CN217563994U - High-efficiency radiator - Google Patents

Abstract

The utility model discloses a high-efficient radiator, including electrical components main part, install polymer heat radiation bottom plate in the electrical components main part, it is used for radiating polymer heat radiation fins to be provided with a plurality of on the polymer heat radiation bottom plate, polymer heat radiation fins's one end is provided with the deashing subassembly, polymer heat radiation fins's the other end is provided with the collection subassembly, the collection subassembly that the other end set up at polymer heat radiation fins's one end, wherein the deashing subassembly can enter into the storehouse of admitting air through external wind source inside, blow through jet-propelled shower nozzle to polymer heat radiation fins's lateral wall to make the dust that adheres at polymer heat radiation fins surface blown down, get into to the collection subassembly inside and collect the storage along polymer heat radiation fins, when clearing up polymer heat radiation fins surface dust, the heat on taking away polymer heat radiation fins surface that the air current that blows also can be quick, further improve polymer heat radiation fins's high-efficient radiating effect.

Description

High-efficiency radiator

Technical Field

The utility model relates to a macromolecular material technical field, concretely relates to high-efficient radiator.

Background

The polymer materials include plastics, rubbers, fibers, films, adhesives, and coatings, among which plastics, synthetic rubbers, and synthetic fibers are referred to as modern three major polymer materials. They are light, rich in raw material, convenient in processing, good in performance and extensive in application, so that its development speed greatly exceeds that of traditional three basic materials.

In order to enhance the heat dissipation performance of the heat sink, some special products are produced by using a high polymer material as a manufacturing material, and the high polymer material heat sink is a device or an instrument which transfers heat generated by machinery or other appliances in the working process in time so as to avoid influencing the normal work of the machinery or other appliances. Common radiators can be divided into various types such as air cooling, heat pipe radiators, liquid cooling, semiconductor refrigeration, compressor refrigeration and the like according to the heat dissipation mode.

The radiator that uses at present often adopts macromolecular material to make, and the radiator is used for guaranteeing that electronic components can not be too high at the in-process temperature of operation, and the high-efficient radiator of installation in long-time use, its surface can have a large amount of dusts, if not clear up in time then can greatly reduced high-efficient radiator's radiating effect.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient radiator solves current electronic components and all can add high-efficient radiator and dispel the heat at the in-process that uses for guarantee that electronic components is not too high at the in-process temperature of operation, and the high-efficient radiator of installation in long-time use, its surface can fall a large amount of dusts, if not in time the clearance then can the radiating effect's of high-efficient radiator of greatly reduced problem.

In order to solve the above technical problem, the utility model particularly provides the following technical scheme:

the utility model provides a high-efficiency radiator, which comprises an electric appliance element main body, wherein a high-molecular polymer radiating bottom plate is arranged on the electric appliance element main body, a plurality of high-molecular radiating fins for radiating are arranged on the high-molecular polymer radiating bottom plate, an ash cleaning component is arranged at one end of each high-molecular radiating fin, and a collecting component is arranged at the other end of each high-molecular radiating fin;

the deashing subassembly includes the storehouse of admitting air, the storehouse of admitting air with electrical components main part links to each other, the bottom intercommunication of the storehouse of admitting air has a plurality of outlet duct, the bottom slope of outlet duct is installed and is spouted the shower nozzle, it sets up at every two sets of polymer heat radiation fins's middle part to spout the shower nozzle, the side intercommunication of the storehouse of admitting air has external air supply communicating pipe.

As a preferred scheme of the utility model, the collection subassembly is including setting up the storehouse is collected to the dust of the polymer heat radiation fins other end, the middle part in storehouse is collected for leading to the groove to the dust, the dust collect the storehouse with the electrical components main part links to each other, the inside in storehouse is collected to the dust slides and is provided with the dust bin, the bottom of dust bin is provided with the pulling slider, the bottom in storehouse is collected to the dust be provided with pulling slider matched with pulling slide.

As a preferred scheme of the utility model, the left side in storehouse is collected to the dust is provided with the dust filter screen, the right-hand member of dust bin is provided with the pulling handle.

As a preferred scheme of the utility model, the articulated closed connecting plate that is provided with of right-hand member in storehouse is collected to the dust, be provided with on the closed connecting plate be used for with the closed connecting plate with the fixing bolt that the storehouse links to each other is collected to the dust.

As a preferred scheme of the utility model, the top that the storehouse was collected to the dust is provided with a plurality of communicating pipe that admits air, admit air communicating pipe with the storehouse middle part is collected to the dust leads to the groove and is linked together.

As a preferred scheme of the utility model, the symmetry articulates on the inner wall of intake communicating pipe has two sets of anti-return connecting plates, anti-return connecting plate with link to each other through the supporting spring who sets up between the intake communicating pipe inner wall.

