CN115361826A

CN115361826A - High-efficient dustproof heat abstractor of distributed energy router

Info

Publication number: CN115361826A
Application number: CN202210997913.XA
Authority: CN
Inventors: 杨军亭; 范迪龙; 梁琛; 康晓华; 马喜平; 钱康; 马振祺; 张家午
Original assignee: STATE GRID GASU ELECTRIC POWER RESEARCH INSTITUTE; State Grid Corp of China SGCC; State Grid Gansu Electric Power Co Ltd
Current assignee: STATE GRID GASU ELECTRIC POWER RESEARCH INSTITUTE; State Grid Corp of China SGCC; State Grid Gansu Electric Power Co Ltd
Priority date: 2022-08-19
Filing date: 2022-08-19
Publication date: 2022-11-18

Abstract

The invention discloses a high-efficiency dustproof heat dissipation device for a distributed energy router, which comprises a device shell, a device shell cover, the distributed energy router, a clamping and fixing structure, a heat dissipation structure and a dustproof structure, wherein the device shell is of a cavity structure with an opening at the upper end; the clamping and fixing structure comprises a clamping screw, a screw supporting block, a driving motor and a clamping plate. The invention relates to the technical field of routers, and particularly provides a high-efficiency dustproof heat dissipation device for a distributed energy router, which can dissipate heat efficiently and prevent dust effectively.

Description

High-efficient dustproof heat abstractor of distributed energy router

Technical Field

The invention relates to the technical field of routers, in particular to a high-efficiency dustproof heat dissipation device for a distributed energy router.

Background

Along with the development of the internet of things technology, home equipment is intelligent, networking is a trend, an energy router is used as a core device of an energy internet and has a series of functions of energy interaction, intelligent distribution, energy storage buffering and the like, the energy router has an important position in an intelligent home, the router can be generally placed in an open corner for a long time and works for 24 hours, a large amount of dust can be accumulated on the surface of the energy router, meanwhile, a large amount of heat is generated by long-time use, the network stability and the service life of the router can be directly influenced, particularly, a large amount of dust can be accumulated at a network cable connecting port, and the energy router is inconvenient to clean, so that the energy router with good heat dissipation and dust prevention functions is very necessary to design.

Disclosure of Invention

In order to overcome the defects, the invention provides the efficient dustproof heat dissipation device for the distributed energy router, which can dissipate heat efficiently and prevent dust effectively.

The invention provides the following technical inventions: the scheme provides a high-efficiency dustproof heat dissipation device for a distributed energy router, which comprises a device shell, a device shell cover, the distributed energy router, a clamping fixing structure, a heat dissipation structure and a dustproof structure, wherein the device shell is of a cavity structure with an opening at the upper end, a heat dissipation supporting plate is arranged at the bottom in the device shell, the device shell cover is arranged at the opening of the device shell in a sliding manner, the clamping fixing structure is arranged at the inner bottom wall of the device shell, the heat dissipation structure is arranged on the heat dissipation supporting plate, the distributed energy router is placed on the heat dissipation structure, an antenna of the distributed energy router penetrates through the device shell cover and extends to the outside, and the dustproof structure is arranged on the front side wall of the device shell; the clamping and fixing structure comprises clamping screws, screw supporting blocks, a driving motor and clamping plates, wherein the screw supporting blocks are provided with two groups, the two groups of screw supporting blocks are arranged between the inner bottom wall of the device shell and the heat dissipation supporting plate, the two ends of each clamping screw are rotatably arranged on the opposite side walls of the two groups of screw supporting blocks, the driving motor is arranged on the side wall of one group of screw supporting blocks, a power output shaft of the driving motor penetrates through the screw supporting blocks and is connected with one end of each clamping screw, a guide sliding groove is formed in the heat dissipation supporting plate, two groups of thread groups in opposite directions are arranged on each clamping screw, the two groups of clamping plates are provided with two groups, the lower ends of the two groups of clamping plates are connected with the two groups of thread groups in opposite directions through threads, the upper ends of the two groups of clamping plates penetrate through the guide sliding groove and slide above the heat dissipation supporting plate, air passing holes are formed in the clamping plates, and the two groups of clamping plates are provided with clamping blocks opposite side walls.

In order to carry out high-efficient heat dissipation to distributed energy source router, heat radiation structure includes radiating bin, coiled pipe, radiating fin, water pump, water tank and radiator fan, the radiating bin is located on the radiating support board, radiating fin locates diapire in the radiating bin, the radiating fin upper end runs through the radiating bin and extends to the outside, the radiating fin equipartition is equipped with the multiunit, distributed energy source router places on the multiunit radiating fin, the coiled pipe is located in the radiating bin, the coiled pipe runs through multiunit radiating fin, water pump and water tank are located on the radiating support board, be connected with water pipe one between water pump and the water tank, water pump and coiled pipe one end are connected with water pipe two, the water tank and coiled pipe other end are connected with water pipe three, device casing relative lateral wall is equipped with the thermovent, be equipped with the dust screen on the thermovent, radiator fan locates on a set of thermovent.

