CN107683073B - Communication equipment supporting structure based on heat dissipation mechanism - Google Patents

Abstract

The invention discloses a communication equipment supporting structure based on a heat dissipation mechanism, which comprises a bottom plate, wherein a supporting frame is fixed on the bottom plate, a placing platform and a heat dissipation fan table are arranged on the supporting frame, a heat dissipation device is placed on the heat dissipation fan table, the heat dissipation device comprises a shell with an upward opening, the opening is opposite to a ventilation opening, a supporting column is arranged below the shell and fixed on the heat dissipation fan table, a heat dissipation fan is arranged at the bottom of the shell, a guide rail is arranged on the inner wall of the shell, the movable plate is fixedly provided with a sliding block, an operating rod is fixed on the side surface of the movable plate and movably penetrates through the side surface of the shell to the outside of the shell, a rotating plate is hinged to the lower surface of the movable plate, a long strip-shaped placing. The heat dissipation device can simply, flexibly and quickly change the width of the air channel so as to change the air speed passing through the air channel, and can change the position of the air outlet so as to cool the local position.

Description

Communication equipment supporting structure based on heat dissipation mechanism

Technical Field

the invention relates to the field of communication device auxiliary equipment, in particular to a communication equipment supporting structure based on a heat dissipation mechanism.

Background

In the present home or office, a router is an indispensable communication device, and the router is usually arranged on a special router support.

When the router is started for a long time in the using process, the working temperature of the router can be increased when the environmental temperature is high, or after the router is used for a long time, or when the router is in a local fault, the router needs to be radiated to reduce the working temperature to a proper temperature so as to ensure that electronic elements of the router operate at the proper temperature and prolong the service life of the router.

The heat dissipation device arranged on the existing router support mostly adopts a heat dissipation fan, and the heat on the surface of the router is transferred to the air by accelerating the air flow on the surface of the router, so that the working temperature of the router is reduced. However, the air channel of the traditional router heat dissipation fan cannot be changed, and the generated wind speed is constant under the condition that the rotating speed of the blades of the heat dissipation fan is inconvenient, so that the heat dissipation fan is not flexible to use and cannot cope with the condition that the wind speed needs to be increased; moreover, the direction of the flowing air generated by the heat dissipation fan is fixed, so that heat dissipation cannot be performed on a certain local position of the router, the heat dissipation efficiency is low, and the expected heat dissipation effect cannot be achieved.

Disclosure of Invention

The invention aims to provide a communication equipment supporting structure based on a heat dissipation mechanism, and aims to solve the problems that the wind speed is constant under the condition that the rotating speed of a radiating fan blade is not changed due to the fact that a radiating fan air channel arranged on a router support in the prior art cannot be changed, the direction of flowing air cannot be changed, the heat dissipation efficiency is low, and the operation is not flexible.

The invention is realized by the following technical scheme:

A communication equipment supporting structure based on a heat dissipation mechanism comprises a bottom plate, wherein a supporting frame is fixed on the bottom plate, a placing platform is fixed at the top end of the supporting frame, a plurality of ventilation openings are formed in the placing platform, a heat dissipation fan table positioned below the placing platform is further installed on the supporting frame, a heat dissipation device is placed on the heat dissipation fan table and comprises a shell with an upward opening, the opening is opposite to the ventilation openings, a supporting column is arranged below the shell and is fixed on the heat dissipation fan table, a heat dissipation fan is arranged at the bottom of the shell, an air outlet of the heat dissipation fan is positioned in the shell, guide rails are arranged on two parallel inner walls of the shell and are parallel to the horizontal plane, two parallel moving plates are further arranged above the heat dissipation fan, slide blocks are fixed at two ends of each moving plate and are matched with the guide rails, an operating rod is fixed on the side face of the moving plate, the operating rod movably penetrates through the side face of the shell to the outside of the shell, a rotating plate is hinged to the lower surface of the moving plate, a long-strip-shaped placing groove is formed in the inner wall of the shell, and the width of the placing groove is equal to the thickness of the rotating plate.

