KR101175976B1 - Apparatus for radiant heat in multiple channel receiver - Google Patents

Abstract

PURPOSE: A heat sink of a multi-channel receiver is provided to effectively dissipate heat from a multi-channel receiver by attaching a heat sink assembly to the surface of the multi-channel receiver. CONSTITUTION: A power supply assembly(100) supplies power to each antenna channel. A multi-channel receiver(200) amplifies a signal received through an antenna(201). A heat sink assembly(300) disperses and releases heat of the multi-channel receiver to outside. The heat sink assembly includes a heat sink plate(310), which is attached to the surface of the multi-channel receiver, and a heat sink lattice pin(320).

Description

Apparatus for radiant heat in multiple channel receivers

The present invention relates to a heat dissipation device of a receiver, and more particularly, to a device for dissipating heat generated from a multi-channel receiver to the outside.

An image radiometer system is a system that receives an image of radiant energy naturally radiated from an object in a millimeter wave band and acquires an image. That is, the image radiometer system detects the electromagnetic wave energy signal (brightness temperature) of the millimeter wave band radiated from the object with a broadband, low noise, high definition receiver and converts it into an electrical signal (voltage) to measure the brightness temperature of the object and image it. It is a two-dimensional image sensor system.

The millimeter wave band used in the image radiometer system has an advantage that remarkably less attenuation by clouds, fog, rain, dust, or flame compared to the visible or infrared region, and high resolution is obtained compared to microwaves.

For this reason, video radio system has the advantage of getting the image through the obstacle. In the visible light, the image of the object cannot be obtained by passing through obstacles such as clouds or fog.However, in the millimeter wave band, the image of the object can be passed through obstacles such as clothes, boxes, and tents in situations where the weather is highly volatile, such as clouds, fog, or bad weather. Can be obtained. In addition, airports and major facilities are used for detection of non-metallic and metallic weapons or explosives hidden in clothing, assistance systems for takeoffs and landings in bad weather conditions, oil leakage detection of ships, and flames or roads in case of fire due to accidents in tunnels. This can be important for civilian technologies, such as observing the shape of obstacles caused by fog in the fog. In addition, as a military technology, it has various applications such as sensors of unmanned robots, detection of tanks hidden in the forest, and detection of military facilities on the ground.

This passive video radio system has the advantage of harmless to the human body by detecting the thermal noise inherent to the object without using a transmitter. However, since the intensity of the received signal is very weak, a low noise, high gain, and high sensitivity receiver is required. .

In order to develop a commercial video radio system, not only the performance of the receiver but also the stability and reliability must be secured. The performance of the receiver is closely related to the two-dimensional image, which is the final output value. The performance of such a receiver is closely related to the receiver temperature. In other words, the performance indicator of the receiver is called the temperature sensitivity, and this temperature sensitivity is related to the bandwidth, the integration time, and the noise figure of the system. As the temperature sensitivity of the receiver increases, the final image quality is improved.

However, the multi-channel receiver in an array form is vulnerable to heat generation because 1 * N receivers are concentrated in a narrow area due to the characteristics of the video radio system. Each receiver is composed of a low noise amplifier (LNA), an amplifier stage (OPAMP), and the like, which cause heat generation. The heat generated in the multi-channel receiver is increased as the multi-channel receiver is manufactured by intensively coupling the heat generated by the components inside the receiver and N pieces. This heat generation has a significant effect on the performance of the imaging radio system. In order to improve the temperature sensitivity that is critical to the receiver's performance in video radio system, the noise figure of the receiver itself must be reduced, but the thermal noise inside the multi-channel receiver makes it difficult to detect fine millimeter-wave signals. Two-dimensional image cannot be obtained. In addition, there is an initial driving time, which is a transition region until the receiver is stabilized, for driving the system. The initial driving time is long due to heat inside the receiver, and the stability of the receiver is deteriorated due to this reason. In addition, there is a problem that consumes a lot of time due to additional calibration to ensure the stability of the receiver.

Korea Patent Registration 10-0929596

The technical problem of the present invention is to effectively dissipate heat generated in a multi-channel receiver. In addition, the technical problem of the present invention is to improve the receiver stability of the video radio. In addition, the technical problem of the present invention is to reduce the noise figure of the receiver.

Embodiments of the present invention provide a multi-channel receiver for amplifying a beam received through the antenna by arranging at least one antenna, and the heat generated in contact with the surface of the multi-channel receiver, the heat generated on the surface of the multi-channel receiver It includes a heat dissipation body to release the outside.

In addition, the heat dissipation member is installed to contact the surface having the largest area among the surface of the multi-channel receiver.

The heat dissipation member includes a heat dissipation plate whose one side is in contact with the surface of the multi-channel receiver, and a plurality of heat dissipation lattice pins protruding from the other side of the heat dissipation plate. The heat dissipation lattice pins have a plurality of heat dissipation lattice pins arranged in a lattice structure to protrude.

