RU175723U1 - Computing unit of an electronic computing device - Google Patents

Abstract

The utility model relates to the field of electronic computing devices for data processing.

The technical result, which the utility model aims to achieve, is to increase the cooling efficiency of the computing unit of the electronic computing device.

The essence of the utility model is that the computing unit of the electronic computing device, unlike the prototype, contains computing boards with retracting fans and air exhaust zones, while the computing boards are installed with the formation of a corridor and directed by retracting fans into the corridor, and the corridor is equipped with a supply duct.

Description

The utility model relates to the field of electronic computing devices for data processing.

The process of processing data in an electronic computing device is provided by one or more computing boards and is accompanied by their heating. However, there is often a need for processing large amounts of data, for which computing boards are combined into computing units, during the operation of which a very large amount of heat is generated, which must be removed to maintain the speed and performance of the computing boards. In this regard, there are a large number of technical solutions aimed at finding the optimal constructive organization of computer boards, providing both effective cooling and high compactness of the computing unit.

A known computing unit of an electronic computing device containing computing boards [US 2010073872, priority date: September 24, 2008, publication date: March 25, 2010, IPC: H05K 7/20].

A known computing unit of an electronic computing device containing computing boards having an air exhaust zone [US 2015062812, priority date: 08/30/2013, publication date: 03/05/2015, IPC: H05K 7/20].

As a prototype, a computing unit of an electronic computing device containing computing boards equipped with fans was selected [US 7738251, priority date: 08/30/2013, publication date: 06/15/2010, IPC: G06F 13/00].

A disadvantage of the known devices is the low cooling efficiency of the computing boards, due to their mutual arrangement, which does not allow the natural intake of cold air from the external environment, which necessitates the use of additional pressure fans, which reduces the cooling efficiency of the computing unit of the electronic computing device, adversely affecting its performance and service life.

The technical problem to which the utility model is directed is to increase the productivity and service life of the electronic computing device.

The technical result, which the utility model aims to achieve, is to increase the cooling efficiency of the computing unit of the electronic computing device.

The essence of the utility model is as follows.

The computing unit of the electronic computing device, unlike the prototype, contains computing boards with retracting fans and air extraction zones, while the computing boards are installed with the formation of a corridor and directed by retracting fans into the corridor, and the corridor is equipped with a supply duct.

The computing unit of an electronic computing device is part of an electronic computing device and is intended to perform a sequence of computational operations consisting of numerical calculations, data manipulation, processing of graphic or audio information, building models and other operations. The computing unit consists of interconnected computing boards.

Computing boards are designed for data processing and can be graphic, sound, network or other boards. Computing boards are predominantly regular in shape, for example, rectangular or square, and can be of any size. Computing boards are equipped with retractors and air exhaust zones. Retracting fans provide air injection and its movement through the internal space of the circuit boards to the air exhaust zones. The air exhaust zones provide the possibility of removing warm air from the internal space of the computing boards and can be a group of holes or slots, or they can be represented by exhaust channels or a deflector. In this case, the air exhaust zones and the retracting fans can advantageously be located on opposite sides of the computing boards.

The corridor formed by the computing boards can be in the form of any polyhedron, for example, a triangular, quadrangular or hexagonal prism. Thus, a corridor in the form of a triangular prism may, for example, contain three computing boards, and a corridor in the form of a hexagonal prism may contain six computing boards, etc. On the one hand, the corridor is equipped with a supply duct, and on the other hand, it can be opened, or it can be closed with additional computer boards. The connection between the boards can be carried out by any known detachable and inseparable methods.

Computing boards are directed by the retractor fans into the corridor and can advantageously be positioned so that the retractor fans can be opposite each other and the air exhaust zones can be directed in one direction. Moreover, the position of the fans opposite each other does not mean a direct coincidence or intersection of their rotation axes, but implies a close arrangement of the rotation axes relative to each other. Computing boards can also be arranged so that the air exhaust zones are directed in different directions, if this provides the possibility of installing the retractor fans opposite each other.

The inlet duct can be of any shape and size, which may depend on the shape and size of the corridor, the location of the computing boards, their retractors, and the air exhaust zones. In this case, the inlet duct can be installed on either side of the corridor. The inlet duct can be installed on the opposite side of the corridor from the retractor fans, which provides an additional increase in the distance that the air travels before it enters the retractor fans, and therefore increases its speed and reduces the temperature, and if the air exhaust zone is also located on the opposite side from the case side intake fans, the inlet duct may take the form of separating the incoming and outgoing air flows, for example p, it can be made in the form of a flared flange at the edges of a hollow truncated cone, a funnel, or it can have partitions on the outer surface that allow the exhaust air to deviate to the sides, etc.

Additionally, the computing unit of the electronic computing device may include an exhaust duct connected to the exhaust air zones of the computing boards. The exhaust duct provides the ability to collect air from the zones of air exhaust, its directional exhaust and secondary use, for example, for heating a room. To ensure the compactness of the computing unit of the electronic device, a discharge duct may be formed around the supply duct and may have a lateral branch.