In order to enable the device to effectively prevent dust at the net wire connecting port and simultaneously have a good function of preventing the net wire from loosening, the dustproof structure comprises a supporting spring, a plugging sliding plate and a shifting rod, the net wire connecting port is arranged on the front side wall of the device shell, a plugging groove is arranged on the front side wall of the device shell and is communicated with the net wire connecting port, the plugging sliding plate slides in the plugging groove, the supporting spring is arranged between the inner side wall of the plugging groove and the plugging sliding plate, a stirring sliding groove is arranged on the front side wall of the device shell, the shifting rod penetrates through the stirring sliding groove and is arranged on the plugging sliding plate, and the dustproof structure is symmetrically provided with two groups about the net wire connecting port.

Preferably, the bottom of the device shell is provided with a support foot pad.

Further, the driving motor is a forward and reverse rotating motor.

Furthermore, a dustproof rubber block is arranged at the top of the device shell and sleeved on the antenna of the distributed energy router.

Furthermore, heat dissipation holes are formed in the heat dissipation fins.

The invention with the structure has the following beneficial effects: according to the efficient dustproof heat dissipation device for the distributed energy router, the distributed energy router is supported and clamped through the clamping and fixing structure and the heat dissipation structure, the distributed energy router is quickly dissipated through the heat dissipation structure, heat conduction is carried out on the surface of the router through the heat dissipation fins, the heat dissipation fins are continuously and quickly cooled through water circulation, the surface of the router and the heat dissipation fins are cooled through the heat dissipation fan, and the cooling efficiency is greatly improved through combination of multiple cooling modes; effectively carry out dustproof shutoff to the net twine connector through dustproof construction, two sets of shutoff slides can fasten the net twine centre gripping simultaneously, prevent not hard up.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic overall structure diagram of a high-efficiency dustproof heat dissipation device for a distributed energy router according to the present invention;

FIG. 2 isbase:Sub>A schematic sectional view A-A of FIG. 1;

fig. 3 is a schematic perspective structural view of an efficient dustproof heat dissipation device of a distributed energy router according to the present invention;

fig. 4 is a top view of an internal structure of a heat dissipation chamber of the efficient dustproof heat dissipation device for the distributed energy router according to the present invention.

The device comprises a device shell, a device shell cover, a distributed energy router, a clamping and fixing structure, a heat dissipation structure 6, a dustproof structure 7, a heat dissipation support plate 8, a clamping screw 9, a screw support block 10, a driving motor 11, a clamping plate 12, a guide chute 13, an air passing hole 14, a clamping block 15, a heat dissipation bin 16, a coiled pipe 17, a heat dissipation fin 18, a water pump 19, a water tank 20, a heat dissipation fan 21, a water pipe I22, a water pipe II, a water pipe 23, a water pipe III, a heat dissipation hole 24, a support spring 25, a support spring 26, a sealing slide plate 27, a deflector rod 28, a network cable connecting port 29, a sealing groove 30, a poking chute 31, a support pad foot 32, a dustproof rubber block 33, and a heat dissipation hole.

Detailed Description

The technical invention in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying 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.

It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

As shown in fig. 1 to 4, the technical invention adopted by the present invention is as follows: a high-efficiency dustproof heat dissipation device for a distributed energy router comprises a device shell 1, a device shell cover 2, a distributed energy router 3, a clamping fixing structure 4, a heat dissipation structure 5 and a dustproof structure 6, wherein the device shell 1 is of a cavity structure with an opening at the upper end, a heat dissipation support plate 7 is arranged at the bottom in the device shell 1, the device shell cover 2 is arranged at the opening of the device shell 1 in a sliding mode, the clamping fixing structure 4 is arranged at the inner bottom wall of the device shell 1, the heat dissipation structure 5 is arranged on the heat dissipation support plate 7, the distributed energy router 3 is placed on the heat dissipation structure 5, an antenna of the distributed energy router 3 penetrates through the device shell cover 2 and extends to the outside, and the dustproof structure 6 is arranged on the front side wall of the device shell 1; the clamping fixing structure 4 comprises a clamping screw 8, screw supporting blocks 9, a driving motor 10 and clamping plates 11, the screw supporting blocks 9 are provided with two groups, the two groups of screw supporting blocks 9 are arranged between the inner bottom wall of the device shell 1 and the heat dissipation supporting plate 7, two ends of each clamping screw 8 are rotatably arranged on the opposite side walls of the two groups of screw supporting blocks 9, the driving motor 10 is arranged on the side walls of the one group of screw supporting blocks 9, a power output shaft of the driving motor 10 penetrates through the screw supporting blocks 9 and is connected with one end of each clamping screw 8, a guide sliding groove 12 is formed in each heat dissipation supporting plate 7, two groups of thread groups in opposite directions are arranged on each clamping screw 8, the clamping plates 11 are provided with two groups, the lower ends of the two groups of clamping plates 11 are connected with the threads in the opposite directions through threads, the upper ends of the two groups of clamping plates 11 penetrate through the guide sliding grooves 12 and slide above the heat dissipation supporting plates 7, air passing holes 13 are formed in the clamping plates 11, and clamping blocks 14 are arranged on the opposite side walls of the two groups of the clamping plates 11.