In the prior art, an air outlet of a heat dissipation fan arranged on a router support faces a router, and after the heat dissipation fan is started, the heat dissipation fan generates flowing air to dissipate heat of the router. However, the air duct of the radiator cannot be changed, and the heat dissipation fan is usually not provided with a rotation speed adjusting device, so that the air speed blown to the router by the heat dissipation fan is constant, and if the rotation speed adjusting device is installed, the rotation speed is increased to generate extra energy consumption; moreover, the direction of the flowing air generated by the heat dissipation fan is certain, that is, the flowing air is mainly concentrated at a certain fixed position of the heat dissipation fan, and the heat dissipation effect on other positions is poor, so that the wind power is still weak when other positions need to be cooled, the heat dissipation efficiency is low, and the expected heat dissipation effect cannot be achieved.

In order to solve the problems, the invention provides a router support with a heat dissipation device capable of changing an air channel, which comprises a bottom plate, wherein a support frame is fixed on the bottom plate, a placing platform is fixed at the top end of the support frame and used for placing a router, a plurality of ventilation openings are formed in the placing platform, the router is placed above the ventilation openings, a heat dissipation fan table is further installed on the support and used for fixing the heat dissipation device, the heat dissipation fan is installed at the bottom of a shell with an upward opening through the heat dissipation device, and an air outlet of the heat dissipation fan is located in the shell, so that air blown out from the heat dissipation fan can be blown out from the opening in the top of the heat dissipation fan and finally blown to the router placed on the placing platform through the ventilation openings.

The heat dissipation fan comprises a shell, a heat dissipation fan and a heat dissipation fan, wherein two parallel inner walls of the shell are provided with guide rails, the guide rails are parallel to the horizontal plane, preferably, the two guide rails are located at the same height, the heat dissipation fan further comprises two parallel moving plates, the moving plates are located above the heat dissipation fan, preferably, the upper surfaces of the moving plates and the upper surface of the shell are located at the same horizontal plane, sliding blocks are fixedly installed at two ends of the moving plates, namely two faces, facing the inner wall, provided with the guide rails, of the shell, the sliding blocks can be fixed in a non-detachable mode such as welding and bonding or in a detachable mode such as threaded connection and clamping. The size of slider and guide rail phase-match, the slider can block on the guide rail and move along the guide rail, and the block of slider and guide rail and the slider are linear guide's prior art on the guide rail is fixed. The two moving plates can slide along the guide rail through the guide rail and the slide block. The side surfaces of the moving plates are fixedly provided with operating rods, the operating rods movably penetrate through the side surfaces of the shell to the outside of the shell, each moving plate is provided with six surfaces, two side surfaces, two end surfaces, an upper surface and a lower surface, the side surfaces are the surfaces of the moving plates facing the inner wall of the shell which is not provided with the guide rail, and the moving plates can move towards the inner wall or the other moving plate along the guide rail by pushing or pulling the operating rods. The bottom of the movable plate is hinged with a rotating plate, namely one end of the rotating plate is hinged on the movable plate, and the other end, namely the movable end, of the rotating plate is in contact with the bottom of the shell, so that the rotating plate is obliquely arranged between the movable plate and the bottom surface of the shell, and the oblique angle is changed along with the movement of the movable plate. The hinge structure can be adopted as the specific hinge mode, a pin hole or a bearing can be arranged at the bottom of the movable plate, a pin shaft is arranged at one end of the rotating plate, the rotating plate can rotate around the hinged end, and the central axis of the pin shaft is perpendicular to the inner wall, provided with the guide rail, of the shell. Preferably, the hinged end of the rotating plate is adjacent to the side of the moving plate facing the other moving plate. The rotating plate enables only one air duct of the heat dissipation fan, namely, the flowing air generated by the heat dissipation fan can only pass through the space between the two moving plates, so that the air duct is divided into two parts along the longitudinal direction, namely an accelerating section with the cross section gradually reduced by taking the rotating plate as the side surface and a straight section with the cross section unchanged between the two moving plates. The acceleration section reduces local eddy generated by the flowing air on the flat bottom surface of the moving plate, and can uniformly increase the wind speed. Therefore, the output of flowing air can be more concentrated by the arrangement of the rotating plates, the cross-sectional area of the air channel can be reduced by changing the distance between the two movable plates, the air outlet volume of the heat dissipation fan is constant, so that the air speed passing through the air channel is increased along with the reduction of the cross-sectional area of the air channel, meanwhile, the positions of the air outlets can be changed by changing the positions of the two movable plates, and any part of the bottom of the router can be effectively cooled. The inner wall of the shell is provided with a long-strip-shaped placing groove, and the width of the placing groove is equal to the thickness of the rotating plate. Because the length of the rotating plate is longer than that of the bottom surface of the moving plate, the rotating plate placed on the bottom surface of the shell can cause that the moving plate can not be close to the inner wall of the shell, namely, the changeable range of the air duct width between the moving plates is reduced. In order to solve the problems, a long strip-shaped placing groove is formed in the inner wall of the shell and used for placing the rotating plate. During the use, place the rotor plate in the standing groove, along with the movable plate is close to each other, the expansion end of rotor plate finally follows landing to the casing bottom surface in the standing groove, forms the wind channel that the cross-sectional area reduces gradually, when needing to reset, rotates the rotor plate to be on a parallel with the horizontal plane, puts into the standing groove, can promote the movable plate to shells inner wall department.