Compared with the prior art, the utility model following beneficial effect has:

the utility model discloses an ash removal subassembly that one end at polymer heat radiation fins set up, the collection subassembly that the other end set up, wherein the ash removal subassembly can enter into the storehouse of admitting air through external wind regime inside, blow through jet-propelled shower nozzle to polymer heat radiation fins's lateral wall, thereby make the dust that the adhesion is on polymer heat radiation fins surface blown down, get into to collect the subassembly inside along polymer heat radiation fins and collect and store, when clearing up polymer heat radiation fins surface dust, the air current that blows also can be quick takes away the heat on polymer heat radiation fins surface, further improve polymer heat radiation fins's high-efficient radiating effect.

Drawings

In order to more clearly illustrate the embodiments of the present invention 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 should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

Fig. 1 is a schematic structural front view according to an embodiment of the present invention.

Fig. 2 is a schematic sectional view of the structure of the embodiment of the present invention.

Fig. 3 is an enlarged schematic view of the structure of the pull handle in fig. 2 according to the embodiment of the present invention.

Fig. 4 is an enlarged schematic view of the structure of the intake communicating pipe in fig. 2 according to the embodiment of the present invention.

The reference numerals in the drawings denote the following, respectively:

1. an electrical component main body; 2. a high molecular polymer heat dissipation base plate; 3. polymer heat radiation fins; 4. a soot cleaning assembly; 5. a collection assembly;

401. an air inlet bin; 402. an air outlet pipe; 403. an air injection nozzle; 404. is externally connected with an air source communicating pipe;

501. a dust collection bin; 502. a dust storage bin; 503. pulling the sliding block; 504. pulling the slide way; 505. a dust filter screen; 506. pulling the handle; 507. closing the connecting plate; 508. fixing the bolt; 509. an air intake communicating pipe; 510. a backflow prevention connecting plate; 511. the spring is supported.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the 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 present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1 to 4, the utility model provides a high-efficient radiator, including electrical components main part 1, install high polymer radiating bottom plate 2 on the electrical components main part 1, be provided with a plurality of on the high polymer radiating bottom plate 2 and be used for radiating polymer heat radiation fins 3, polymer heat radiation fins 3's one end is provided with deashing subassembly 4, and polymer heat radiation fins 3's the other end is provided with collection subassembly 5.

In this embodiment, because current electronic components all can add high-efficient radiator at the in-process that uses and dispel the heat for guarantee that electronic components is not too high at the in-process temperature of operation, and the high-efficient radiator of installation in long-time use, its surface can drop a large amount of dusts, if not clear up then can greatly reduced high-efficient radiator's radiating effect in time.

After a radiator added on the surface of an electronic component is used for a period of time, most of the surface of the radiator can fall into a section of dust, if the dust is not cleaned in time, the heat dissipation capacity of a high-efficiency radiating fin can be reduced, and the dust adhered on the radiating fin can be firmly adhered on the surface of the radiating fin to corrode and damage the radiating fin assembly to a certain extent in wet weather, so that the service life of the radiator is greatly shortened.

As shown in fig. 1 to 4, in the present embodiment, the ash removal assembly 4 includes an air inlet bin 401, the air inlet bin 401 is connected to the electrical component main body 1, the bottom end of the air inlet bin 401 is communicated with a plurality of air outlet pipes 402, the bottom ends of the air outlet pipes 402 are obliquely provided with air injection nozzles 403, the air injection nozzles 403 are disposed in the middle of each two groups of polymer heat dissipation fins 3, and the side edge of the air inlet bin 401 is communicated with an external air source communicating pipe 404.

In this embodiment, the collecting assembly 5 includes a dust collecting bin 501 disposed at the other end of the polymer heat dissipating fins 3, the middle of the dust collecting bin 501 is a through slot, the dust collecting bin 501 is connected to the electrical component main body 1, a dust storing bin 502 is slidably disposed inside the dust collecting bin 501, a pulling slider 503 is disposed at the bottom end of the dust storing bin 502, a pulling slide 504 matched with the pulling slider 503 is disposed at the bottom end of the dust collecting bin 501, and a dust filtering net 505 is disposed on the left side of the dust collecting bin 501.

The right-hand member of dust storage box 502 is provided with pulling handle 506, the articulated closed connecting plate 507 that is provided with of right-hand member of dust collection storehouse 501, be provided with on the closed connecting plate 507 and be used for the fixing bolt 508 that links to each other closed connecting plate 507 and dust collection storehouse 501, the top of dust collection storehouse 501 is provided with a plurality of communicating pipe 509 that admits air, it is linked together to admit air communicating pipe 509 and dust collection storehouse 501 middle part logical groove, the symmetry articulates on the inner wall of communicating pipe 509 that admits air has two sets of anti-return connecting plates 510, anti-return connecting plate 510 links to each other through the supporting spring 511 that sets up between communicating pipe 509 inner wall that admits air.

