CN219976855U - Fluid active refrigeration heat radiation structure applied to pad body - Google Patents

Abstract

The utility model relates to the technical field of refrigeration and heat dissipation structures, and discloses a fluid active refrigeration and heat dissipation structure applied to a pad body, which comprises the pad body, a refrigeration water tank, a refrigeration sheet, a heat dissipation water tank and an auxiliary water tank; the cushion body is provided with a flow channel, the cushion body is connected with a refrigeration pipeline, a refrigeration loop is formed between the refrigeration pipeline and the flow channel, and the refrigeration pump body drives refrigeration fluid to flow in the refrigeration loop; the refrigerating sheet is provided with a refrigerating surface and a radiating surface, and the refrigerating surface is attached to the refrigerating water tank; the radiating surface is attached to the radiating water tank, the radiating water tank is communicated with the auxiliary water tank through a radiating pipeline to form a radiating loop, and the radiating pump body drives radiating fluid to flow in the radiating loop; through the circulation flow of refrigeration fluid in the refrigeration circuit of refrigeration pump body drive, the effect of refrigeration can be realized to the pad body, and the heat that the radiating surface given off can conduct the heat dissipation through the radiator, and auxiliary water tank realizes radiating effect at the air current forced air cooling effect of air outlet, has realized the radiating effect of the radiating surface quick heat dissipation of refrigeration piece.

Description

Fluid active refrigeration heat radiation structure applied to pad body

Technical Field

The utility model relates to the technical field of refrigeration and heat dissipation structures, in particular to a fluid active refrigeration and heat dissipation structure applied to a cushion body.

Background

The cooling and heat dissipating structure is widely applied to the field of cooling fluid, for example, fluid cooling of a pad body. The inside of the cushion body is provided with a flow passage, fluid flows between the flow passage and the water tank, and the fluid in the water tank is refrigerated by arranging the refrigerating sheets so as to realize the effect that the cushion body can refrigerate.

In the prior art, the cooling fin radiates heat when cooling, and because the cooling fin and the water tank are generally arranged inside the shell, the better heat radiation effect is difficult to realize only by arranging the heat radiation holes in the shell.

Disclosure of Invention

The utility model aims to provide a fluid active refrigeration heat dissipation structure applied to a cushion body, and aims to solve the problem of poor heat dissipation effect of the refrigeration heat dissipation structure in the prior art.

The utility model is realized in such a way that the fluid active refrigeration and heat dissipation structure applied to the cushion body comprises the cushion body, a refrigeration water tank for installing refrigeration fluid, a refrigeration sheet, a heat dissipation water tank for installing heat dissipation fluid and an auxiliary water tank arranged at an air outlet; the pad body is provided with a flow channel for flowing refrigerating fluid, the pad body is connected with a refrigerating pipeline, and a refrigerating loop is formed between the refrigerating pipeline and the flow channel; the refrigerating water tank is connected with the refrigerating pump body in a refrigerating pipeline, and the refrigerating pump body drives refrigerating fluid to flow in the refrigerating loop; the refrigerating sheet is provided with a refrigerating surface and a radiating surface, and the refrigerating surface is attached to the refrigerating water tank;

the heat radiation surface is attached to the heat radiation water tank, the heat radiation water tank is communicated with the auxiliary water tank through a heat radiation pipeline to form a heat radiation loop, the heat radiation loop is connected with a heat radiation pump body, and the heat radiation pump body drives heat radiation fluid to flow in the heat radiation loop.

Further, the fluid active refrigeration heat dissipation structure applied to the pad body comprises a shell, and the refrigeration water tank, the refrigeration sheet, the heat dissipation water tank and the refrigeration pump body are arranged in the shell.

Further, the refrigerating surface is in planar attachment connection with the refrigerating water tank.

Further, the radiating surface is in planar attachment connection with the radiating water tank.

Further, the auxiliary water tank and the heat dissipation pump body are respectively arranged in the shell.

Further, the refrigerating water tank, the radiating water tank and the auxiliary water tank are respectively provided with a liquid injection port on the shell.

Further, an air inlet communicated with the inside of the shell is formed in the shell, and the auxiliary water tank is arranged towards the air inlet.

Further, a heat dissipation interval is formed between the air inlet and the auxiliary water tank, a heat conduction rubber block is arranged in the heat dissipation interval, the inner end of the heat conduction rubber block is in butt joint with the auxiliary water tank, and the outer end of the heat conduction rubber block layer is arranged towards the air inlet;

the heat conduction glue block is internally provided with a heat conduction channel, and the heat conduction channel penetrates through the heat conduction glue block along the direction from the air inlet to the auxiliary water tank and is arranged right opposite to the auxiliary water tank.

