RU2674521C1 - Radio electronic device - Google Patents

Abstract

FIELD: radio equipment; electronics.SUBSTANCE: invention relates to electronic equipment and can be used in electronic devices containing heat-generating radio elements that require cooling and protection from external influences during operation. Electronic device includes a housing made of a heat-conducting material, and fuel elements located inside the housing. Case has a ribbed radiator integrated in it and a needle radiator, which serves as its side wall. Device is equipped with a centrifugal fan and a panel covering the needle radiator housing. Fuel elements are distributed in the internal space of the device so that the elements with the highest heat generation are grouped near the needle radiator of the case, and the elements with the lowest heat generation are grouped near the ribbed body radiator. In a needle radiator there is a cavity in which a centrifugal fan is flush with the needles of a needle radiator. Panel has at least one hole for air flow to the centrifugal fan.EFFECT: improving the efficiency of heat removal from the fuel elements in the body of the electronic device, as well as improving the efficiency of heat exchange between the body of the electronic device and the environment.5 cl, 6 dwg

Description

The invention relates to electronic equipment and can be used in electronic devices containing fuel elements that require cooling and protection from external influences during operation.

To ensure acceptable thermal conditions of electronic devices characterized by increased power, for example, transceivers based on software-defined radio systems (SDR), various cooling options are used for the fuel elements and the body of the device, providing both natural cooling due to convection, for example, from a fin radiator, so and forced air cooling by air flow.

Known radio-electronic device with air cooling (see RF patent RU2491662, IPC G12B9 / 02, G12B15 / 04, H05K5 / 00, H05K7 / 20, published on 08.27.2013), providing the required thermal regime of its fuel elements. The housing of the known device contains side walls made in the form of radiators, and the fuel elements are distributed inside the housing depending on the level of their heat generation. The walls of the housing are double with the formation of air ducts between them, and the internal space of the housing is divided into compartments separated by air channels. The presence of air channels between the walls and compartments increases the overall dimensions of the electronic device. In addition, to ensure the cooling of the fuel elements, it is necessary to connect an additional device that supplies air to the air channels, which, in turn, does not allow autonomous use of the electronic device for a long time.

As a prototype of the claimed device, the Voyager CBM-100 radio electronic device of Klas Telecom, Inc., known from the prior art, was selected. (USA) (see, for example, a link on the Internet https://klastelecom.com/wp-content/uploads/2016/05/voyager_cbm100_brochure_web_v1_03.pdf), including a housing made of heat-conducting material, and heat-generating elements placed inside corps. The body of a well-known electronic device is equipped with needle and fin radiators integrated into it. A disadvantage of the known device is the lack of an active cooling system and, as a result, an insufficient level of heat removal from its fuel elements.

The technical problem to which the invention is directed is to create a radio electronic device having high thermal stability of the operating mode.

The technical result achieved by solving the technical problem is to increase the efficiency of heat removal from the fuel elements in the housing of the electronic device, as well as to increase the efficiency of heat exchange between the housing of the electronic device and the environment.

The technical result is achieved due to the fact that the electronic device contains a housing made of heat-conducting material, and fuel elements located inside the housing, the housing has a finned radiator and a needle radiator integrated into it, which serves as its side wall. The electronic device is equipped with a centrifugal fan and a panel that covers the needle radiator of the housing. The heat-generating elements are distributed in the internal space of the device so that the elements with the highest heat are grouped near the needle radiator of the housing, and the elements with the lowest heat are grouped near the fin radiator of the housing, while a cavity is made in the needle radiator, in which the centrifugal fan is mounted flush with the needle of the radiator. The panel has at least one opening for air flow to the centrifugal fan.

The fin radiator can also serve as a side wall of the housing to increase the heat exchange surface with the environment.

The needle radiator may have one or more additional cavities, providing increased heat transfer efficiency due to a more even distribution of air flows from the centrifugal fan in the needle radiator.

A removable air filter can be installed on the air inlet to the centrifugal fan to reduce the level of contamination of the needle radiator from the air entering through the opening.

The panel can be made removable, which allows for maintenance of a centrifugal fan and to clean the fin radiator from fine dust.

Further, the present invention is illustrated by drawings, which show an embodiment of the inventive electronic device.

