CN214892070U - Heat exchanger water-cooling plate capable of being cooled sufficiently - Google Patents

Abstract

The utility model discloses a heat exchanger water cooling plate capable of cooling fully, which comprises an inner circulation component and an outer circulation component; an external circulation component is arranged in the internal circulation component; the internal circulation assembly comprises a heat conducting plate, a plate body, a first water inlet pipe, a valve, a heat conducting fin, a micro water pump, a first cavity, a second cavity, a refrigerating fin, a third cavity and a baffle plate; first cavity, second cavity and third cavity have been seted up respectively to the inside of plate body, heat to equipment is transmitted through heat-conducting plate and conducting strip, heat conduction area has been increased, then refrigerate the inside moisture of second cavity through the refrigeration piece, later discharge the moisture that finishes through miniature pump into inside the first cavity, thereby cool off the temperature on conducting strip surface, last moisture gets back to inside the second cavity through the pipeline, refrigerate once more and extract, thereby the inner loop work has been realized, this device can be more high-efficient thorough carry out cooling work, and the work efficiency is improved.

Description

Heat exchanger water-cooling plate capable of being cooled sufficiently

Technical Field

The utility model relates to a heat exchanger water-cooling plate technical field specifically is a heat exchanger water-cooling plate of sufficient cooling.

Background

Traditional heat exchanger water-cooling board all installs the water-cooling tube at plate body inside embedded usually to cool down equipment through the inside moisture of water-cooling tube, but this kind of mode water-cooling tube is less with the area of contact of equipment, and heat transfer is slower, and the refrigerated time of cooling down is longer, hardly realizes high-efficient thorough cooling down.

Therefore, a heat exchanger water-cooling plate capable of being cooled sufficiently is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a heat exchanger water-cooling board that can fully cool off to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a heat exchanger water-cooling plate capable of being cooled sufficiently comprises an inner circulation assembly and an outer circulation assembly;

an external circulation component is arranged in the internal circulation component;

the internal circulation assembly comprises a heat conducting plate, a plate body, a first water inlet pipe, a valve, a heat conducting fin, a micro water pump, a first cavity, a second cavity, a refrigerating fin, a third cavity and a baffle plate;

a first cavity, a second cavity and a third cavity are respectively formed in the plate body, and the first cavity is positioned above the second cavity and the third cavity;

the heat conducting plate is embedded in the front surface of the plate body, heat conducting fins are uniformly and integrally formed on one side of the heat conducting plate, and one side of each heat conducting fin penetrates through one side of the plate body and is located in the first cavity;

the first cavity is communicated with the second cavity through a pipeline, and the refrigeration sheets are uniformly bonded on the inner top wall and the inner bottom wall of the second cavity.

Preferably: baffles are uniformly and integrally formed on the inner top wall and the inner bottom wall of the second cavity; through the arrangement, the flow speed of the water is slowed down.

Preferably: a micro water pump is arranged in the third cavity; through the arrangement, the moisture which is cooled in the second cavity is extracted.

Preferably: a water inlet of the micro water pump is communicated with the inside of the second cavity through a pipeline, and a water outlet of the micro water pump is communicated with the inner bottom wall of the first cavity through a pipeline; through the arrangement, the moisture after cooling is convenient to extract and discharge.

Preferably: a first water inlet pipe is communicated with the center of the upper surface of the first cavity, and a valve is arranged on the outer side wall of the first water inlet pipe; through above setting, more convenient pour into moisture into to first cavity is inside.

Preferably: the external circulation component comprises a heat exchange pipe, a second water inlet pipe and a water outlet pipe;

the heat exchange tubes are positioned in the first cavity and are arranged among the heat conducting fins in an S shape; through the above arrangement, the heat around the heat-conducting fin can be efficiently exchanged.

Preferably: one end of the heat exchange tube penetrates through one side of the first cavity and is communicated with a second water inlet tube; through the arrangement, the water can be conveniently injected into the heat exchange tube.

Preferably: the other end of the heat exchange tube penetrates through the other side of the first cavity and is communicated with a water outlet pipe; through the arrangement, the moisture in the heat exchange tube is conveniently discharged.

