CN111578746A

CN111578746A - Spiral vortex-shaped heat dissipation pipe structure for large computer server

Info

Publication number: CN111578746A
Application number: CN202010389249.1A
Authority: CN
Inventors: 不公告发明人
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-10
Filing date: 2020-05-10
Publication date: 2020-08-25

Abstract

The invention discloses a spiral vortex heat radiation pipe structure for a large computer server, which improves the heat radiation area of a single heat radiation pipe and has good heat radiation effect through a spiral vortex double structure, it is characterized in that the bottom connecting seat is an annular seat, the bottom of the bottom connecting seat is provided with a bottom connecting groove, at least three fixed tubes distributed at equal angles are arranged on the bottom connecting seat, one end of the spiral vortex tube is connected with the fixed tube on the bottom connecting seat, and is communicated with the spiral vortex pipe, the other end of the spiral vortex pipe is spirally raised, the top connecting seat is positioned right above the bottom connecting seat, at least three fixed pipes which are distributed at equal angles are arranged at the bottom of the top connecting seat, the bottom of the spiral vortex tube is an inclined plane which forms a conical diversion surface, the other end of the spiral vortex tube is connected with the fixed tube on the top connecting seat, and are communicated with each other, the top connecting seat is an annular seat, and the top of the top connecting seat is provided with a top connecting groove.

Description

Spiral vortex-shaped heat dissipation pipe structure for large computer server

Technical Field

The invention discloses a spiral vortex-shaped heat dissipation pipe structure for a large-scale computer server, relates to a heat dissipation pipe structure used on a large-scale extreme and server, and belongs to the field of computer equipment. In particular to a radiating pipe structure which improves the radiating area of a single radiating pipe and has good radiating effect by a spiral and vortex double structure.

Background

It possesses the high-speed data computation processing ability that has, and a large amount of data computation make the server need be equipped with good heat dissipation mechanism, in order to guarantee that the server does not receive the temperature influence and produce the excess temperature overload, general large-scale computer server carries out the heat dissipation fast through radiator fan cooperation water-cooling tube, and current cooling tube only carries out thermal heat dissipation exchange through its pipe form outward appearance when dispelling the heat, the heat radiating area of single cooling tube is limited, therefore need improve heat radiating area and efficiency wholly through increasing the cooling tube quantity, this shunt that leads to radiating easily is many, the liquid resistance is big, and need occupy great heat dissipation space.

Publication No. CN208968317U discloses a microchannel heat pipe, comprising: a first heat dissipation duct; a second heat dissipation duct; a third heat dissipation duct; the first flow outlet on the first heat dissipation pipe is communicated with the second flow inlet on the adjacent second heat dissipation pipe, the second flow outlet on the second heat dissipation pipe is communicated with the third flow inlet on the adjacent third heat dissipation pipe, and the first flow inlet on the second heat dissipation pipe is communicated with the second flow outlet on the adjacent second heat dissipation pipe, so that a medium flows in from the first flow inlet and flows out from the third flow outlet.

Disclosure of Invention

In order to improve the situation, the spiral vortex-shaped heat dissipation pipe structure for the large-scale computer server provided by the invention has the advantages that the heat dissipation area of a single heat dissipation pipe is increased through a spiral vortex double structure, and the heat dissipation effect is good.

