WO2019032080A1

WO2019032080A1 - Cooling device

Info

Publication number: WO2019032080A1
Application number: PCT/UA2018/000086
Authority: WO
Inventors: Сергей Сергеевич ТОВАРНИЦКИЙ
Original assignee: Сергей Сергеевич ТОВАРНИЦКИЙ
Priority date: 2017-08-11
Filing date: 2018-07-31
Publication date: 2019-02-14

Abstract

A device for cooling computing devices that is made in the form of a surface having a ventilation opening of arbitrary shape. A computing device is mounted directly on the surface of the cooling device so that the computing device intakes cold air for cooling purposes from one side of the surface by means of the convective movement of a heat transfer agent and by means of heat transfer agent propulsors in the form of fans of the computing device. A stream of cold air passes through the ventilation opening to the heat transfer agent of the computing device, cools same, and hot air is expelled out the other side of the surface. The cooling device allows greater cooling efficiency by separating the streams of cold and hot air, which significantly reduces or eliminates the effect of mixing of the air streams.

Description

Cooling device

TECHNICAL FIELD

The invention relates to the field of computing in general, and to cooling devices in particular, with the result that can be used in the design and manufacture of computers, servers, information processing systems, the manufacture of components for them and in other industries.

PRIOR ART

At the present time, computer technology is developing very rapidly. Most electronic devices, which are used both in computers, servers, and independently, during normal operation emit a certain amount of heat. With increasing power of computer systems, the amount of heat that devices and computer modules emit is rapidly growing. This trend is a problem both at the device or module level and at the system level. Excess temperature leads to instability, malfunctioning or even failure of devices and in some cases their failure.

Also, with the development, some information processing technologies, such as mining cryptocurrencies, for example, need to simultaneously use many devices at the same time, such as video cards, which are usually located in the same package. In such cases, the problem becomes even more acute, because in order to increase the efficiency of information processing, devices are used at capacities close to the maximum, which leads to the release of large amounts of heat.

Hereinafter, the terms computing device, electronic device, means information processing devices that contain a graphics processor — video cards, central processors, memory modules, information storage modules, and other information processing modules, both in computers and servers and those that can be used separately.

Modern computing devices, such as graphic adapters (video cards), processors, memory modules, etc., contain

SUBSTITUTE SHEET (RULE 26) integrated circuits - chips, and other parts that produce a fairly large amount of heat during normal operation. The largest number of emit chips and usually their surface is not enough to utilize the heat generated by them. In such cases, heat-removing elements are installed on the chip - radiators that are made from materials with high thermal conductivity - aluminum, for example. To improve heat dissipation, a radiator can have many fins through which air passes for cooling. The presence of fins significantly increases the area of cooling, but this is not enough in the current environment, when the power of computing devices is constantly growing. In such cases, a fan is installed on the radiator, which acts as a propeller of the cooling medium — air. Under the condition of a constant cooling area, an increase in the velocity of the coolant, air, again makes it possible to significantly increase the cooling efficiency of the device.

But under conditions of a total increase in the power of all electronic devices and, if necessary, to use them at high or maximum power, there comes a time when the use of both the radiator and the fan becomes insufficient and the device becomes too hot or overheated and stops working.

Close to the claimed invention is the case for the PC1-e devices (electronic resource https://www.akitio.com/expansion/thunder2-pcie- hox).

The disadvantage of the aforementioned devices is that the use of electronic components, in particular video cards, which emit part or all of the air that is used for cooling, into the body in which they are located, and from there take away the air for cooling under high or maximum loads on the video card quite problematic, and with the use of more than one video card in one package, it is sometimes impossible at all due to the large or excessive heating of graphics processors and other parts in ideo card or electronic component. This happens due to the fact that inside there is an intensive mixing of the cooling air flow even with active ventilation of the entire body, therefore, as a result, not only the air collected from the outside, but also part of the heated air is used to cool the electronic devices.

In most cases, excessive heating occurs due to a general local increase in temperature around the device. Most often this happens when the devices are in the same package, but this effect

SUBSTITUTE SHEET (RULE 26) sometimes observed even when devices operate separately in open space.