Compared with the prior art, the beneficial effects of the utility model are that: the heat of equipment is transferred through the heat-conducting plate and the heat-conducting sheet, the heat-conducting area is increased, then the moisture inside the second cavity is refrigerated through the refrigerating sheet, the moisture that finishes the cooling through the miniature pump is discharged into the first cavity, thereby the temperature on the surface of the heat-conducting sheet is cooled, finally, the moisture returns to the second cavity through the pipeline, the refrigeration and the extraction are carried out again, thereby the internal circulation work is realized, the device can carry out the cooling work more efficiently and thoroughly, and the working efficiency is improved.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

FIG. 2 is a rear view sectional structure diagram of the present invention;

FIG. 3 is a side view of the cutting structure of the present invention;

fig. 4 is an enlarged schematic view of the structure of the region a in fig. 2 according to the present invention.

In the figure: 1. an internal circulation assembly; 10. a heat conducting plate; 11. a plate body; 12. a first water inlet pipe; 13. a valve; 14. a heat conductive sheet; 15. a micro water pump; 16. a first cavity; 17. a second cavity; 171. a refrigeration plate; 18. a third cavity; 19. a baffle plate; 2. an outer circulation assembly; 20. a heat exchange pipe; 21. a second water inlet pipe; 22. and (5) discharging a water pipe.

Detailed Description

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

Examples

Referring to fig. 1-4, the present invention provides a technical solution: a heat exchanger water-cooling plate capable of being cooled sufficiently comprises an inner circulation assembly 1 and an outer circulation assembly 2;

an external circulation component 2 is arranged in the internal circulation component 1;

the internal circulation component 1 comprises a heat conducting plate 10, a plate body 11, a first water inlet pipe 12, a valve 13, a heat conducting fin 14, a micro water pump 15, a first cavity 16, a second cavity 17, a refrigerating fin 171, a third cavity 18 and a baffle plate 19;

a first cavity 16, a second cavity 17 and a third cavity 18 are respectively formed in the plate body 11, and the first cavity 16 is positioned above the second cavity 17 and the third cavity 18;

a heat conducting plate 10 is embedded in the front surface of the plate body 11, a heat conducting fin 14 is uniformly and integrally formed on one side of the heat conducting plate 10, and one side of the heat conducting fin 14 penetrates through one side of the plate body 11 and is positioned in the first cavity 16;

the first cavity 16 is communicated with the second cavity 17 through a pipeline, and the inner top wall and the inner bottom wall of the second cavity 17 are uniformly adhered with the refrigerating sheets 171.

In this embodiment, specifically: the inner top wall and the inner bottom wall of the second cavity 17 are uniformly and integrally formed with baffle plates 19; through the above arrangement, the speed of the moisture flowing can be slowed down, so that the time for the moisture to contact with the refrigeration sheet 171 is longer, the temperature of the moisture is lowered, and rapid cooling is facilitated.

In this embodiment, specifically: a micro water pump 15 is arranged in the third cavity 18; through the arrangement, the moisture cooled in the second cavity 17 can be extracted, so that the work of internal circulation is realized, and the cooling efficiency is higher.

In this embodiment, specifically: a water inlet of the micro water pump 15 is communicated with the inside of the second cavity 17 through a pipeline, and a water outlet of the micro water pump 15 is communicated with the inner bottom wall of the first cavity 16 through a pipeline; through the arrangement, the moisture after cooling can be extracted and discharged more conveniently, so that the cooling effect is better.

In this embodiment, specifically: a first water inlet pipe 12 is communicated with the center of the upper surface of the first cavity 16, and a valve 13 is arranged on the outer side wall of the first water inlet pipe 12; the water is injected into the first cavity 16 through the first inlet pipe 12, and then the valve 13 is closed, thereby facilitating the internal circulation process of the present device.

In this embodiment, specifically: the external circulation component 2 comprises a heat exchange pipe 20, a second water inlet pipe 21 and a water outlet pipe 22;

the heat exchange tubes 20 are positioned inside the first cavity 16, and the heat exchange tubes 20 are arranged among the heat conducting fins 14 in an S shape; through the above arrangement, when the moisture inside the heat exchange tube 20 flows, the temperature of the moisture around the heat conducting fin 14 can be subjected to heat exchange, so that the heat conducting fin 14 can be subjected to heat dissipation more conveniently, and the heat dissipation efficiency is improved.

In this embodiment, specifically: one end of the heat exchange pipe 20 penetrates through one side of the first cavity 16 and is communicated with a second water inlet pipe 21; through the above arrangement, moisture can be more conveniently injected into the heat exchange tube 20.