The invention relates to a spiral vortex-shaped heat radiation pipe structure for a large-scale computer server, which is realized by the following steps: the invention relates to a spiral vortex-shaped heat radiation pipe structure for a large-scale computer server, which consists of a top connection seat, a fixed mount, a spiral vortex pipe, a fixed pipe, a bottom connection seat, a liquid inlet hole, a fixed circular groove, a heat radiation vortex channel, a liquid channel and a conical flow guide surface, wherein the bottom connection seat is an annular seat, the bottom of the bottom connection seat is provided with a bottom connection groove, at least three fixed pipes which are distributed at equal angles are arranged on the bottom connection seat, one end of the spiral vortex pipe is connected and communicated with the fixed pipe on the bottom connection seat, the other end of the spiral vortex pipe rises spirally, the top connection seat is positioned right above the bottom connection seat, the bottom of the top connection seat is provided with at least three fixed pipes which are distributed at equal angles, the bottom of the top connection seat is an inclined plane-shaped conical flow guide surface, the other end of the spiral vortex pipe is connected and communicated with the, the top connecting seat is provided with a top connecting groove at the top, the spiral vortex tube is communicated with the top connecting groove, the spiral vortex tube is communicated with a bottom connecting groove, a vortex plate is arranged in the spiral vortex tube, two ends of the vortex plate are respectively connected with two fixed tubes, a liquid channel is formed between two adjacent layers of the vortex plate, a cavity is arranged in the vortex plate to form a heat dissipation vortex channel, the heat dissipation vortex channel is open, the heat dissipation vortex channel and the liquid channel are staggered, at least two fixed frames are arranged in the top connecting seat at equal angles, at least two fixed frames are arranged in the bottom connecting seat at equal angles, the fixed frames are L-shaped frames, fixed circular grooves are arranged on the fixed frames, the end surfaces of the fixed tubes are inclined conical flow guide surfaces, a sealing gasket is arranged on the top connecting seat, a sealing gasket is arranged on the bottom connecting seat, and the liquid channel is raised outwards to form convex points, the spiral directions of two adjacent spiral vortex pipes are opposite, the opening of the heat dissipation vortex channel faces downwards, the opening of the heat dissipation vortex channel is wide, the fan is arranged on the bottom connecting seat, and the spiral vortex pipes are made of copper materials.

Has the beneficial effects.

Firstly, the heat dissipation area of a single heat dissipation pipe can be obviously improved in a fixed space through a spiral and vortex double structure, so that the heat dissipation efficiency of the heat dissipation pipe is improved.

And secondly, the space utilization rate is improved, and the limitation of the using area of the device is reduced.

And thirdly, the shunt is reduced, and the liquid resistance is small.

Drawings

Fig. 1 is a perspective view of a spiral scroll-shaped heat sink structure for a large-scale computer server according to the present invention.

FIG. 2 is a top view of a spiral scroll heat sink structure for a mainframe computer server according to the present invention.

FIG. 3 is a schematic structural diagram of a spiral scroll heat sink structure for a server of a mainframe computer according to the present invention.

FIG. 4 is a schematic view of a fixing tube of a spiral heat dissipation tube for a server of a mainframe computer according to the present invention.

In the attached drawings

Wherein the method comprises the following steps: the device comprises a top connecting seat (1), a fixing frame (2), a spiral vortex tube (3), a fixing tube (4), a bottom connecting seat (5), a liquid inlet hole (6), a fixing circular groove (7), a heat dissipation vortex channel (8), a liquid channel (9) and a conical flow guide surface (10).

The specific implementation mode is as follows:

