KR100953728B1 - Horn array antenna - Google Patents

Abstract

The present invention relates to an antenna for transmitting and receiving a frequency signal, and more particularly, a horn array antenna having high gain and directivity, which is easy to manufacture and which can efficiently heat dissipate and cool heat generated from a power amplifier of an embedded microwave transceiver. It is to provide.

To this end, in the present invention, the antenna body for transmitting and receiving a frequency signal by forming a plurality of partitions and a fan-shaped horn open on both sides between the partitions; A housing in close contact with the antenna body; Disclosed is a horn array antenna including a distributor installed in a cavity formed between the antenna body and the housing.

Horns, arrays, antennas, power amplifiers.

Description

Horn array antenna

The present invention relates to an antenna that transmits and receives a frequency signal, and more particularly, has a high gain and directivity, and is easy to manufacture, and a horn capable of efficiently radiating and cooling heat generated from a power amplifier of an embedded microwave transceiver. It relates to an array antenna.

In general, an antenna and a power amplifier are installed in a communication facility such as a satellite communication system or a mobile communication system. Among them, the antenna is for radiating or receiving radio waves in free space, and there are various classification criteria, but generally, linear antenna, aperture antenna, micro strip antenna, array antenna, reflector antenna, lens antenna, horn antenna, etc. It can be divided into

FIG. 1 illustrates an example of an array antenna of the above-described antennas. As shown in FIG. 1, openings 11 having a parallelogram shape are arranged like a checkerboard, and each of the openings 11 has metal diaphragms 12 on all sides. It consists of a shape surrounded by).

When the array antenna 10 is used for a short wavelength such as a millimeter wave, the array antenna 10 can be manufactured compactly. However, in the case of an X band having a long wavelength or less, when the array of 256 antenna openings 11 is applied, the array antenna 10 Not only does the overall size increase, but a large number of diaphragms 12 require a high degree of difficulty in processing and molding, and there is a problem that miniaturization is very difficult.

Therefore, the conventional array antenna 10 has a long manufacturing period, it is extremely difficult to produce through the mold due to the plurality of diaphragm 12, the defect rate such that the twisting phenomenon of the diaphragm 12 occurs in the cooling process according to the casting production Very high, as a result there is a problem that the manufacturing cost of the antenna rises.

In addition, since the conventional array antenna 10 has a lower directivity than the horn array antenna, there is a problem in that the performance of the microwave repeater is limited.

Meanwhile, FIG. 2 illustrates a state where a conventional array antenna 10 is installed in a microwave repeater. As shown in FIG. 2, the array antenna 10 is installed together with the microwave module 20 in which a power amplifier is embedded.

When the power amplifier of the microwave module 20 requires a large power, an additional heat sink 30 is essentially installed separately from the array antenna 10 for heat dissipation, so that the volume and weight of the microwave module 20 must be increased. Since the 10 and the microwave module 20 and the heat sink 30 are separately installed, there is a problem that the overall external size of the microwave module 20 including the array antenna 10 is unnecessarily large.

Therefore, in the case of the communication equipment such as the microwave repeater installed with the conventional array antenna 10 and the power amplifier, a lot of manufacturing costs are required due to the large appearance and heavy weight, and it is difficult and inconvenient for transportation and installation. .

      SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above, and an object of the present invention is to provide a horn array antenna that can be easily manufactured while increasing the antenna gain and directivity.

      Another object of the present invention is to provide a horn array antenna that can efficiently radiate heat of the power amplifier built in the microwave transceiver without installing a separate heat sink.

In order to achieve the above object, the present invention provides an antenna body for transmitting and receiving a frequency signal by forming a plurality of partitions and a fan-shaped horn open at both sides between the partitions; A housing in close contact with the antenna body; Provided is a horn array antenna including a distributor installed in a cavity formed between the antenna body and the housing.

According to the present invention, the partition wall of the antenna is formed in a serration shape, and the horn between the partition walls is formed in a fan shape with both sides open, thus making it very easy to manufacture, thereby reducing manufacturing cost and manufacturing time.

In addition, since the shape of the horn is formed in an arc shape or a parabolic shape in addition to the fan shape, the present invention can further increase the gain and directivity.