Additionally, the computing unit of the electronic computing device may be provided with an external casing installed to form a gap relative to the computing boards and comprising an air exhaust zone connected to the exhaust duct. The presence of an external casing allows the use of the air leaving the corridor on the opposite side from the supply air duct to cool the computer boards from the outside, preventing the dispersion and mixing of the flows of supplied and exhausted air. Also, the presence of the housing provides the possibility of combining several computing units in it, which increases the performance of the electronic computing device.

Additionally, to ensure more efficient removal of warm air and less dispersion, the exhaust duct may contain one or more exhaust fans, which can be located in any part of it.

Additionally, the computing unit of the electronic computing device may contain electronic components that close the corridor on the opposite side from the supply duct, which makes it possible to cool them. Electronic components can be additionally equipped with retractor fans directed into the corridor, which makes it possible to create additional vacuum in the corridor and more efficient use of cold air passing by the retractor fans of the circuit boards. Electronic components can be represented by a power supply, a motherboard, additional computing boards, or other components.

The utility model possesses a set of essential features previously unknown from the prior art, characterized in that the computing unit contains computing boards with retracting fans and air extraction zones, while the computing boards are installed to form a corridor and directed by retracting fans into the corridor, and the corridor is equipped with a supply duct. This design allows you to create a low pressure area inside the corridor that promotes air from the external environment to suction fans with significant acceleration, providing a high speed of updating and air exhaust from the computing unit, which results in a technical result consisting in increasing the cooling efficiency of the electronic computing computing unit devices, thereby increasing its performance and service life.

The presence of new distinctive essential features indicates the compliance of the utility model with the patentability criterion of “novelty”.

The utility model can be made of known materials using known means, which indicates the compliance of the utility model with the patentability criterion of "industrial applicability".

The utility model is illustrated by the following drawings.

FIG. 1 - Computing unit of an electronic computing device with an inlet duct installed on the side opposite from the retracting fans, left side view.

FIG. 2 - Computing unit of an electronic computing device with a supply duct installed on the side of the retractor fans, top view.

FIG. 3 - Computing unit of an electronic computing device closed by computing boards, left view.

FIG. 4 - Computing unit of an electronic computing device with inlet ducts installed on both sides of the corridor, top view.

FIG. 5 - Electronic computing device, left view.

FIG. 6 - Electronic computing device with several computing units, left view.

The computing unit of the electronic computing device (Fig. 1-4) consists of computing boards 1 installed with the formation of a corridor, containing retractor fans 2, and air exhaust zones 3. In this case, the corridor is equipped with a supply duct 4.

The computing unit of the electronic computing device is connected to the network, and the computing boards 1 begin to work, generating a large amount of heat. In this case, the retracting fans 2 are activated, which create a region with a reduced pressure, into which a stream of cold air rushes through the supply duct 4 at high speed. A stream of cold air is drawn in from the corridor by the retractor fans 2, is directed inside the computing boards 1, cools them and is discharged through the air exhaust zones 3 to the outside.

The electronic computing device (Fig. 5, 6) contains a computing unit, an external case 5, a power supply unit 6, equipped with a fan 7, and a motherboard 8. In this case, an exhaust duct 9 is provided in the upper part of the external housing 5, equipped with a fan 10.

An electronic computing device is connected to a network. In this case, cold air passes through the corridor of the computing unit and is sucked in by suction fans 2, and part of the air is sucked in by the fan 7 of the power supply unit 6, cooling it and the motherboard 8. Then the air moves along the wall of the housing 5 to the exhaust duct 9, where it is mixed with air, coming from zones 3 of the air outlet. In this case, the exhaust fan 10 creates a region with reduced pressure, contributing to the removal of warm air from the electronic computing device. Warm air removed from the electronic computing device is subsequently used to heat the room or other purposes.

This ensures the achievement of the technical result, which consists in increasing the cooling efficiency of the computing unit of the electronic computing device and, accordingly, increases the performance and service life of the electronic computing device.

Claims (7)

1. A computing unit of an electronic computing device, characterized in that it contains computing boards with retracting fans and air exhaust zones, the computing boards being installed with the formation of a corridor and directed by retracting fans into the corridor, and the corridor is equipped with a supply duct. 2. The computing unit of the electronic computing device according to claim 1, characterized in that it comprises a discharge duct connected to the air extraction zones of the computing boards. 3. The computing unit of the electronic computing device according to p. 2, characterized in that it further comprises an external housing that is installed with the formation of a gap relative to the computing circuit boards and containing an air exhaust zone connected to the exhaust duct. 4. The computing unit of the electronic computing device according to claim 3, characterized in that the exhaust duct further comprises a exhaust fan. 5. The computing unit of the electronic computing device according to claim 1, characterized in that the supply duct is installed on the opposite side from the retracting fans. 6. The computing unit of the electronic computing device according to claim 5, characterized in that it contains additional electronic components that close the corridor on the side closest to the retracting fans. 7. The computing unit of the electronic computing device according to claim 6, characterized in that the additional electronic components are equipped with retractor fans directed into the corridor.

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