the invention relates to a spiral vortex-shaped heat radiation pipe structure for a large-scale computer server, which is realized by the following steps: the invention relates to a spiral heat radiation pipe structure for a large-scale computer server, which consists of a top connecting seat (1), a fixed frame (2), a spiral vortex pipe (3), a fixed pipe (4), a bottom connecting seat (5), a liquid inlet hole (6), a fixed circular groove (7), a heat radiation vortex channel (8), a liquid channel (9) and a conical flow guide surface (10), wherein the bottom connecting seat (5) is an annular seat, the bottom of the bottom connecting seat (5) is provided with a bottom connecting groove, the bottom connecting seat (5) is provided with at least three fixed pipes (4) which are distributed at equal angles, one end of the spiral vortex pipe (3) is connected and communicated with the fixed pipe (4) on the bottom connecting seat (5), the other end of the spiral vortex pipe (3) rises spirally, the top connecting seat (1) is positioned right above the bottom connecting seat (5), the bottom of the top connecting seat (1) is provided with at least three fixed pipes (4) which are distributed at equal angles, the bottom of the spiral vortex tube is an inclined plane-shaped conical diversion surface (10), the other end of the spiral vortex tube (3) is connected and communicated with a fixed tube (4) on a top connecting seat (1), the top connecting seat (1) is an annular seat, a top connecting groove is formed in the top of the top connecting seat (1), the spiral vortex tube (3) is communicated with the top connecting groove, the spiral vortex tube (3) is communicated with a bottom connecting groove, a vortex plate is arranged in the spiral vortex tube (3), two ends of the vortex plate are respectively connected with two fixed tubes (4), a liquid channel (9) is formed between two adjacent layers of the vortex plates, a cavity is arranged in the vortex plate to form a heat dissipation vortex channel (8), the heat dissipation vortex channel (8) is open, the heat dissipation vortex channel (8) is staggered with the liquid channel (9), at least two fixing frames (2) are arranged in the top connecting seat (1) at equal angles, the bottom connecting seat (5) is internally provided with at least two fixing frames (2) at equal angles, the fixing frames (2) are L-shaped frames, the fixing frames (2) are provided with fixing circular grooves (7), the end surfaces of the fixing pipes (4) are inclined planes to form conical diversion surfaces (10), a sealing gasket is arranged on the top connecting seat (1), the bottom connecting seat (5) is provided with a sealing gasket, the liquid channel (9) is arched outwards to form convex points, the rotating directions of two adjacent spiral vortex pipes (3) are opposite, the opening of the heat dissipation vortex pipe (8) faces downwards, the opening of the heat dissipation vortex pipe (8) is wide, the bottom connecting seat (5) is provided with a fan, and the spiral vortex pipes (3) are made of copper materials;

when the cooling device is used, a person firstly connects the top connecting seat (1) and the bottom connecting seat (5) with a water cooling system on a computer respectively and is matched and fixed with a bolt through the fixing frame (2) to complete installation, condensate enters a top connecting groove of the top connecting seat (1), then enters a liquid channel (9) in the spiral vortex tube (3) from one end of the spiral vortex tube and spirally flows to the bottom fixing seat downwards, meanwhile, hot air flows enter from an opening of the heat dissipation vortex channel (8) and rotatably enters the deep part of the heat dissipation vortex channel (8), and the condensate in the liquid channel (9) is cooled in the heat dissipation vortex channel (8), so that the gas heat dissipation area is large, the heat dissipation efficiency is enhanced, the space utilization rate is improved, and the limitation of the using area of the device is reduced;

the sealing gasket is arranged on the top connecting seat (1), and the sealing gasket is arranged on the bottom connecting seat (5), so that the sealing performance of the connection with a water cooling system is good, and the influence of condensate leakage on the heat dissipation effect is avoided;

the liquid channel (9) is arched outwards to form a convex point design, so that the contact area between the liquid channel (9) and the heat dissipation vortex channel (8) is increased, and the heat dissipation effect is enhanced;

the two adjacent spiral vortex pipes (3) are designed to be opposite in rotation direction, so that the two adjacent spiral vortex pipes (3) can be embedded into each other, the placing number of the spiral vortex pipes (3) can be increased, and different use requirements can be met;

the design that the opening of the heat dissipation vortex channel (8) is downward is convenient for the ascending hot air flow to enter and the descending cold air flow to be discharged, and the heat exchange is convenient;

the design that the opening of the heat dissipation vortex channel (8) is wide is convenient for gas exchange, and the heat dissipation efficiency is high;

the design of the fan is arranged on the bottom connecting seat (5), so that the air can be assisted to flow into the heat dissipation vortex channel (8) for cooling, and the heat dissipation effect is good;

the end surface of the fixed pipe (4) is designed into a conical diversion surface (10) with an inclined surface, so that the downward-flowing condensed water generated by heat exchange during heat dissipation can be guided;

the spiral vortex tube (3) is made of copper materials, so that the heat conduction effect is good, and the heat dissipation efficiency is high;

the spiral vortex tube (3) and the liquid channel (9) are matched, and the heat dissipation area of a single heat dissipation tube is obviously increased in a fixed space through a spiral vortex double structure, so that the heat dissipation efficiency of the heat dissipation tube is improved;