In addition, the heat dissipation unit includes a thermal pad provided between the surface of the multi-channel receiver and one side of the heat sink, to spread the heat of the multi-channel receiver to transfer to one side of the heat sink.

According to the embodiment of the present invention, by attaching the heat radiating member adjacent to the surface of the receiver, it is possible to effectively release the heat generated by the receiver. In addition, the heat radiation efficiency can be improved by providing a lattice structure heat radiation grid pin on the surface of the heat sink. Therefore, the heat dissipation can reduce the noise figure of the receiver.

1 is an external perspective view of a multi-channel receiving processing apparatus according to an embodiment of the present invention.
2 is a diagram showing an actual picture of a multi-channel receiving processing apparatus according to an embodiment of the present invention.
3 is a diagram illustrating a connection between a multi-channel receiver and a video signal processing period.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention in more detail. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms, and only the embodiments are intended to complete the disclosure of the present invention and to those skilled in the art to fully understand the scope of the invention. It is provided to inform you. Wherein like reference numerals refer to like elements throughout.

1 is an external perspective view of a multi-channel receiving processing apparatus according to an embodiment of the present invention, Figure 2 is a view showing a real picture of the multi-channel receiving processing apparatus according to an embodiment of the present invention, Figure 3 is a multi-channel receiving This figure shows the connection between the processing unit and the video signal processing period.

The multichannel reception processing apparatus 90 includes a power supply assembly 100, a multichannel receiver 200, and a heat dissipation unit 300.

The power assembly 100 includes a power supply 60 to supply power to each antenna channel. The drive controller 50 controls the scan driver 40 and supplies power to all devices through the power supply 60. For reference, the image signal processor 80 includes an AD converter board, an offset board, a scan driving control, and a DSP board. The image signal processor 80 converts an analog signal received from the multi-channel receiving processing apparatus 90 into a digital signal in an AD conversion board, corrects an output value through an offset, and then performs signal processing to process the image output device 70. To provide.

In the multi-channel receiver 200, at least one antenna 201 for receiving a signal radiated by an object is disposed to amplify a signal (beam) received through the antenna 201. The noise of the millimeter wave band radiated in proportion to its own temperature of the object 10 is collected as a signal by the lens 20 as a dielectric material. The collected signal is reflected by 90 degrees using the reflector 30 to multi-channel receiver. To be received by each antenna. The reflection plate 30 may be adjusted by the scan driver 40 to reflect the reflection angle of the reflection plate 30. The antenna 201 of each unit may be formed of a known material capable of receiving signals in the millimeter wave band.

In the structure 210 (hereinafter, referred to as an antenna array structure) in which the unit antennas 201 are arranged, a plurality of unit antennas are arrayed, and each unit antenna is connected to each unit receiver of a receiver of a corresponding channel. Hereinafter, a signal processing system corresponding to each unit antenna is called a channel. The antenna array structure 210 includes a plurality of antennas arranged to form one sub antenna, and various patterns (eg, a straight pattern and a Y-shaped pattern) spaced apart in three directions with respect to a center position set between the sub antennas. It is arranged in a structure. The antenna array structure 210 may be formed by arranging the unit antennas in the above-described structure on the antenna installation object or by arranging the unit antennas in the above-described structure on the base plate.

The multi-channel receiver 200 includes antennas for each channel, which is vulnerable to heat generation because the N- receivers are arranged in a narrow area. That is, each of the arrayed antennas is provided with a low noise amplifier (LNA), an amplifier stage (OPAMP), a band pass filter, etc., which cause heat generation, and is provided inside the multi-channel receiver. The heat generation inside the multi-channel receiver is increased as the multi-channel receiver is manufactured by intensively coupling the heat generated by the components inside the receiver and N pieces. This heat generation has a significant effect on the performance of the imaging radio system. Therefore, the heat generation of the multi-channel receiver must be heated to the air, thereby improving the performance of the video radio system.

To this end, an embodiment of the present invention includes a heat dissipation unit 300 for dissipating and dissipating heat of a multi-channel receiver to the outside.

The heat dissipation unit 300 includes a heat dissipation plate 310 having one side contacting the surface of the multi-channel receiver, and a plurality of heat dissipation lattice pins 320 protruding from the other side of the heat dissipation plate.

The heat sink 310 is installed to be in contact with the surface of the multi-channel receiver 200, and emits heat generated from the surface of the multi-channel receiver 200 to the outside (for example, the atmosphere). Therefore, since the heat generated in the multi-channel receiver 200 is discharged through the heat dissipation unit 300, as a result, it is possible to improve the performance of the multi-channel receiver to improve the overall performance of the video radio system.