In addition, the present invention can minimize the dielectric loss and the conductor loss and reduce the size of the antenna by implementing the strip line using the air medium.

In addition, the present invention is installed in close contact with the horn array antenna integrally in the housing it is possible to more efficiently dissipate heat generated from the power amplifier of the microwave transceiver built into the housing through the partition wall and the horn of the antenna body.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a perspective view showing a horn array antenna according to the present invention, Figure 4 is a cross-sectional view showing the structure of the horn array antenna according to the present invention, as shown the horn array antenna 100 of the present invention is largely the antenna body ( 200), the housing 300, the distributor 400.

First, the antenna body 200 radiates heat conducted from the housing 300 while transmitting and receiving a frequency signal. In the present invention, as an example, a plurality of partitions 210 having a serration shape formed thereon and , And formed between the two partition walls 210 to connect the fan-shaped horn 220 having both sides open, the wave guide hole 230 formed on the bottom surface of each horn 220, and the wave guide hole 230. It consists of a transmission line formed on the bottom surface of the antenna body (200).

Here, the partition wall 210 is for forming the horn 220, and a plurality of predetermined intervals are formed in a substantially triangular sawtooth shape like a serration.

The horn 220 is a portion in which the frequency signal is radiated and received, and is formed to increase antenna gain and directivity in a substantially fan shape between the two partition walls 210. Here, the horn 220 has a structure in which both sides except for the partition wall 210 are open. In the TE _0,1 (Transverse Electric) mode, since the electric field does not exist in the conductor plate in the horizontal direction, The same characteristics can be maintained even when the partition wall 210, that is, a structure in which both sides of the four sides are open.

In addition, the horn 220 between the two partition walls 210 are arc-shaped or parabolic on the opposite surfaces of the two partition walls 210 as shown in FIG. 5 in addition to the fan shape as shown in FIGS. 3 and 4. As shown in the figure, the directivity of the antenna can be further improved.

The wave guide hole 230 of the antenna body 200 is formed in the neck portion of each horn 220, and serves to radiate the frequency signal transmitted through the transmission line to the free space or from the free space. It transmits the received frequency signal to the transmission line. The length, diameter, or shape of the wave guide hole 230 may be appropriately changed according to the frequency band.

The transmission line of the antenna body 200 transmits a frequency signal between the wave guide hole 230 and the probe 320 installed in the housing 300. In the present invention, the antenna body 200 is an example thereof. By forming a cavity 240 on the bottom of the) it was possible to implement a stripline with air as a medium, thereby enabling a distribution role.

The housing 300 is installed in close contact with the bottom surface of the antenna body 200 and heats the heat of the power amplifier built in the microwave transceiver T to the antenna body 200. In the present invention, the housing 300 is an example. By forming a cavity 310 on the upper surface of the) to implement a stripline with air as a medium, and to install a probe 320 to transmit the frequency signal.

In addition, a housing space is formed inside the housing 300 so that the microwave transceiver T having a power amplifier can be installed therein, thereby absorbing heat generated from the power amplifier of the microwave transceiver T. By conducting heat conduction to the partition wall 220 and the horn 230 of the antenna body 200 to ensure efficient heat dissipation.

The distributor 400 is installed between the antenna body 200 and the housing 300 in order to distribute the signal amplified by the power amplifier of the microwave transceiver T to the plurality of horns 220. In this example, a conductor line distributor 400 is installed in the cavities 240 and 310 formed between the antenna body 200 and the housing 300 to implement a stripline.

Since the conductor forming the distributor 400 uses air having a dielectric constant of 1 as a medium, it cannot be mounted by floating between the cavities 240 and 310, but the antenna body as shown in FIG. 4 using quarter wave characteristics. The stripline may be implemented by coupling the bottom surface of the 200 and the top surface of the housing 300 to be short.

Therefore, the signal output from the power amplifier of the microwave transceiver T is passed through a strip line consisting of the cavity 240, 310 and the distributor 400 through the probe 320 installed in the housing 300. Dispensing transmission to the guide hole 230, the radiation is made through the horn 220. The received signal is transmitted to the microwave transceiver T through the reverse process.