the liquid channel (9) and the heat dissipation vortex channel (8) are matched, so that liquid shunting is reduced, the liquid resistance is low, and the heat dissipation efficiency is high;

the condensate enters the liquid channel (9) in the spiral vortex tube (3) from one end of the spiral vortex tube and flows downwards in a spiral way, so that the gas heat dissipation area is large, the heat dissipation efficiency is enhanced, the space utilization rate is improved, and the limitation of the using area of the device is reduced;

the design that hot air flow enters from the opening of the heat dissipation vortex channel (8) and rotates to enter the deep part of the heat dissipation vortex channel (8) reduces liquid shunting, has small liquid resistance, large gas heat dissipation area and high heat dissipation efficiency;

the spiral vortex double-structure radiating area of the single radiating pipe is improved, and the radiating effect is good.

Claims

1. The utility model provides a large-scale computer server is with spiral vortex form heat-dissipating tube structure which characterized by: the spiral vortex tube heat exchanger comprises a top connecting seat, a fixing frame, a spiral vortex tube, a fixing tube, a bottom connecting seat, a liquid inlet hole, a fixing circular groove, a heat dissipation vortex channel, a liquid channel and a conical diversion surface, wherein the bottom connecting seat is an annular seat, the bottom of the bottom connecting seat is provided with a bottom connection groove, the bottom connecting seat is provided with at least three fixing tubes which are distributed at equal angles, one end of the spiral vortex tube is connected with and communicated with the fixing tube on the bottom connecting seat, the other end of the spiral vortex tube rises spirally, the top connecting seat is positioned right above the bottom connecting seat, the bottom of the top connecting seat is provided with at least three fixing tubes which are distributed at equal angles, the bottom of the top connecting seat is an inclined plane and is a conical diversion surface, the other end of the spiral vortex tube is connected with and communicated with the fixing tube on the top connecting seat, the top connecting seat is an annular seat, the top of, the spiral vortex tube is communicated with the bottom connecting groove, a vortex plate is arranged in the spiral vortex tube, two ends of the vortex plate are respectively connected with the two fixing tubes, a liquid channel is formed between two adjacent layers of the vortex plate, a cavity is arranged in the vortex plate to form a heat dissipation vortex channel, the heat dissipation vortex channel and the liquid channel are staggered, at least two fixing frames are arranged in the top connecting seat at equal angles, at least two fixing frames are arranged in the bottom connecting seat at equal angles, the end surface of each fixing tube is an inclined plane-shaped conical flow guide surface, and a fan is arranged on the bottom connecting seat.

2. The spiral heat pipe structure of claim 1, wherein the spiral pipe and the liquid channel are designed to be matched to each other, so that the heat dissipation area of a single heat pipe is substantially increased in a fixed space by the spiral and swirl structure.

3. The spiral heat sink tube structure for large computer server as claimed in claim 1, wherein the design of the condensate entering into the liquid channel inside the spiral heat sink tube from one end of the spiral heat sink tube and flowing downwards spirally has a large gas heat dissipation area, and the design of the hot air entering from the opening of the heat sink scroll and rotating to the deep part of the heat sink scroll reduces the liquid diversion, and has a small liquid resistance and a large gas heat dissipation area.

4. The spiral scroll-shaped heat sink structure for a large computer server as claimed in claim 1, wherein the fixing frame is an L-shaped frame, and the fixing frame is formed with a fixing circular groove.

5. The spiral heat sink structure for a large computer server as claimed in claim 1, wherein the liquid channel is outwardly curved to form a convex point, and two adjacent spiral pipes are oppositely curved.

6. The spiral scroll-shaped heat sink structure for a mainframe computer server as claimed in claim 1, wherein said heat sink scroll is open.

7. The spiral scroll-shaped heat sink structure for a mainframe computer server as claimed in claim 6, wherein said heat sink scroll is open downward and said heat sink scroll is open wide.

8. The spiral heat sink tube structure for a large computer server as claimed in claim 7, wherein the spiral tube is made of a copper material.