity 22.

Specifically, after the cover plate 3 is opened by the user, the heat-conducting plate 4 is shifted upwards, so that the clamping block 4k is separated from the clamping groove 210k, and the heat-conducting plate 4 can be taken out.

Referring to fig. 4-8, the component 1 includes a control board 12 and a heat sink 11, the control board 12 is installed in the placing cavity 21, the heat sink 11 is installed on the control board 12, and the heat absorbing strips 41 on the heat conducting plate 4 are in contact with the heat sink 11; specifically, after the components on the control board 12 generate heat, the heat sink 11 mounted on the control board 12 absorbs the heat, and then the heat is directly absorbed by the heat absorbing strips 41 on the heat conducting plate 4 and transferred to the heat conducting strips 42; the contact design of the heat sink 11 and the heat sink strip 41 can transfer the heat generated by the component 1 to the heat conducting strip 42 disposed in the heat dissipation cavity 22 more quickly.

Referring to fig. 3-8, in view of the trouble of removing the dust in the heat dissipation chamber 22 by detaching the cover plate 3, the present invention further comprises a brush plate 6 and a driving mechanism 7, wherein the brush plate 6 is provided with bristles 60 on the periphery, and the brush plate 6 is movably mounted in the heat dissipation chamber 22, so that the bristles 60 can contact with the side wall of the heat dissipation chamber 22 and the heat conduction strips 42 on the heat conduction plate 4; the drive mechanism 7 is mounted on the housing 2 and is in driving connection with the brush plate 6.

When the heat dissipation cavity 22 needs to be cleaned, the driving mechanism 7 is started to drive the brush plate 6 to move in the heat dissipation cavity 22, so that the bristles 60 brush the inner wall of the heat dissipation cavity 22 and the heat conducting strip 42, and the brushed dust falls out of the outside through the air outlet 22 p.

Referring to fig. 7-10, a sliding rod 22h is disposed in the heat dissipation chamber 22, a sliding hole 6h is disposed on the brush plate 6, and the sliding hole 6h is slidably connected to the sliding rod 22h, so that the brush plate 6 is movably mounted in the heat dissipation chamber 22; and the sliding rod 22h and the sliding hole 6h are matched, so that the moving stability of the brush plate 6 can be effectively improved.

Referring to fig. 7-10, the driving mechanism 7 of the present invention includes a motor 71 and a screw 72, the screw 72 is rotatably installed in the heat dissipation chamber 22 and is parallel to the sliding rod 22h, and the brush plate 6 is provided with a screw hole 61 in threaded connection with the screw 72; the motor 71 is mounted on the housing 2 and drivingly connected to the screw 72, and when the motor 71 is started to drive the screw 72 to rotate, the brush plate 6 can move back and forth along the length direction of the sliding rod 22h, so that the bristles 60 brush the inner wall of the heat dissipation chamber 22 and the heat conduction strip 42.

It should be noted that the driving mechanism 7 in the present invention may also be an electric cylinder, and the telescopic end of the electric cylinder is fixed to the brush plate 6, and can also control the brush plate 6 to move along the direction of the penetration of the sliding rod 22 h.

Referring to fig. 9, the heat conducting plate 4, the heat absorbing strips 41 and the heat conducting strips 42 are integrally formed, and the heat conducting plate 4, the heat absorbing strips 41 and the heat conducting strips 42 are made of aluminum materials; wherein, heat-conducting plate 4, heat absorption strip 41 and heat conduction strip 42 integrated into one piece, convenient integrative dismantlement and installation, and the aluminium material possesses good heat conductivility, has the heat of quick transmission, and aluminium material low price, and manufacturing cost is lower.

It should also be noted that while embodiments of the present application have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the application.

Claims (7)

1. The utility model provides a communication engineering uses economize on electricity controlling means, includes components and parts (1), its characterized in that still includes:

the device comprises a shell (2), wherein a placing cavity (21) with an outward opening and a heat dissipation cavity (22) with an outward opening are formed in the shell (2), the component (1) is installed in the placing cavity (21), and an air outlet (22p) communicated with the heat dissipation cavity (22) is formed in the shell (2);

the cover plate (3) is detachably arranged on the shell (2) to cover the placing cavity (21) and the heat dissipation cavity (22), and an air inlet (3p) communicated with the heat dissipation cavity (22) is formed in the cover plate (3);

the heat conducting plate (4), the heat conducting plate (4) is installed between the placing cavity (21) and the heat dissipation cavity (22) to isolate the placing cavity (21) and the heat dissipation cavity (22), a heat absorbing strip (41) extending into the placing cavity (21) is arranged on one side of the heat conducting plate (4), and a heat conducting strip (42) extending into the heat dissipation cavity (22) is arranged on the other side of the heat conducting plate (4);

the fan (5) is installed on the cover plate (3) and is correspondingly communicated with the air inlet (3 p).

2. The power-saving control device for communication engineering according to claim 1, wherein a placing opening (210) for connecting the heat dissipation cavity (22) is arranged on the side wall of the placing cavity (21), and two sides of the placing opening (210) are respectively provided with a clamping groove (210k) with an upward opening; the both ends of heat-conducting plate (4) are equipped with fixture block (4k) respectively, fixture block (4k) with draw-in groove (210k) slidable ground cooperation, so that heat-conducting plate (4) detachably install place in mouthful (210), and keep apart place chamber (21) with heat dissipation chamber (22).

3. The power saving control device for communication engineering according to claim 2, wherein the component (1) comprises a control board (12) and a heat sink (11), the control board (12) is installed in the placing cavity (21), the heat sink (11) is installed on the control board (12), and the heat sink strip (41) on the heat conducting plate (4) is in contact with the heat sink (11).

4. The electricity-saving control device for communication engineering according to claim 1, characterized by further comprising a brush plate (6) and a driving mechanism (7), wherein bristles (60) are arranged on the periphery of the brush plate (6), and the brush plate (6) is movably mounted in the heat dissipation cavity (22) so that the bristles (60) can contact with the side wall of the heat dissipation cavity (22) and the heat conduction strips (42) on the heat conduction plate (4); the driving mechanism (7) is installed on the shell (2) and is in driving connection with the brush plate (6).

5. The power saving control device for communication engineering according to claim 4, wherein a sliding rod (22h) is arranged in the heat dissipation cavity (22), a sliding hole (6h) is arranged on the brush board (6), and the sliding hole (6h) is slidably connected with the sliding rod (22h) so that the brush board (6) can be movably installed in the heat dissipation cavity (22).

6. The electricity-saving control device for communication engineering according to claim 5, characterized in that the driving mechanism (7) comprises a motor (71) and a screw (72), the screw (72) is rotatably installed in the heat dissipation chamber (22) and is parallel to the sliding rod (22h), the brush plate (6) is provided with a screw hole (61) in threaded connection with the screw (72); the motor (71) is arranged on the shell (2) and is in driving connection with the screw rod (72) so as to drive the screw rod (72) to rotate.

7. The power saving control device for communication engineering as claimed in claim 1, wherein the heat conducting plate (4), the heat absorbing strips (41) and the heat conducting strips (42) are integrally formed, and the heat conducting plate (4), the heat absorbing strips (41) and the heat conducting strips (42) are made of aluminum material.

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