In FIG. 1 shows a radio electronic device.

In FIG. 2 shows a radio electronic device on the side of a finned radiator.

In FIG. 3 shows a view of the electronic device with the panel removed from the side of the needle radiator.

In FIG. 4 shows the electronic device from the side of the needle radiator with the panel installed.

In FIG. 5 shows a side view of a radio electronic device with additional cavities in a needle radiator.

In FIG. 6 shows a complete electronic device.

In accordance with the present invention, the electronic device comprises a housing 1 made of heat-conducting material. In this case, a fin radiator 2 and a needle radiator 3 are integrated into the housing 1, providing cooling of the fuel elements of the electronic device. The fin radiator 2 serves as a side wall of the housing 1. The needle radiator 3, which also serves as the side wall of the housing 1, has a cavity 4 in which the centrifugal fan 5 is mounted. A removable panel 6 covers the needle radiator 3, thereby creating many channels blown by the centrifugal fan 5, which, in turn, is mounted flush with the needles of a needle-shaped radiator 3 so as not to increase the dimensions of the electronic device. The panel 6 has an opening 7, which provides air flow to the centrifugal fan 5. A removable air filter 8 can be installed on the opening 7, preventing dust from clogging the channels of the needle radiator 3. For a more uniform distribution of air flows in all directions of the needle radiator 3 and, as a result, more efficient heat transfer, the needle radiator 3 may have one or more additional cavities 9 formed by partially removing the needles of the needle radiator 3.

In the process of operation of a radio electronic device, especially characterized by increased power (for example, an SDR-based transceiver), it is necessary to maintain its stable thermal regime. The cooling of the fuel elements placed inside the casing of the electronic device is carried out by transferring the heat generated from them to the casing 1 made of heat-conducting material by means of mechanical contact. To increase the efficiency of heat dissipation, the heat-generating elements are distributed inside the housing 1 so that the heat-generating elements with low power, therefore, with low heat generation, are grouped near the fin radiator 2 of the housing 1, and the heat-generating elements with high power, and therefore, with high heat generation, are grouped near the needle radiator 3, cooled by a centrifugal fan 5.

Part of the housing 1, made in the form of a fin radiator 2, provides passive cooling of the fuel elements of the electronic device by means of natural convection. Another part of the housing 1, made in the form of a needle-shaped radiator 3, preferably with a centrifugal fan 5 mounted in the cavity 4 and a removable panel 6, provides active cooling of the fuel elements of the electronic device. A removable panel 6, installed so as to cover all the needles of the needle-shaped radiator 3, creates many channels blown by air using a centrifugal fan 5, the air flow to which is provided by an opening 7 in the panel 6 (the movement of air flows in Fig. 4 is shown by arrows). An air filter 8 is installed to clean the air coming in through the hole 7. In addition, to ensure a more uniform distribution of air flows in the needle radiator 3 by partially removing the needles, additional cavities 9 can be made.

Thus, the claimed radio-electronic device can significantly increase the efficiency of heat removal from the heat-releasing elements placed in it while increasing the heat transfer efficiency between the housing of the radio-electronic device and the environment and thereby ensures a stable thermal regime of the electronic device.

Claims (9)

1. A radio-electronic device containing a housing made of heat-conducting material and heat-generating elements placed inside the housing, the housing has a finned radiator and a needle radiator integrated therein, which serves as its side wall, characterized in that additionally equipped with a centrifugal fan and a panel covering the needle heat sink of the housing, fuel elements are distributed in the internal space of the device so that the elements with the highest heat are grouped near the needle radiator of the housing, and the elements with the lowest heat are grouped near the fin radiator of the body, in this case, a cavity is made in the needle radiator, into which the centrifugal fan is mounted flush with the needle of the needle radiator, and the panel has at least one opening for air flow to the centrifugal fan. 2. The device according to claim 1, characterized in that the fin radiator is a side wall of the housing. 3. The device according to claim 1, characterized in that the needle radiator has one or more additional cavities for distributing air from the centrifugal fan along the needle radiator. 4. The device according to claim 1, characterized in that the panel is removable. 5. The device according to claim 1, characterized in that a removable air filter is installed on the hole for air flow to the centrifugal fan.

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