Further, after the surface of the polymer heat dissipation fin 3 falls into a certain amount of dust, the user connects the external air source through the external air source communication pipe 404, so that the clean air flow enters the air inlet bin 401, enters the air jet nozzle 403 through the air outlet pipe 402, and blows in between every two groups of polymer heat dissipation fins 3 through the air jet nozzle 403, so as to blow off the dust falling into the surface of the polymer heat dissipation fin 3, because the polymer heat dissipation fin 3 is in a blade shape, so that the dust blown down by the air jet nozzle 403 can move downwards to the other end of the polymer heat dissipation fin 3 along the inner wall of the polymer heat dissipation fin 3, and the air inlet communication pipe 509 is arranged at the other end of the polymer heat dissipation fin 3, the air inlet communication pipe 509 can directly collect the mixed gas flowing along the polymer heat dissipation fin 3, so that the air mixed with the dust enters the dust collecting bin 501 through the air inlet communication pipe 509.

And through setting up the anti-return connecting plate 510 inside the air intake communicating pipe 509, the anti-return connecting plate 510 passes through supporting spring 511 elastic support inside the air intake communicating pipe 509, and the supporting force of supporting spring 511 is less than the strength that the wind blows, thereby make the air current enter into the dust collection bin 501 inner chamber through the air intake communicating pipe 509, certain rotation can take place for the anti-return connecting plate 510, after rotating, the anti-return connecting plate 510 resets again under the resilience effect of supporting spring 511, thereby block the air current entering into the dust collection bin 501 inner chamber, avoid it to appear a large amount of phenomenon of backward flow, and the mixed gas stream that enters into the dust collection bin 501 inside can flow out through the dust filter screen 505 that the dust collection bin 501 left end set up, and the dust that contains in the mixed gas can fall into the dust storage bin 502 inside, thereby carry out quick collection to dust, avoid dust to fly to other positions of equipment and cause the damage, the user rotates fixing bolt 508, rotate closed connecting plate 507, make the dust storage bin 502 from the dust collection bin 501 inside, thereby carry out the dust in the dust storage bin 502.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims (6)

1. The utility model provides a high-efficient radiator, includes electrical components main part (1), install high molecular polymer radiating bottom plate (2) on electrical components main part (1), be provided with a plurality of and be used for radiating polymer radiating fin (3) on high molecular polymer radiating bottom plate (2), its characterized in that: one end of each polymer radiating fin (3) is provided with an ash removal component (4), and the other end of each polymer radiating fin (3) is provided with a collection component (5);

the deashing subassembly (4) including air inlet bin (401), air inlet bin (401) with electrical components main part (1) links to each other, air inlet bin's (401) bottom intercommunication has a plurality of outlet duct (402), jet-propelled shower nozzle (403) are installed in the bottom slope of outlet duct (402), jet-propelled shower nozzle (403) set up every two sets of the middle part of polymer heat dissipation fin (3), air inlet bin's (401) side intercommunication has external air supply communicating pipe (404).

2. A high efficiency heat sink as recited in claim 1, wherein: collect subassembly (5) including setting up storehouse (501) is collected to the dust of polymer heat radiation fins (3) other end, the middle part that storehouse (501) was collected to the dust is logical groove, storehouse (501) is collected to the dust with electrical components main part (1) links to each other, the inside slip in storehouse (501) is collected to the dust is provided with dust bin (502), the bottom of dust bin (502) is provided with pulling slider (503), the bottom in storehouse (501) is collected to the dust be provided with pulling slider (503) matched with pulling slide (504).

3. A high efficiency heat sink as recited in claim 2, wherein: the left side of dust collection bin (501) is provided with dust filter screen (505), the right-hand member of dust storage box (502) is provided with pulling handle (506).

4. A high efficiency heat sink as recited in claim 3, wherein: the right end of the dust collection bin (501) is hinged to be provided with a closed connecting plate (507), and a fixing bolt (508) used for connecting the closed connecting plate (507) with the dust collection bin (501) is arranged on the closed connecting plate (507).

5. The efficient heat sink of claim 4, wherein: the top of dust collection storehouse (501) is provided with a plurality of communicating pipe (509) that admits air, admit air communicating pipe (509) with dust collection storehouse (501) middle part is led to the groove and is linked together.

6. A high efficiency heat sink as recited in claim 5, wherein: two sets of anti-backflow connecting plates (510) are symmetrically hinged to the inner wall of the air inlet communicating pipe (509), and the anti-backflow connecting plates (510) are connected with the inner wall of the air inlet communicating pipe (509) through supporting springs (511) arranged.

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