CN212211787U - Efficient heat dissipation device for cloud computing server - Google Patents

Abstract

The utility model relates to the technical field of heat dissipation devices, in particular to a high-efficiency heat dissipation device for a cloud computing server, which comprises a water tank, a heat dissipation plate, a support rod, a connecting rod and a water pipe; the lower plate surface of the heat dissipation plate is flush with the lower end surface of the water tank, a water flow channel is arranged in the heat dissipation plate, the water inlet end of the water flow channel is communicated with the water inlet on the water tank, the water outlet end of the water flow channel is communicated with the inside of the water tank, and the other end surface of the adjacent heat dissipation plate is connected through a connecting rod; the cooling water is at the in-process of the water current in-channel of flow distribution board, and the cooling water carries out cold and hot exchange with the heat that the heating panel absorbed cloud server for the heating panel keeps the temperature of certain interval, thereby the heating panel incessantly absorbs the heat that cloud server gived off, and the specific surface area of louvre and heat dissipation strip increase heating panel simultaneously, thereby has increased the heat absorption efficiency of heating panel to cloud server.

Description

Efficient heat dissipation device for cloud computing server

Technical Field

The utility model relates to a heat abstractor technical field especially relates to a high-efficient heat abstractor for cloud computing server.

Background

With the rapid development of internet technology and computer technology, cloud computing technology has come into existence, which is a technology that can change the way in which people acquire, process and store information by transferring the processing process of data from a personal computer or a server to a large-scale cloud computing center and providing the computing power and storage power to users in a service way by using the transmission capability of high-speed internet, and the cloud computing server performs a large amount of operations and processes to generate a large amount of heat, especially a CPU part and a memory bank part, so the operating efficiency and the service life of the server can be directly affected by the quality of the heat dissipation effect.

Disclosure of Invention

The utility model provides a problem lie in providing a high-efficient heat abstractor for cloud computing server, through placing the cloud ware between two adjacent heating panels, circulation cooling water in the rivers passageway in the heating panel, the cooling water in time carries out cold and hot exchange with absorptive heat on the heating panel, cools down the processing to the cloud ware.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a high-efficiency heat dissipation device for a cloud computing server comprises a water tank, a heat dissipation plate, a support rod, a connecting rod and a water pipe; the adjacent water tanks are connected through a support rod, the upper end surfaces of the water tanks are connected with one end of the support rod, the lower end surfaces of the water tanks are connected with the other end of the support rod, the adjacent water tanks are communicated through water pipes, the water pipe connecting position of the upper end surfaces of the water tanks is a water outlet, the water pipe connecting position of the lower end surfaces of the water tanks is a water inlet, and the side wall surfaces of the water tanks are fixedly; the lower plate surface of the heat dissipation plate is flush with the lower end surface of the water tank, a water flow channel is formed in the heat dissipation plate, the water inlet end of the water flow channel is communicated with the water inlet in the water tank, the water outlet end of the water flow channel is communicated with the interior of the water tank, and the other end surface of the adjacent heat dissipation plate is connected through a connecting rod.

Preferably, the other end surface of the heat dissipation plate is provided with a sliding groove, an extension plate is arranged in the sliding groove, and the extension plate is connected in the sliding groove in a sliding manner.

Preferably, a plurality of heat dissipation holes are uniformly formed in the heat dissipation plate, and each heat dissipation hole does not penetrate through the water flow channel.

Preferably, the upper plate surface and the lower plate surface of each heat dissipation plate are uniformly provided with a plurality of rows of heat dissipation strips.

Preferably, a first hole is symmetrically formed in the lower end face of each water tank and is not communicated with the interior of the water tank, one end of the supporting rod is in clearance fit with the first hole, a first threaded hole is symmetrically formed in the upper end face of the water tank and is not communicated with the interior of the water tank, and the other end of the supporting rod is in threaded connection with the first threaded hole.

Preferably, every No. two holes are opened to the lower plate face of the other end of heating panel, No. two downthehole clearance fit connecting rod's one end, and No. two screw holes are opened to the last face of the other end of heating panel, and No. two screw hole threaded connection connecting rod's the other end.

The utility model has the advantages that:

the utility model discloses in, the cooling water is at the rivers in-process in the heating panel that flows through, and the cooling water carries out cold and hot exchange with the heat that the heating panel absorbed cloud ware for the heating panel keeps the temperature of certain interval, thereby the heating panel incessantly absorbs the heat that cloud ware gived off, and the specific surface area of louvre and heat dissipation strip increase heating panel has simultaneously increased the heat absorption efficiency of heating panel to cloud ware.

