CN207820417U - The radiator structure of filter cavity - Google Patents

Abstract

The utility model discloses the radiator structures of filter cavity, including shell, the equally distributed cooling fin of outer surface of outer cover, auxiliary heat dissipation piece is located at the both sides of cooling fin, the auxiliary heat dissipation on piece is evenly arranged with multiple heat emission holes, cooling fin both sides are evenly distributed with multiple auxiliary heat dissipation pieces, the central shaft of the heat emission hole of the multiple auxiliary heat dissipation on piece corresponds point-blank, one cooling fin forms a heat-sink unit with multiple auxiliary heat dissipation pieces on the cooling fin, there are gaps between the heat-sink unit, its clearance distance 0.3cm~0.5cm, when implementation, cooling fin is aluminium with the material that auxiliary heat dissipation piece uses.When cooling fin is arranged, the height of cooling fin is can be adjusted according to the needs, enhances its heat dissipation performance, after increasing fin height, while increasing multiple auxiliary heat dissipation pieces to increase heat dissipation area in both sides, enhances its heat dissipation performance.

Description

The radiator structure of filter cavity

Technical field

The utility model is related to a kind of wood working tools, and in particular to the radiator structure of filter cavity.

Background technology

With the development and progress of electronic technology science and technology, simple circuit structure also can no longer meet demand, of today Circuit structure becomes increasingly complex, and more and more electronic products require the data volume of transmission increasing, and system structure is enabled more to become Complexity, therefore the design of cooling system is increasingly paid close attention to by height.In face of this development trend, novel heat dissipation dress is designed It is set to as certainty.

Utility model content

Technical problem to be solved in the utility model is that the construction for heat radiating device of current filter can no longer meet Nowadays complicated circuit structure, and it is an object of the present invention to provide filter cavity radiator, solve the heat dissipation dress of current filter Set the problem of structure can no longer meet nowadays complicated circuit structure.

The utility model is achieved through the following technical solutions：

The radiator structure of filter cavity, including shell, the equally distributed cooling fin of outer surface of outer cover further include that auxiliary dissipates Backing, auxiliary heat dissipation piece are located at the both sides of cooling fin, and the auxiliary heat dissipation on piece is evenly arranged with multiple heat emission holes.To increase it Heat dissipation effect allows filter to radiate there are mainly two types of method, is that the temperature around filter is allowed to reduce respectively, is also just to speed up Effective heat dissipation area that heat distributes allows the temperature of surrounding to reduce and is required for increasing fan lamp apparatus, of high cost, occupied space Greatly, noise is also big, all not applicable in many places, and therefore, the utility model enhances heat dissipation from effective heat dissipation area is increased Multiple heat emission holes are arranged in auxiliary heat dissipation on piece by adding auxiliary heat dissipation piece in the both sides of cooling fin in ability, effective to increase The heat dissipation area of cooling fin is added, has increased heat emission hole and effectively enhance cross-ventilation, enhance heat dissipation performance.

Further, cooling fin both sides are evenly distributed with multiple auxiliary heat dissipation pieces, and the multiple auxiliary heat dissipation on piece dissipates The central shaft of hot hole corresponds point-blank.When cooling fin is arranged, the height of cooling fin is can be adjusted according to the needs, Enhance its heat dissipation performance, after increasing fin height, while increasing multiple auxiliary heat dissipation pieces to increase heat dissipation area in both sides, increase Its strong heat dissipation performance, the central shaft of the heat emission hole of multiple auxiliary heat dissipation on pieces correspond point-blank, are conducive to air Convection current, enhance its heat dissipation effect.

Further, a cooling fin forms a heat-sink unit with multiple auxiliary heat dissipation pieces on the cooling fin, described There are gap, clearance distance 0.3cm~0.5cm between heat-sink unit.By flowing out gap between each heat-sink unit, Gap is narrow to influence cross-ventilation, and gap is wide, can reduce the quantity of heat-sink unit, influence heat dissipation performance, clearance distance setting In 0.3cm~0.5cm, it since it is provided with heat emission hole, in small gap, still can guarantee cross-ventilation, help to radiate.