The heat dissipation unit 300 is installed to contact the surface having the largest area among the surface of the multi-channel receiver. When the multi-channel receiver 200 is installed at a right angle to the video signal processor, a heat radiating member is installed to contact the side wall of the vertical wall. By installing a heat dissipation unit so as to be in contact with the largest area among the surfaces of the multi-channel receiver 200, it is possible to maximize the emission effect of the surface heat of the multi-channel receiver.

The heat sink 310 may be implemented with a plate plate made of a thermally conductive material such as aluminum to spread heat generated from the surface of the multi-channel receiver 200 to the entire heat sink in the form of a wide plate. The heat sink 310 is coupled to the surface of the multi-channel receiver through the screw fastening. The screw is inserted between the lattice gaps between the radiating grid pins of the lattice structure and penetrates the radiating plate to screw the multi-channel receiver. In addition, the heat dissipation plate 310 includes a plurality of heat dissipation grid fins 320 protruding from the other side of the heat dissipation plate to dissipate heat transmitted from the multi-channel receiver. The heat dissipation plate 310 is made of a thermally conductive material, and receives heat generated from the multi-channel receiver on one side thereof, and conducts heat to the heat dissipation plate.

The heat dissipation grid fin 320 is provided with a plurality of high thermal conductivity aluminum material, it is formed on the other side of the heat dissipation plate 310 as a plurality of lattice structure. Since the heat radiation lattice pin 320 has a lattice structure, the heat dissipation grid pin 320 has a lattice gap between the heat dissipation lattice pins, and air in the air flows between the lattice gaps to maximize the heat dissipation effect of the heat dissipation lattice pins.

Meanwhile, the heat dissipation member 300 may include a thermal pad 330 in addition to the heat dissipation plate 310 and the heat dissipation lattice pin 320. The thermal pad 330 is provided between the surface of the multi-channel receiver 200 and one side of the heat sink 310 to diffuse heat of the multi-channel receiver 200 so that the thermal pad 310 Pass on one side.

The thermal pad 330 fills a fine gap between the metal and the metal so that heat generated in the heat-producing portion is well transmitted to the heat sink. In actual implementation of the multi-channel receiving processing apparatus, the image signal processor and the multi-channel receiver are provided in a housing made of metal, respectively. Therefore, the surface of the multi-channel receiver 200 is a metal material, the heat dissipation member is also made of a metal material, when the direct contact with these metal materials may be inferior in heat transfer efficiency. The thermal pad 330 is provided between the surface of the multi-channel receiver 200 and one side of the heat sink 310 to prevent the heat transfer efficiency from dropping.

Therefore, the thermal pad 330 fills a minute gap between the housing metal of the multi-channel receiver 200 and the metal of the heat sink 310 so that heat generated in the heat-producing portion is well transmitted to the heat sink. The material of the thermal pad 330 is made of a heat conducting material having high heat conduction efficiency. Preferably, the thermal pad 330 is made of silver and aluminum.

The thermal pad 330 has a pad shape, and a method of manufacturing the pad shape is made of nano powders in which aluminum and silver are synthesized to increase thermal conductivity, and then a silicon material is synthesized into the nano powder to form a pad shape. do. By synthesizing the silicon material to the nano-powder, it is possible to maximize the heat conduction efficiency by increasing the sealing between the metal of the housing of the multi-channel receiver 200 and the metal of the heat sink.

Although the present invention has been described with reference to the accompanying drawings and the preferred embodiments described above, the present invention is not limited thereto but is limited by the following claims. Accordingly, those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the spirit of the following claims.

80: video signal processor 90: multi-channel receiving processing device
200: multi-channel receiver 201: antenna
210: antenna array structure 300: heat dissipation body
310: heat sink 320: heat radiation grid pin
330: thermal pad

Claims (8)

A multi-channel receiver for arranging at least one antenna to amplify a beam received through the antenna;
And a heat dissipation unit installed to be in contact with the surface of the multi-channel receiver and dissipating heat generated from the surface of the multi-channel receiver to the outside.
The heat dissipation unit,
A heat dissipation plate having a heat dissipation plate having one side directly contacting the surface of the multi-channel receiver and the other side protruding a plurality of heat dissipation lattice pins, wherein the plurality of heat dissipation lattice pins are arranged in a lattice structure. Device. The heat dissipation device of claim 1, wherein the heat dissipation member is installed to contact a surface having the largest area among the surfaces of the multi-channel receiver. delete delete The method according to claim 1, wherein the heat dissipation body,
And a thermal pad provided between a surface of the multichannel receiver and one side of the heat sink to spread heat of the multichannel receiver to transfer to one side of the heat sink. The heat dissipation device of claim 5, wherein the thermal pad has a pad shape made of a thermally conductive material. The heat dissipating device of claim 6, wherein the heat conducting material is made of a composite material of aluminum and silver. The heat dissipation device of claim 6, wherein the pad shape is manufactured by synthesizing a silicon material with nano powders composed of aluminum and silver.

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