As shown in fig. 3 and 4, the heat dissipation structure 5 includes a heat dissipation chamber 15, a serpentine tube 16, heat dissipation fins 17, a water pump 18, a water tank 19 and a heat dissipation fan 20, the heat dissipation chamber 15 is disposed on the heat dissipation support plate 7, the heat dissipation fins 17 are disposed on the inner bottom wall of the heat dissipation chamber 15, the upper ends of the heat dissipation fins 17 penetrate through the heat dissipation chamber 15 and extend to the outside, multiple sets of heat dissipation fins 17 are uniformly distributed on the heat dissipation fins 17, the distributed energy router 3 is disposed on the multiple sets of heat dissipation fins 17, the serpentine tube 16 is disposed in the heat dissipation chamber 15, the serpentine tube 16 penetrates through the multiple sets of heat dissipation fins 17, the water pump 18 and the water tank 19 are disposed on the heat dissipation support plate 7, a first water pipe 21 is connected between the water pump 18 and the water tank 19, one ends of the water pump 18 and the serpentine tube 16 are connected with a second water pipe 22, the other ends of the water tank 19 and the serpentine tube 16 are connected with a third water pipe 23, heat dissipation ports 24 are disposed on opposite side walls of the device housing 1, a dust screen is disposed on the heat dissipation ports 24, and the heat dissipation fan 20 is disposed on a set of the heat dissipation ports 24.

As shown in fig. 1 and fig. 2, the dustproof structure 6 includes a support spring 25, a plugging sliding plate 26 and a shift lever 27, a cable connector 28 is disposed on a front side wall of the device housing 1, a plugging groove 29 is disposed on a front side wall of the device housing 1, the plugging groove 29 is communicated with the cable connector 28, the plugging sliding plate 26 slides in the plugging groove 29, the support spring 25 is disposed between an inner side wall of the plugging groove 29 and the plugging sliding plate 26, a shift chute 30 is disposed on the front side wall of the device housing 1, the shift lever 27 penetrates through the shift chute 30 and is disposed on the plugging sliding plate 26, and two sets of the dustproof structure 6 are symmetrically disposed about the cable connector 28.

As shown in fig. 1 and 3, the bottom of the device case 1 is provided with a support foot 31.

Wherein, the driving motor 10 is a forward and reverse rotating motor.

As shown in fig. 1 and 3, a dustproof rubber block 32 is disposed on the top of the device housing 1, and the dustproof rubber block 32 is sleeved on the antenna of the distributed energy router 3.

Wherein, the radiating fins 17 are provided with radiating holes 33.