Further, a plurality of lateral holes are formed in the periphery of the heat-conducting rubber block, and the lateral holes are communicated with the heat-conducting channel.

Further, the lateral holes form lateral openings at the periphery of the heat conducting glue block, and are arranged in an outward inclined manner along the extending direction of the lateral holes from inside to outside and towards the auxiliary water tank.

Compared with the prior art, the fluid active refrigeration and heat dissipation structure applied to the pad body provided by the utility model has the advantages that the refrigeration pump body drives the refrigeration fluid to circulate in the refrigeration loop, the pad body can realize the refrigeration effect, the heat emitted by the heat dissipation surface of the refrigeration sheet can conduct and dissipate heat through the heat dissipation water tank, the heat dissipation effect is realized through the air flow air cooling effect of the auxiliary water tank at the air outlet, and the rapid heat dissipation effect of the heat dissipation surface of the refrigeration sheet is realized.

Drawings

FIG. 1 is a schematic perspective view of a fluid active refrigeration and heat dissipation structure applied to a cushion body according to the present utility model;

fig. 2 is a schematic cross-sectional view of a heat conducting gel block provided by the utility model.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The implementation of the present utility model will be described in detail below with reference to specific embodiments.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present utility model, it should be understood that, if there is an azimuth or positional relationship indicated by terms such as "upper", "lower", "left", "right", etc., based on the azimuth or positional relationship shown in the drawings, it is only for convenience of describing the present utility model and simplifying the description, but it is not indicated or implied that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus terms describing the positional relationship in the drawings are merely illustrative and should not be construed as limiting the present utility model, and specific meanings of the terms described above may be understood by those of ordinary skill in the art according to specific circumstances.

Referring to fig. 1-2, a preferred embodiment of the present utility model is provided.

The fluid active refrigeration and heat dissipation structure applied to the cushion body comprises the cushion body, a refrigeration water tank 201 for containing refrigeration fluid, a refrigeration sheet 300, a heat dissipation water tank 401 for containing heat dissipation fluid and an auxiliary water tank 400 arranged at an air outlet; the cushion body is provided with a flow channel for the flow of refrigerating fluid, the cushion body is connected with a refrigerating pipeline, and a refrigerating loop is formed between the refrigerating pipeline and the flow channel; the refrigeration water tank 201 is connected with the refrigeration pump 200 in a refrigeration pipeline, and the refrigeration pump 200 drives the refrigeration fluid to flow in a refrigeration loop; the refrigerating plate 300 has a refrigerating surface attached to the refrigerating water tank 201;

the radiating surface is attached to the radiating water tank 401, the radiating water tank 401 is communicated with the auxiliary water tank 400 through a radiating pipeline to form a radiating loop, a radiating pump body is connected to the radiating loop, and the radiating pump body drives radiating fluid to flow in the radiating loop.

The above-mentioned fluid initiative refrigeration heat radiation structure who applies to pad body, drive refrigerating fluid circulation flow in the refrigeration circuit through refrigeration pump body 200, the pad body can realize refrigerated effect, and the heat that the radiating surface of refrigeration piece 300 gives off can conduct the heat dissipation through radiator tank 401, and through the air-cooled effect of air current at the air outlet of supporting water tank 400, realizes radiating effect, has realized the radiating effect fast of the radiating surface of refrigeration piece 300.

Alternatively, as another embodiment, a radiator may be used instead of the radiator tank 401 or the like.

The active fluid cooling and radiating structure applied to the pad body comprises a shell 100, a cooling water tank 201, a cooling plate 300, a radiating water tank 401 and a cooling pump body 200 which are arranged in the shell 100, so that the whole structure can be more compact.

The refrigerating surface is attached to the refrigerating water tank 201 in a plane, so that a better refrigerating effect can be achieved.

The radiating surface is in planar attachment connection with the radiating water tank 401, so that better heat transfer between the radiating water tank 401 and the radiating surface can be realized.

The supporting water tank 400 and the heat dissipation pump body are respectively disposed inside the housing 100, so that the structure is more integrated.

The refrigeration tank 201, the heat radiation tank 401, and the support tank 400 are each formed with a liquid inlet in the casing 100, and can be filled with the refrigeration fluid and the heat radiation fluid at any time through the liquid inlet.

The housing 100 is provided with an air inlet communicated with the interior of the housing 100, and the auxiliary water tank 400 is arranged towards the air inlet, so that air flow entering from the air inlet is convenient for radiating the radiating fluid in the auxiliary water tank 400.