In conclusion, the movable plate can move in the shell through the guide rail and the sliding block, the air channel is formed above the radiating fan by matching the rotating plate and the protective plate, and the width of the air channel is changed along with the mutual approaching or departing of the movable plate, so that the air speed through the air channel is changed, a user is allowed to flexibly control the air speed according to the actual condition, and the power consumption is reduced compared with the traditional method for adjusting the rotating speed of the blades; meanwhile, the position of the air outlet between the moving plates can also be changed, so that the concentrated heat dissipation of a certain local position at the bottom of the router is realized, the heat dissipation efficiency is improved, and the expected heat dissipation effect is achieved.

furthermore, a wiring rack is further arranged on the bottom plate, and a plurality of network cable claws are arranged on the wiring rack. The purpose of the cabling rack and the network cable claw is to collect and arrange the network cables extending from the placing platform, and the situation that a user cannot identify the required network cables due to the fact that a plurality of network cables are mutually tangled is avoided. The arrangement of the wire claws may be various, for example, a plurality of wire claws may be arranged on the same horizontal plane of the chute, or a plurality of wire claws may be arranged in the height direction of the chute.

As an optimal structure of the mesh wire claw, the mesh wire claw comprises a fixing frame fixed on a wiring frame, a fixing claw assembly is fixedly mounted on the fixing frame and comprises a metal claw, the metal claw is fixed on the fixing frame, the cross section of the metal claw is in a semicircular ring shape, a rubber claw is connected onto the metal claw, the cross section of the fixing claw assembly is in a circular ring shape with a notch, the central angle of the notch is 10-30 degrees, and the rubber claw is made of silicon rubber. Through the structure, when a user puts the net wire into the fixed claw assembly of the net wire claw, the user can directly press the net wire into the circular ring of the fixed claw assembly from the notch with force, the rubber claw can deform when the net wire is put into the fixed claw assembly, abrasion to the surface of the net wire cannot be caused, and meanwhile, after the net wire is put into the fixed claw assembly, the rubber claw can reset and the net wire is placed to fall off from the notch. The mechanism is simple in structure and convenient to install, and meanwhile, the net cables can be firmly grabbed and prevented from being separated from the notches.

Further, a handle is arranged at one end of the operating rod, which is positioned outside the shell. The handle is convenient for a user to control the operating rod so as to push and pull the moving plate.