In this embodiment, specifically: the other end of the heat exchange tube 20 penetrates through the other side of the first cavity 16 and is communicated with a water outlet tube 22; through the arrangement, the moisture in the heat exchange tube 20 is more conveniently discharged.

In this embodiment: the micro water pump 15 is R40-02.

Working principle or structural principle: when the device is used, firstly, the valve 13 is opened, moisture is injected into the first cavity 16 through the first water inlet pipe 12, after the moisture is filled, the valve 13 is closed, then the heat conducting plate 10 of the device is attached to the surface of equipment needing heat dissipation, then the micro water pump 15 and the refrigerating sheet 171 are started, the moisture in the second cavity 17 is refrigerated through the refrigerating sheet 171, the refrigerated moisture is extracted through the micro water pump 15, then the refrigerated moisture is discharged into the first cavity 16 to cool the heat conducting sheet 14, when the micro water pump 15 extracts the moisture in the second cavity 17, the moisture in the first cavity 16 automatically flows into the second cavity 17, the flowing speed of the moisture can be reduced through the baffle plate 19 in the second cavity 17, so that the time for contacting the moisture with the refrigerating sheet 171 is longer, the water temperature is lower, and the heat conducting sheet 14 is convenient to cool, when micro water pump 15 moves, pour into moisture into to the inside of heat exchange tube 20 through second inlet tube 21, can exchange the heat around the conducting strip 14 through heat exchange tube 20 to make its refrigerated faster, this device can make the more thorough and high-efficient of water-cooling board refrigerated more, improved work efficiency.

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 (8)

1. A heat exchanger water-cooling plate capable of being cooled sufficiently comprises an inner circulation assembly (1) and an outer circulation assembly (2), and is characterized in that:

an external circulation component (2) is arranged in the internal circulation component (1);

the internal circulation component (1) comprises a heat-conducting plate (10), a plate body (11), a first water inlet pipe (12), a valve (13), a heat-conducting fin (14), a micro water pump (15), a first cavity (16), a second cavity (17), a refrigerating fin (171), a third cavity (18) and a baffle plate (19);

a first cavity (16), a second cavity (17) and a third cavity (18) are respectively formed in the plate body (11), and the first cavity (16) is positioned above the second cavity (17) and the third cavity (18);

the heat-conducting plate is characterized in that a heat-conducting plate (10) is embedded in the front surface of the plate body (11), heat-conducting fins (14) are uniformly and integrally formed on one side of the heat-conducting plate (10), and one side of each heat-conducting fin (14) penetrates through one side of the plate body (11) and is located in the first cavity (16);

the first cavity (16) is communicated with the second cavity (17) through a pipeline, and the refrigeration sheets (171) are uniformly adhered to the inner top wall and the inner bottom wall of the second cavity (17).

2. The substantially coolable heat exchanger water-cooled plate of claim 1, wherein: the inner top wall and the inner bottom wall of the second cavity (17) are uniformly and integrally formed with a baffle plate (19).

3. The substantially coolable heat exchanger water-cooled plate of claim 1, wherein: and a micro water pump (15) is arranged in the third cavity (18).

4. The substantially coolable heat exchanger water-cooled plate of claim 3, wherein: the water inlet of the micro water pump (15) is communicated with the inside of the second cavity (17) through a pipeline, and the water outlet of the micro water pump (15) is communicated with the inner bottom wall of the first cavity (16) through a pipeline.

5. The substantially coolable heat exchanger water-cooled plate of claim 1, wherein: the center of the upper surface of the first cavity (16) is communicated with a first water inlet pipe (12), and a valve (13) is installed on the outer side wall of the first water inlet pipe (12).

6. The substantially coolable heat exchanger water-cooled plate of claim 1, wherein: the external circulation component (2) comprises a heat exchange pipe (20), a second water inlet pipe (21) and a water outlet pipe (22);

the heat exchange tubes (20) are located in the first cavity (16), and the heat exchange tubes (20) are arranged among the heat conducting fins (14) in an S shape.

7. The fully coolable heat exchanger water-cooled plate of claim 6, wherein: one end of the heat exchange pipe (20) penetrates through one side of the first cavity (16) and is communicated with a second water inlet pipe (21).

8. The fully coolable heat exchanger water-cooled plate of claim 6, wherein: the other end of the heat exchange tube (20) penetrates through the other side of the first cavity (16) and is communicated with a water outlet tube (22).

Images