The heat dissipation hole and the heat dissipation strip can reduce the sound decibel that cloud server during operation produced, and sound is reflected on heat dissipation hole and heat dissipation strip many times, reduces cloud server's noise gradually to and draw out in the extension board spout, can hold the area on the increase heating panel on the one hand, and on the other hand increases the effective heat absorption area of heating panel, then better absorption cloud server during operation the heat that gives off.

Drawings

Fig. 1 is a perspective view of an efficient heat dissipation device for a cloud computing server according to the present invention;

FIG. 2 is a block diagram of a water flow passage;

fig. 3 is a cross-sectional view of an efficient heat dissipation device for a cloud computing server according to the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3 at A;

FIG. 5 is an enlarged view of a portion of FIG. 3 at B;

FIG. 6 is an enlarged view of a portion of FIG. 3 at C;

illustration of the drawings: the water tank comprises a water tank 1, a first hole 11, a first threaded hole 12, a heat dissipation plate 2, a water flow channel 21, a water inlet end 211, a water outlet end 212, an extension plate 221, a sliding groove 22, a heat dissipation hole 23, a heat dissipation strip 24, a support rod 3, a connecting rod 4, a water pipe 5, a second hole 24 and a second threaded hole 25.

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 of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Specific examples are given below.

Referring to fig. 1 to 6, an efficient heat dissipation device for a cloud computing server includes a water tank 1, a heat dissipation plate 2, a support rod 3, a connection rod 4, and a water pipe 5; the adjacent water tanks 1 are connected through a support rod 3, the upper end face of each water tank 1 is connected with one end of the support rod 3, the lower end face of each water tank 1 is connected with the other end of the support rod 3, the adjacent water tanks 1 are communicated through water pipes 5, the connection position of the water pipes 5 on the upper end face of each water tank 1 is a water outlet, the connection position of the water pipes 5 on the lower end face of each water tank 1 is a water inlet, and the side wall face of each water; the lower plate surface of the heat dissipation plate 2 is flush with the lower end surface of the water tank 1, a water flow channel 21 is formed in the heat dissipation plate 2, the water inlet end 211 of the water flow channel 21 is communicated with the water inlet on the water tank 1, the water outlet end 212 of the water flow channel 21 is communicated with the inside of the water tank 1, and the other end surface of the adjacent heat dissipation plate 2 is connected through a connecting rod 4.

The other end surface of the heat dissipation plate 2 is provided with a sliding groove 22, an extension plate 221 is arranged in the sliding groove 22, and the extension plate 221 is slidably connected in the sliding groove 22.

A plurality of heat dissipation holes 23 are uniformly formed in the heat dissipation plate 2, and each heat dissipation hole 23 does not penetrate through the water flow channel 21.

As an embodiment of the present invention, a plurality of rows of heat dissipation strips 24 are uniformly disposed on the upper plate surface and the lower plate surface of each heat dissipation plate 2; when the heat dissipation plate 2 works, the cloud servers are placed on the heat dissipation plate 2, and the connecting wires between the adjacent cloud servers can penetrate through the heat dissipation holes 23; cooling water is introduced into an upper water inlet of the water tank 1, the cooling water flows into the water flow channel 21 from a water inlet end 211 of the water flow channel 21, then the water flow channel 21 is filled with the cooling water, then the cooling water enters the water tank 1 from a water outlet end 212 of the water flow channel 21, after the water tank 1 is filled with the cooling water, the cooling water flows into a pipeline from a water outlet of the water tank 1, and then the cooling water enters an upper water tank 1 from a water inlet of a lower water tank 1; in-process in the rivers passageway 21 in the cooling water is at flow distribution board 2, the cooling water carries out cold and hot exchange with the heat that heating panel 2 absorbed the cloud ware, make heating panel 2 keep the temperature of certain interval, thereby heating panel 2 incessantly absorbs the heat that the cloud ware gived off, louvre 23 and heat dissipation strip 24 increase heating panel 2's specific surface area simultaneously, thereby heating panel 2 has been increased to the endothermic efficiency of cloud ware, louvre 23 and heat dissipation strip 24 can reduce the sound decibel that the cloud ware during operation produced simultaneously, sound is through reflecting on louvre 23 and heat dissipation strip 24 many times, reduce the noise of cloud ware gradually, and extract in the extension board 221 spout 22, can hold the area on the one hand increase heating panel 2, on the other hand increase heating panel 2's effective heat absorption area, then better absorb the heat that the cloud ware during operation gived off.