Compared with the prior art, the invention has the following advantages and beneficial effects:

1. According to the invention, the movable plate can move in the shell through the guide rail and the slide block, the air channel is formed above the heat dissipation fan by matching with the rotating plate and the protective plate, and the width of the air channel is changed along with the mutual approaching or departing of the movable plate, so that the air speed through the air channel is changed, a user is allowed to flexibly control the air speed according to the actual condition, and the power consumption is reduced compared with the traditional method for adjusting the rotating speed of the blades; meanwhile, the position of the air outlet between the movable plates can be changed, so that the concentrated heat dissipation of a certain local position at the bottom of the router is realized, the heat dissipation efficiency is improved, and the expected heat dissipation effect is achieved;

2. According to the invention, by improving the structure of the net wire claw, a user can conveniently place the net wire into the net wire claw, and the net wire claw can firmly grasp the net wire to prevent the net wire from being separated from the notch;

3. The rotating plate of the invention can eliminate local eddy formed by the flowing air on the flat bottom surface of the moving plate.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principles of the invention. In the drawings:

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

FIG. 2 is a schematic structural diagram of a heat dissipation device according to the present invention;

FIG. 3 is a top view of the heat dissipation device of the present invention;

fig. 4 is a top view of the wire claw of the present invention.

Reference numbers and corresponding part names in the drawings:

1-bottom plate, 2-support frame, 3-wiring frame, 4-heat dissipation fan table, 5-placing platform, 6-network cable claw, 60-fixing frame, 61-metal claw, 62-rubber claw, 7-support column, 8-shell, 9-moving plate, 10-operating rod, 11-rotating plate, 12-heat dissipation fan, 13-protection plate, 14-guide rail and 15-sliding block.

Detailed Description

in order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to examples and accompanying drawings, and the exemplary embodiments and descriptions thereof are only used for explaining the present invention and are not meant to limit the present invention.

Example 1:

The communication equipment supporting structure based on the heat dissipation mechanism as shown in fig. 1 to 4 comprises a bottom plate 1, wherein a supporting frame 2 is fixed on the bottom plate 1, a placing platform 5 is fixed at the top end of the supporting frame 2, a plurality of ventilation openings are formed in the placing platform 5, a heat dissipation fan table 4 positioned below the placing platform 5 is further installed on the supporting frame 2, a heat dissipation device is placed on the heat dissipation fan table 4 and comprises a shell 8 with an upward opening, the opening is just opposite to the ventilation openings, a supporting column 7 is arranged below the shell 8, the supporting column 7 is fixed on the heat dissipation fan table 4, a heat dissipation fan 12 is arranged at the bottom of the shell 8, an air outlet of the heat dissipation fan 12 is positioned inside the shell 8, guide rails 14 are arranged on two parallel inner walls of the shell 8, the guide rails 14 are parallel to a horizontal plane, and further comprise two parallel moving plates 9, the, the two ends of the moving plate 9 are both fixed with sliding blocks 15, the sliding blocks 15 are matched with the guide rails 14, the side surface of the moving plate 9 is fixed with an operating rod 10, the operating rod 10 movably penetrates through the side surface of the shell 8 to the outside of the shell 8, the lower surface of the moving plate 9 is hinged with a rotating plate 11, the inner wall of the shell 8 is provided with a long strip-shaped placing groove, and the width of the placing groove is equal to the thickness of the rotating plate 11; the bottom plate 1 is also provided with a wiring rack 3, and a plurality of network cable claws 6 are arranged on the wiring rack 3; the network cable claw 6 comprises a fixed frame 60 fixed on the cabling rack 3, and a fixed claw component is fixedly arranged on the fixed frame 60; the fixing claw assembly comprises a metal claw 61, the metal claw 61 is fixed on the fixing frame 60, the cross section of the metal claw 61 is semicircular, the metal claw 61 is connected with a rubber claw 62, and the cross section of the fixing claw assembly is in a circular ring shape with a gap; the central angle of the notch is 10-30 degrees; the rubber claws 62 are made of silicon rubber; a handle is provided on the end of the operating lever 10 outside the housing 8.

When in use, the router is firstly placed on the placing platform 5 and is aligned with the ventilation opening; then, the network cable connected with the router is pressed into the metal claw 61 through the rubber claw 62 to be fixed, so that the purpose of arranging and collecting the network cable is achieved.