The essence of this effect is as follows. With an increase in the velocity of the coolant - air, the intensity of mixing of air flows increases, when air comes in contact with the elements of the cooling system and the computer case, turbulence is generated, due to which air flows are mixed even more intensively. In a closed case, it is almost impossible to avoid mixing the air flow, which is directed to the cooling and the heated air flow between them. It is often impossible to avoid such an effect in open space, as usually the ejection of heated air does not occur, but in a chaotic manner, under the influence of turbulence, as a result of which in the nearest space of the computing device there is also an active mixing of cold and heated air flows between them. This effect is greatly enhanced by placing several powerful devices nearby, for example, several video cards, even in open space.

The basis of the claimed invention is the task of developing a device that will more efficiently cool video cards and other electronic components and, as a result, make them more stable, save resources, lower the temperature of the chips (graphics processor, etc.) and the component as a whole, and in some cases will make the computing device work as such.

DISCLOSURE OF INVENTION

The problem is solved using a device for cooling computing devices, which is made in the form of a flat or arbitrary surface with an arbitrary-shaped vent hole, according to which at least one computing device is mounted on the surface in such a way that the flow of cold air moving on one side of the surface due to the convection movement of the coolant, and due to the coolant propellants, which are installed on the computing device through the ventilation the hole gets on the heating element of the computing device, cools it and then goes to the other side of the surface, according to which at least one computing device is mounted on the surface in such a way that the flow of cold air moving from one side of the surface due to the convection movement of the heat carrier and the account of the coolant propulsion, which is installed on the computing device, and at the expense of at least one heat carrier propulsion, which is installed

SUBSTITUTE SHEET (RULE 26) on the surface or the vent hole, through the vent hole gets on the heating element of the computing device, cools it and then leaves through at least one coolant propeller that is installed on the surface or the vent hole on the other side of the surface, according to which at least one computing device in such a way that the flow of cold air, moving on one side of the surface due to the convection movement of the heat carrier For, and at the expense of coolant propellants, which are installed on the computing device, through the limiting surface and the vent hole gets onto the heating element of the computing device, it cools it and then goes through the limiting surface to the other side of the surface device in such a way that the flow of cold air, moving on one side of the surface through the duct, due to the convection motion of the heat the carrier, and at the expense of the coolant propellants, which are installed on the computing device, through the vent hole gets on the heating element of the computing device, cools it and then goes through the air duct to the other side of the surface.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the drawings are given, by which the essence of the claimed invention is explained.

FIG. 1 Schematic view of the cooling device, top view. FIG. 2 Schematic view of the cooling device, bottom view.

FIG. 3 Schematic diagram of the operation of the device for cooling, option 1

FIG. 4 Schematic diagram of the operation of the device for cooling, option 2

BEST MODE FOR CARRYING OUT THE INVENTION

A modern computing device, for example, a video card 13 (FIG. 2), has in itself (FIG. 4) a circuit board 1 on which components are located, chips, in particular, a graphics processor 2, on top of a processor that is a heat source, usually a diffuser is mounted heat - radiator 3, which can have many fins. To improve efficiency, at least one fan 4 is additionally mounted on the radiator, which is mounted on the lid 5. Also, the separating surface b has a ventilation hole 7

SUBSTITUTE SHEET (RULE 26) through which the cold air 8 passes through the duct 11, the fan 10 and the bounding surface 12 is heated, and the heated air 9 falls on the other side of the surface.

In option 1, in order to improve and increase the cooling efficiency according to the proposed invention, the computing device 13 is placed directly on or below the surface 6 (FIG. 1, FIG. 2) in such a way that the cold air is drawn from the computing device for cooling from one side of the surface b, and the output of heated air is carried out on the other side of the surface.

It can be seen (Fig. 3) that the flow of cold air 8 through the vent hole 7 in the surface b through the hole in the lid 5 of the electronic device enters the radiator 3, accelerating at the same time by the coolant propeller - a fan in the computing device. Next, removing heat from the radiator 3, the air is heated, after which the heated air 9 leaving the device limits falls on the other side of the surface 6.

The proposed design allows you to significantly separate the air flow, which in turn leads to a significant reduction or disappearance of the effect of mixing air flow, resulting in increased cooling efficiency of the computing device.

In option 2 (Fig. 4), at least from one side directly onto the surface 6, or to the vent 7, or to the computing device, which is placed on the surface 6, can be mounted together or in different versions and in different order , and bounding surfaces in such a way as to vent or inject air to the air vent 7 or computing device.