Every the lower terminal surface symmetry of water tank 1 is seted up No. one hole 11, and No. one hole 11 does not communicate the water tank 1 inside, and No. one hole 11 internal clearance fit bracing piece 3 one end, and No. one screw hole 12 is seted up to the up end symmetry of water tank 1, and No. one screw hole 12 does not communicate with the water tank 1 is inside, and the other end of a screw hole 12 threaded connection bracing piece 3.

As an embodiment of the present invention, a second hole 24 is formed on the lower plate surface of the other end of each heat dissipation plate 2, one end of the connecting rod 4 is in clearance fit in the second hole 24, a second threaded hole 25 is formed on the upper plate surface of the other end of the heat dissipation plate 2, and the second threaded hole 25 is in threaded connection with the other end of the connecting rod 4; during operation, the size and dimension of cloud ware are not unified, and for heating panel 2 board places different cloud ware, through swivelling joint pole 3 and connecting rod 4, adjust the distance between adjacent heating panel 2, increase or reduce the space between adjacent heating panel 2, the less cloud ware of relative volume reduces the distance between adjacent heating panel 2, reduces heat abstractor's occupation space.

The working principle is as follows: placing the cloud servers on the heat dissipation plate 2, wherein the connecting wires between the adjacent cloud servers can pass through the heat dissipation holes 23; cooling water sequentially flows through a pipeline at the lower end of the water tank 1, a water flow channel 21 in the heat dissipation plate 2, the inside of the water tank 1, a pipeline at the upper end of the water tank 1 and the adjacent water tank 1 above; in the process that the cooling water flows through the water flow channel 21 in the heat dissipation plate 2, the cooling water and the heat dissipation plate 2 absorb the heat of the cloud server to perform heat exchange, so that the heat dissipation plate 2 keeps the temperature in a certain range, the heat dissipation plate 2 continuously absorbs the heat dissipated by the cloud server, and meanwhile, the heat dissipation holes 23 and the heat dissipation strips 24 increase the specific surface area of the heat dissipation plate 2, thereby increasing the heat absorption efficiency of the heat dissipation plate 2 to the cloud server.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. A high-efficiency heat dissipation device for a cloud computing server is characterized by comprising a water tank, a heat dissipation plate, a support rod, a connecting rod and a water pipe; the adjacent water tanks are connected through a support rod, the upper end surfaces of the water tanks are connected with one end of the support rod, the lower end surfaces of the water tanks are connected with the other end of the support rod, the adjacent water tanks are communicated through water pipes, the water pipe connecting position of the upper end surfaces of the water tanks is a water outlet, the water pipe connecting position of the lower end surfaces of the water tanks is a water inlet, and the side wall surfaces of the water tanks are fixedly; the lower plate surface of the heat dissipation plate is flush with the lower end surface of the water tank, a water flow channel is formed in the heat dissipation plate, the water inlet end of the water flow channel is communicated with the water inlet in the water tank, the water outlet end of the water flow channel is communicated with the interior of the water tank, and the other end surface of the adjacent heat dissipation plate is connected through a connecting rod.

2. The efficient heat dissipation device for the cloud computing server as claimed in claim 1, wherein a sliding groove is formed in the other end surface of the heat dissipation plate, an extension plate is disposed in the sliding groove, and the extension plate is slidably connected in the sliding groove.

3. The efficient heat dissipation device for cloud computing servers of claim 2, wherein the heat dissipation plate has a plurality of heat dissipation holes uniformly formed therein, and each heat dissipation hole does not penetrate through the water flow channel.

4. The efficient heat dissipation device for the cloud computing server as claimed in claim 3, wherein the upper plate surface and the lower plate surface of each heat dissipation plate are uniformly provided with a plurality of rows of heat dissipation strips.

5. The efficient heat dissipation device for the cloud computing server of claim 1, wherein the lower end face of each water tank is symmetrically provided with a first hole, the first hole is not communicated with the inside of the water tank, one end of the support rod is in clearance fit with the first hole, the upper end face of the water tank is symmetrically provided with a first threaded hole, the first threaded hole is not communicated with the inside of the water tank, and the first threaded hole is in threaded connection with the other end of the support rod.

6. The efficient heat dissipation device for the cloud computing server as recited in claim 4, wherein a second hole is formed in a lower plate surface of the other end of each heat dissipation plate, one end of the connecting rod is in clearance fit in the second hole, a second threaded hole is formed in an upper plate surface of the other end of each heat dissipation plate, and the second threaded hole is in threaded connection with the other end of the connecting rod.

Images