Further, cooling fin and the material that auxiliary heat dissipation piece uses are aluminium.Using metal material, its heat conductivility is good, Aluminium has at low cost, easy processing characteristic

The utility model compared with prior art, has the following advantages and advantages：

1, the radiator structure of the utility model filter cavity, by adding auxiliary heat dissipation piece in the both sides of cooling fin, Multiple heat emission holes are arranged in auxiliary heat dissipation on piece, are effectively increased the heat dissipation area of cooling fin, increase heat emission hole and effectively increase Strong cross-ventilation, enhances heat dissipation performance；

2, the radiator structure of the utility model filter cavity is increased by increasing multiple auxiliary heat dissipation pieces in both sides simultaneously Add heat dissipation area, enhance its heat dissipation performance, the central shaft of the heat emission hole of multiple auxiliary heat dissipation on pieces is corresponded in straight line On, be conducive to the convection current of air, enhance its heat dissipation effect；

3, the radiator structure of the utility model filter cavity, by flowing out gap, gap between each heat-sink unit Narrow to influence cross-ventilation, gap is wide, can reduce the quantity of heat-sink unit, influences heat dissipation performance, and clearance distance setting exists 0.3cm~0.5cm, in small gap, still can guarantee cross-ventilation since it is provided with heat emission hole, help to radiate.

Description of the drawings

Attached drawing described herein is used for providing further understanding the utility model embodiment, constitutes the one of the application Part does not constitute the restriction to the utility model embodiment.In the accompanying drawings：

FIG. 1 is a schematic structural view of the utility model.

Label and corresponding parts title in attached drawing：

1- shells；2- cooling fins；3- auxiliary heat dissipation pieces；4- heat emission holes.

Specific implementation mode

To make the purpose of this utility model, technical solution and advantage be more clearly understood, with reference to embodiment and attached drawing, The utility model is described in further detail, and the exemplary embodiment and its explanation of the utility model are only used for explaining this Utility model is not intended to limit the scope of the present invention.

Embodiment

As shown in Figure 1, the radiator structure of the utility model filter cavity, including shell 1,1 outer surface of shell are uniformly divided The cooling fin 2 of cloth, auxiliary heat dissipation piece 3 are located at the both sides of cooling fin 2, multiple heat dissipations are evenly arranged on the auxiliary heat dissipation piece 3 Hole 4,2 both sides of cooling fin are evenly distributed with multiple auxiliary heat dissipation pieces 3, the center of the heat emission hole 4 on the multiple auxiliary heat dissipation piece 3 Axis corresponds point-blank, and a cooling fin 2 forms a heat dissipation list with multiple auxiliary heat dissipation pieces 3 on the cooling fin Member, there are gap between the heat-sink unit, clearance distance 0.3cm~0.5cm, when implementation, cooling fin 2 and auxiliary heat dissipation piece 3 materials used are aluminium.When cooling fin is arranged, the height of cooling fin is can be adjusted according to the needs, enhances its heat dissipation performance, is increased After radiation fin height, while increasing multiple auxiliary heat dissipation pieces to increase heat dissipation area in both sides, enhances its heat dissipation performance.

Above-described specific implementation mode, to the purpose of this utility model, technical solution and advantageous effect carried out into One step is described in detail, it should be understood that the foregoing is merely specific embodiment of the present utility model, is not used to limit Determine the scope of protection of the utility model, within the spirit and principle of the utility model, any modification for being made equally is replaced It changes, improve, should be included within the scope of protection of this utility model.

Claims (3)

1. the radiator structure of filter cavity, including shell (1), the equally distributed cooling fin in shell (1) outer surface (2) is special Sign is, further includes auxiliary heat dissipation piece (3), and auxiliary heat dissipation piece (3) is located at the both sides of cooling fin (2), the auxiliary heat dissipation piece (3) On be evenly arranged with multiple heat emission holes (4)；Cooling fin (2) both sides are evenly distributed with multiple auxiliary heat dissipation pieces (3), described more The central shaft of heat emission hole (4) on a auxiliary heat dissipation piece (3) corresponds point-blank.

2. the radiator structure of filter cavity according to claim 1, which is characterized in that a cooling fin (2) dissipates with this Multiple auxiliary heat dissipation pieces (3) on backing form a heat-sink unit, and there are gap, clearance distances between the heat-sink unit 0.3cm~0.5cm.

3. the radiator structure of filter cavity according to claim 1, which is characterized in that the cooling fin (2) and auxiliary The material that cooling fin (3) uses is aluminium.