The horn array antenna 100 of the present invention configured as described above has excellent directivity in spite of the open sides of the horn 220, and the partition 210 has a simple sawtooth shape, so that the horn array antenna 100 may be processed or molded in the manufacturing process. This is very easy, this makes the production of the product very easy and can greatly reduce the manufacturing cost.

In addition, since the horn array antenna 100 of the present invention is formed in an arc or parabolic shape as shown in FIG. 5 in addition to the fan shape, the horn array antenna 100 has improved gain and directivity than the general horn antenna due to its curved shape. It can be obtained, thereby improving the performance of products such as microwave repeaters.

And the horn array antenna 100 of the present invention can form a cavity 240, 310 as a transmission line to implement a strip line with air medium to minimize dielectric loss and conductor loss, and to minimize the size of the antenna It is possible to realize a small high-directional antenna.

Furthermore, since the horn array antenna 100 of the present invention has a built-in microwave transceiver (T) having a power amplifier through the housing 300, the appearance and weight of the horn array antenna 100 compared to the prior art that the antenna and the microwave transceiver are installed, respectively Can be greatly reduced.

In addition, since the horn array antenna 100 of the present invention has a structure in which the antenna body 200 and the housing 300 are in close contact with each other, the heat generated from the power amplifier is divided into the partition wall 210 and the horn 220 of the antenna body 200. It can dissipate through. Therefore, it is possible to achieve excellent cooling efficiency, thereby achieving component stability of the power amplifier.

Meanwhile, FIG. 6 shows another embodiment of the horn array antenna according to the present invention, and shows an example in which a plurality of horizontal grooves 211 are formed on each side of the partition wall 210 of the horn 220.

That is, as shown in FIG. 6, the horizontal grooves 211 formed in each of the partition walls 210 are small in size like a corrugated horn antenna and have a symmetric beam pattern and obtain a wide beam width radiation pattern. In addition, the level of the side lobe and back lobe is lower than that of the general streamlined horn, and the cross polarization can be reduced, thereby miniaturizing the overall appearance of the antenna.

Such embodiments of the present invention are merely illustrative of preferred examples, and the scope of the present invention is not limited thereto, and may be appropriately changed within the scope of the same idea.

1 is a perspective view showing an example of a conventional array antenna.

Figure 2 is a schematic diagram showing an example of a microwave repeater with an antenna installed in the prior art.

3 is a perspective view showing a horn array antenna according to the present invention.

Figure 4 is a cross-sectional view showing the structure of a horn array antenna according to the present invention.

5 is a cross-sectional view showing another embodiment of a horn array antenna according to the present invention;

Figure 6 is a perspective view of the antenna body showing another embodiment of a horn array antenna according to the present invention.

<Description of the code for the main part of the drawing>

100: horn array antenna 200: antenna body

210: bulkhead 211: horizontal groove

220: Horn 230: Wave Guide Hole

240: cavity 300: housing

310: cavity 320: probe

400: circuit T: microwave transceiver

Claims (8)

An antenna body 200 for transmitting and receiving a frequency signal by forming a plurality of partitions 210 and a fan-shaped horn 220 having both sides open between the partitions; A housing 300 installed in close contact with the antenna body 200; A distributor 400 installed in the cavities 240 and 310 formed between the antenna body 200 and the housing 300; Horn array antenna comprising a. The method of claim 1, wherein the antenna body 200 A plurality of partitions 210; A horn 220 formed between the partition walls 210 so that both sides have an open fan shape; A plurality of wave guide holes 230 arranged in each piece portion; Transmission line arranged to be connected to the wave guide hole 230 Horn array antenna, characterized in that consisting of. The horn array antenna according to claim 1 or 2, wherein the partition (210) has a serration shape. The horn array antenna of claim 1 or 2, wherein the horn (220) is arc shaped. The horn array antenna according to claim 1 or 2, wherein horizontal grooves (211) are further formed on the surfaces of the partition walls (210) on both sides of the horn (220). The horn array antenna according to claim 1, wherein the housing (300) has a transmission line and a probe (320) on an upper surface thereof. delete The horn array antenna of claim 1, wherein the housing (300) includes a microwave transceiver (T) having a power amplifier therein.

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