It can be seen (Fig. 4), if we consider simultaneously the bounding surface, the duct and the coolant propeller - a fan, that the flow of cold air 8 passes through the duct 11, then accelerated by the fan 10, after which through the limiting surface 12 enters the vent hole 7 surface 6, and through the hole in the lid 5 of the electronic device, enters the radiator 3, accelerating while the coolant propeller - fan 4 in the computing device, then, removing heat from the radiator 3 pa air is heated and the heated air leaving 9 falls outside the device to the other side surface 6.

The proposed design due to the use of additional air ducts and coolant propulsives allows to increase

SUBSTITUTE SHEET (RULE 26) cooling efficiency compared to option 1, because it increases the speed of the coolant and allows you to take in cold air and emit heated at arbitrary points in space, thereby minimizing or making it impossible the effect of mixing flows.

From the above options it is clear that the use of air ducts, fans and limiting surfaces can occur in different ways, while the air duct can be installed on the vent hole or limiting surface, and in the absence of a fan between them, and the fan, in turn, can be installed at either end duct, and in other versions.

It is also clear that when using several computing devices at the same time, they can be mounted simultaneously on the same plane, each limiting plane, fan or duct can simultaneously serve any number of devices by mounting and splitting or combining its functions for a certain number of devices.

This invention has been described in its preferred forms and in various examples with a certain degree of certainty, it is clear that the above disclosure of preferred forms and various examples can be changed in the details of the design, and the scope of the invention is defined by the claims, which are attached.

Consequently, when the cooling process is noted, the flow of cold and heated air is separated.

Thus, this invention allows to significantly increase the cooling efficiency of computing devices, and in some cases even create an opportunity for their use.

SUBSTITUTE SHEET (RULE 26)

Claims

FORMULA

A device for cooling computing devices, which is made in the form of a flat or arbitrary surface with an arbitrary shaped vent hole, characterized in that at least one computing device is mounted on the surface in such a way that a stream of cold air moving on one side of the surface due to convection coolant movement, and at the expense of coolant propulsion, which are installed on the computing device through the vent hole gets to the heating element calculation unit, and further cools it appears on the other side surface.

The device according to claim 1, characterized in that at least one computing device is mounted on the surface in such a way that the flow of cold air, moving on one side of the surface due to the convection movement of the heat carrier, and due to the heat carrier propellers that are installed on the computing device, and due to at least one coolant propulsion unit, which is installed on a surface or a vent hole, through a vent hole gets onto the heating element of the computing device It cools it and is then discharged through at least one coolant propulsion that is installed on the surface or the air vent on the other side of the surface.

The device according to claim 1, characterized in that at least one computing device is mounted on the surface in such a way that the flow of cold air, moving on one side of the surface due to the convection movement of the coolant, and due to the coolant propellers that are installed on the computing device, through the limiting surface through the vent hole gets on the heating element of the computing device, cools it and then goes through the limiting surface to the other side of the surface.

The device according to claim 1, characterized in that at least one computing device is mounted on the surface in such a way that the flow of cold air, moving on one side of the surface through the duct, due to the convective movement of the heat carrier, and due to the heat carrier propellers that are installed on computing device through the vent hole gets on the heating element of the computing

SUBSTITUTE SHEET (RULE 26) device, cools it and then it is discharged through the duct to the other side of the surface.

5. The device according to claim 2, characterized in that at least one computing device is mounted on the surface in such a way that the flow of cold air, moving on one side of the surface due to the convective movement of the coolant, and due to the propulsive coolants that are installed on the computing device, through the limiting surface through the vent hole gets on the heating element of the computing device, cools it and then goes through the limiting surface to the other guyu side surface.

6. The device according to claim 2, characterized in that at least one computing device is mounted on the surface in such a way that the flow of cold air, moving from one side of the surface through the duct, due to the convective movement of the coolant, and installed on the computing device, through the vent hole gets on the heating element of the computing device, cools it and then goes through the air duct to the other side of the surface.

7. The device according to p. 3, characterized in that at least one computing device is mounted on the surface in such a way that the flow of cold air, moving from one side of the surface through the duct, due to the convective movement of the coolant, and installed on the computing device, through the vent hole gets on the heating element of the computing device, cools it and then goes through the air duct to the other side of the surface.

8. The device according to claim 5, characterized in that at least one computing device is mounted on the surface in such a way that the flow of cold air, moving on one side of the surface through the duct, due to the convective movement of the coolant, and installed on the computing device, through the vent hole gets on the heating element of the computing device, cools it and then goes through the air duct to the other side of the surface.

SUBSTITUTE SHEET (RULE 26)