In this embodiment, a heat dissipation space is formed between the air inlet and the auxiliary water tank 400, a heat conducting rubber block 500 is arranged in the heat dissipation space, the inner end of the heat conducting rubber block 500 is abutted on the auxiliary water tank 400, and the outer end of the heat conducting rubber block 500 layer is arranged towards the air inlet;

the heat conducting glue block 500 is provided with a heat conducting channel 502, and the heat conducting channel 502 penetrates through the heat conducting glue block 500 along the direction from the air inlet to the auxiliary water tank 400 and is arranged opposite to the auxiliary water tank 400.

Through arranging the heat conduction glue block 500, the heat transfer to the auxiliary water tank 400 can be realized, and the air flow blown out by the air inlet can also be directly aligned with the auxiliary water tank 400 through the heat conduction channel 502, so that the heat dissipation effect is better.

The outer periphery of the heat-conducting glue block 500 is provided with a plurality of lateral holes 501, the lateral holes 501 are communicated with the heat-conducting channel 502, the flow of air flow can be quickened, and the air flow can be blown to the auxiliary water tank 400 through the lateral holes 501 and not only the heat-conducting channel 502.

The lateral holes 501 are formed in the outer circumference of the heat conductive rubber block 500 to be laterally opened, and the lateral holes 501 are arranged obliquely outward and toward the supporting water tank 400 along the extending direction of the lateral holes 501 from inside to outside, and the air flow blown out of the lateral holes 501 can be blown onto the supporting water tank 400.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. The fluid active refrigeration and heat dissipation structure applied to the cushion body is characterized by comprising the cushion body, a refrigeration water tank for containing refrigeration fluid, a refrigeration sheet, a heat dissipation water tank for containing heat dissipation fluid and an auxiliary water tank arranged at an air outlet; the pad body is provided with a flow channel for flowing refrigerating fluid, the pad body is connected with a refrigerating pipeline, and a refrigerating loop is formed between the refrigerating pipeline and the flow channel; the refrigerating water tank is connected with the refrigerating pump body in a refrigerating pipeline, and the refrigerating pump body drives refrigerating fluid to flow in the refrigerating loop; the refrigerating sheet is provided with a refrigerating surface and a radiating surface, and the refrigerating surface is attached to the refrigerating water tank;

the heat radiation surface is attached to the heat radiation water tank, the heat radiation water tank is communicated with the auxiliary water tank through a heat radiation pipeline to form a heat radiation loop, the heat radiation loop is connected with a heat radiation pump body, and the heat radiation pump body drives heat radiation fluid to flow in the heat radiation loop.

2. The fluid active cooling and heat dissipating structure applied to the cushion according to claim 1, wherein the fluid active cooling and heat dissipating structure applied to the cushion comprises a housing, and the cooling water tank, the cooling plate, the heat dissipating water tank and the cooling pump body are arranged in the housing.

3. The fluid active refrigeration and heat dissipation structure applied to a cushion body according to claim 2, wherein the refrigeration surface is in planar attachment connection with the refrigeration water tank.

4. The fluid active refrigeration and heat dissipation structure applied to a cushion body according to claim 2, wherein the heat dissipation surface is in planar attachment connection with the heat dissipation water tank.

5. The fluid active refrigeration and heat dissipation structure applied to a cushion body according to claim 2, wherein the auxiliary water tank and the heat dissipation pump body are respectively arranged in the shell.

6. The active cooling and heat dissipating structure of claim 5, wherein the cooling water tank, the heat dissipating water tank and the auxiliary water tank are respectively provided with a liquid filling port on the housing.

7. The active cooling and heat dissipating structure for a fluid of a cushion according to any one of claims 2 to 6, wherein the housing is provided with an air inlet communicating with the interior of the housing, and the auxiliary water tank is disposed toward the air inlet.

8. The fluid active refrigeration and heat dissipation structure applied to a cushion body according to claim 7, wherein a heat dissipation interval is formed between the air inlet and the auxiliary water tank, a heat conduction rubber block is arranged in the heat dissipation interval, the inner end of the heat conduction rubber block is butted on the auxiliary water tank, and the outer end of the heat conduction rubber block layer is arranged towards the air inlet;

the heat conduction glue block is internally provided with a heat conduction channel, and the heat conduction channel penetrates through the heat conduction glue block along the direction from the air inlet to the auxiliary water tank and is arranged right opposite to the auxiliary water tank.

9. The fluid active cooling and heat dissipating structure applied to the cushion according to claim 8, wherein the outer periphery of the heat conducting glue block is provided with a plurality of lateral holes, and the lateral holes are communicated with the heat conducting channel.

10. The fluid active cooling and heat dissipating structure for a cushion according to claim 9, wherein the lateral hole forms a lateral opening at the outer periphery of the heat conducting glue block, and is arranged obliquely outward and toward the auxiliary water tank along the extending direction of the lateral hole from inside to outside.