When the device is used, the distributed energy router 3 is placed on the multiple groups of radiating fins 17, the driving motor 10 is started, the driving motor 10 drives the clamping screw 8 to rotate, the clamping screw 8 drives the two groups of clamping plates 11 to move oppositely, the distributed energy router 3 is clamped through the clamping block 14, then the device shell cover 2 is installed at an opening of the device shell 1, an antenna of the distributed energy router 3 penetrates through the device shell cover 2, a gap between the antenna and the device shell cover 2 is blocked through the dustproof rubber block 32, dust is prevented from falling into the device, the device is in an initial unused state, the two groups of blocking sliding plates 26 block a network cable connecting port 28, when the device is used, the shifting rod 27 drives the blocking sliding plate 26 to slide in the shifting sliding groove 30, a power line, a network cable and the like are connected with the distributed energy router 3 through the network cable connecting port 28, the shifting rod 27 is released after connection is completed, the network cable is clamped under the action of 25 of the resilience of the supporting spring, and the positions of the network cable connecting port 28 which is not used are blocked, so that the network cable loosening prevention and the dust prevention effect is effectively achieved; distributed energy router 3 surface high temperature is cooled down through radiating fin 17, through starting water pump 18, make in the water tank 19 cooling water pass through water pipe one 21 and two 22 entering heat dissipation storehouse 15 of water pipe, carry out high-efficient cooling to radiating fin 17 through coiled pipe 16, then in three 23 backward flows to water tank 19 of water pipe, start radiator fan 20 simultaneously, radiator fan 20 blows in the device with outside cold wind, cool down distributed energy router 3 and radiating fin 17 simultaneously, realize high-efficient cooling.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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 invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. A high-efficiency dustproof heat dissipation device for a distributed energy router is characterized by comprising a device shell, a device shell cover, the distributed energy router, a clamping fixing structure, a heat dissipation structure and a dustproof structure, wherein the device shell is of a cavity structure with an opening at the upper end, a heat dissipation supporting plate is arranged at the bottom in the device shell, the device shell cover is arranged at the opening of the device shell in a sliding mode, the clamping fixing structure is arranged at the inner bottom wall of the device shell, the heat dissipation structure is arranged on the heat dissipation supporting plate, the distributed energy router is placed on the heat dissipation structure, an antenna of the distributed energy router penetrates through the device shell cover and extends to the outside, and the dustproof structure is arranged on the front side wall of the device shell; the clamping and fixing structure comprises two groups of screw supporting blocks, two groups of screw supporting blocks are arranged between the inner bottom wall of the device shell and the heat dissipation supporting plate, two ends of each clamping screw are rotatably arranged on two opposite side walls of the two groups of screw supporting blocks, the driving motor is arranged on one side wall of the one group of screw supporting block, a power output shaft of the driving motor penetrates through the screw supporting blocks and is connected with one end of the clamping screw, a guide sliding groove is formed in the heat dissipation supporting plate, two groups of thread groups in opposite directions are arranged on the clamping screw, two groups of clamping plates are arranged, the lower ends of the two groups of clamping plates are connected to the two groups of thread groups in opposite directions through threads, the upper ends of the two groups of clamping plates penetrate through the guide sliding groove and slide above the heat dissipation supporting plate, air passing holes are formed in the clamping plates, and clamping blocks are arranged on the opposite side walls of the two groups of clamping plates.

2. The efficient dustproof heat dissipation device for the distributed energy router as claimed in claim 1, wherein the heat dissipation structure comprises a heat dissipation bin, a plurality of sets of serpentine tubes, heat dissipation fins, a water pump, a water tank and heat dissipation fans, the heat dissipation bin is disposed on the heat dissipation support plate, the heat dissipation fins are disposed on the bottom wall of the heat dissipation bin, the upper ends of the heat dissipation fins extend through the heat dissipation bin and extend to the outside, the sets of the heat dissipation fins are uniformly distributed on the heat dissipation fins, the distributed energy router is placed on the sets of the heat dissipation fins, the serpentine tubes are disposed in the heat dissipation bin, the serpentine tubes extend through the sets of the heat dissipation fins, the water pump and the water tank are disposed on the heat dissipation support plate, the water pump and the water tank are connected with one water pipe, the water pump and one end of the serpentine tubes are connected with two water pipes, the other ends of the water tank and the serpentine tubes are connected with three water pipes, the opposite side walls of the device housing are provided with heat dissipation ports, the heat dissipation fans are provided with dustproof nets, and the heat dissipation ports are disposed on the sets of the heat dissipation ports.

3. The efficient dustproof heat dissipation device for the distributed energy router as claimed in claim 1, wherein the dustproof structure comprises a support spring, a plugging sliding plate and a shift lever, the front sidewall of the device housing is provided with a cable connector, the front sidewall of the device housing is provided with a plugging groove, the plugging groove is communicated with the cable connector, the plugging sliding plate slides in the plugging groove, the support spring is arranged between the inner sidewall of the plugging groove and the plugging sliding plate, the front sidewall of the device housing is provided with a shifting chute, the shift lever penetrates through the shifting chute and is arranged on the plugging sliding plate, and the dustproof structure is symmetrically arranged in two groups about the cable connector.

4. The device of claim 1, wherein a support pad is disposed at a bottom of the device housing.

5. The efficient dustproof heat dissipation device for the distributed energy router of claim 1, wherein the driving motor is a forward/reverse motor.

6. The efficient dustproof heat dissipation device for the distributed energy router according to claim 1, wherein a dustproof rubber block is arranged at the top of the device housing, and the dustproof rubber block is sleeved on an antenna of the distributed energy router.

7. The device of claim 2, wherein the heat sink fins have heat dissipation holes.