When the router works for a long time and is hot, the handle is pushed according to the specific part to be radiated, so that the operating rod 10 is driven, the moving plate 9 moves along the guide rail 14, and the air outlet position is adjusted; and then further fine tuned to adjust the width between the moving plates 9 to change the width of the duct and increase or decrease the velocity of the flowing air through the duct.

or the moving plate 9 can be pushed to the limit position at first, so that the movable end of the rotating plate 11 is positioned on the bottom surface of the shell 8, then the width of the air duct and the position of the air outlet are adjusted, the air duct is longitudinally divided into an accelerating section and a flat section, and the air vortex generated at the flat bottom surface of the moving plate 9 is eliminated.

The heat dissipation device of the invention enables the movable plate 9 to move in the shell through the guide rail 14 and the slide block 15, and the rotating plate 11 and the protective plate 13 are matched to form an air channel above the heat dissipation fan 12, and the width of the air channel is changed along with the mutual approaching or departing of the movable plate 9, so that the air speed passing through the air channel is changed, a user is allowed to flexibly control the air speed according to the actual condition, and compared with the traditional method for adjusting the rotating speed of the blades, the power consumption is reduced; meanwhile, the position of the air outlet between the moving plates 9 can also be changed, so that the concentrated heat dissipation of a certain local position at the bottom of the router is realized, the heat dissipation efficiency is improved, and the expected heat dissipation effect is achieved.

the above-mentioned embodiments are intended to illustrate the objects, technical solutions and advantages of the present invention in further detail, and it should be understood that the above-mentioned embodiments are merely exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (6)

1. Communication equipment supporting structure based on heat dissipation mechanism, including bottom plate (1), be fixed with support frame (2) on bottom plate (1), support frame (2) top is fixed with place the platform (5), be provided with a plurality of vents on place the platform (5), still install heat dissipation fan platform (4) that are located place the platform (5) below on support frame (2), heat abstractor has been placed on heat dissipation fan platform (4), its characterized in that, heat abstractor includes upwards open-ended casing (8), the opening is just to the vent, casing (8) below is provided with support column (7), support column (7) are fixed on heat dissipation fan platform (4), and casing (8) bottom is provided with heat dissipation fan (12), the air outlet of heat dissipation fan (12) is located inside casing (8), all is provided with guide rail (14) on two inner walls that are parallel to each other of casing (8), the heat dissipation fan is characterized in that the two guide rails (14) are located at the same height, the guide rails (14) are parallel to the horizontal plane, the heat dissipation fan further comprises two parallel moving plates (9), the moving plates (9) are located above the heat dissipation fan (12), sliding blocks (15) are fixed at two ends of each moving plate (9), the sliding blocks (15) are matched with the guide rails (14), an operating rod (10) is fixed on the side face of each moving plate (9), the operating rod (10) movably penetrates through the side face of the shell (8) to the outside of the shell (8), a rotating plate (11) is hinged to the lower surface of each moving plate (9), a long strip-shaped placing groove is formed in the inner wall of the shell (8), and the width of the placing groove is equal to the thickness; and a handle is arranged at one end of the operating rod (10) positioned outside the shell (8).

2. the heat dissipation mechanism-based communication device support structure of claim 1, wherein a rack (3) is further disposed on the base plate (1), and a plurality of wire claws (6) are disposed on the rack (3).

3. The communication equipment supporting structure based on the heat dissipation mechanism is characterized in that the network cable claw (6) comprises a fixed frame (60) fixed on the cabling rack (3), and a fixed claw component is fixedly arranged on the fixed frame (60).

4. The communication equipment supporting structure based on the heat dissipation mechanism is characterized in that the fixing claw assembly comprises a metal claw (61), the metal claw (61) is fixed on a fixing frame (60), the cross section of the metal claw (61) is in a semi-circular ring shape, a rubber claw (62) is connected onto the metal claw (61), and the cross section of the fixing claw assembly is in a circular ring shape with a gap.

5. The heat dissipation mechanism-based communication device support structure of claim 4, wherein the notch has a central angle of 10-30 °.

6. The heat dissipation mechanism-based communication device support structure of claim 4 or 5, wherein the material of the rubber claws (62) is silicone rubber.