KR102095900B1 - Horn antenna and Manufacturing method thereof - Google Patents

Abstract

The present invention relates to a horn antenna and a manufacturing method thereof. The horn antenna comprises: an electrode feeding portion (10); a forward-tapered and extended horn waveguide (21); and a radio wave transmission portion (20) integrally provided with a horn extension tube (22) extending rearward from a rear surface of the horn waveguide (21) so as to be coupled to a front end part of the electrode feeding portion (10). According to the present invention, antenna characteristics can be improved by reducing tolerance.

Description

Horn antenna and manufacturing method thereof

The present invention relates to a horn antenna and a method of manufacturing the same, and more specifically, the electrode part and the waveguide are respectively MCT-processed into one body, and the EDM-processed horn antenna so that the inner surface of the waveguide extends and extends at a predetermined slope and the manufacturing thereof It's about how.

In general, the size of the aperture formed in the waveguide of the horn antenna transmits and receives the radio wave in proportion to the wavelength of the radio wave. In addition, the horn antenna is provided with an inner waveguide, and thus the wavelength is inversely proportional to frequency, so the appearance may be very large at a low frequency, so the use of a horn antenna having a large volume and weight in actual production and operation is limited.

Therefore, the horn antenna has a low frequency radio wave, and as the wavelength increases, the horn antenna has an excessively large shape, and is generally used for transmitting and receiving radio waves in GHz or higher.

Since the horn antenna has uniform characteristics and high gain, it is mainly used as a standard antenna for beam pattern measurement, forms the tip of the waveguide in a trumpet shape, opens both sides of the waveguide, and then electrodes on one side of the waveguide Connect so that the radio waves travel through the waveguide and are radiated into the air. At this time, since there is no impedance matching between the waveguide and the air, a part of the radio waves is reflected, so all energy is not radiated into the air. Therefore, in the design of the horn antenna, the opening of the waveguide is gradually widened to match the impedance between the air and the waveguide, so that as much energy as possible is radiated from the opening.

Meanwhile, the performance of the antenna can be described in various ways. That is, the antenna's radiation efficiency (or "antenna efficiency") is defined as the ratio of the amount of power emitted by the antenna to the amount of power received from the antenna (from the power source).

That is, the electric wave power is the square of the base current of the antenna multiplied by the radiation resistance Rr, and the power supplied to the antenna is the base current of the antenna multiplied by the total resistance Ra of the antenna circuit. Therefore, the radiation efficiency is represented by Rr / Ra.

Ra is the sum of the high-frequency resistance, ground resistance, radiation resistance, resistance of the extension coil and the coupling coil, etc. of the antenna conductor, and in order to improve radiation efficiency, it is necessary to make resistances other than radiation resistance as much as possible. And, other antenna performance characteristics include operating frequency bandwidth, gain, directivity and antenna pattern.

As a related art, Korean Patent Publication No. 10-2008-0071953 (published on August 05, 2008) discloses a 'dual linear polarized horn array antenna'.

The prior art is a dual polarization horn array antenna that receives a first polarization, which is a polarization parallel to the equator of the earth, a H polarization (Horizontal Polarization), and a second polarization, which is a vertical polarization of the earth's equator, and the second polarization. A plurality of horns 10 to which polarization and the second polarization are incident; A plurality of polarization filtering units 20 respectively provided on the horns 10 and separating the first polarized wave and the second polarized wave incident together; A first polarization guide 30 for guiding the first polarization separated from the polarization filtering units 20; And a second polarization guide 50 for guiding the second polarization separated from the polarization filtering parts 20, wherein the horns 10 include an outer opening of the square shape and the polarization open to the outside. A square-shaped inner opening opened toward the filtering part 20 is formed, and a square ring-shaped protruding jaw protruding toward the central region by a predetermined width along the periphery of the inner opening is formed in the inner opening, and the outer opening is formed. The direction of each side of the parallel to the direction of each side of the inner opening, the upper portion of the polarization filtering portion 20 is a square cylinder shape, the lower portion of the polarization filtering portion 20 is a rectangular cylinder narrower than the width of the upper portion Shape, the second polarized wave is provided to the second polarization guide 50 connected to the lower portion of the polarization filtering portion 20 passing through the lower portion of the polarization filtering portion 20, the rectangular cylindrical shape, the second 1 Polarization is the above The first polarization guide 30 is provided through a passage formed in any one of the four walls formed on the upper portion of the polarization filtering portion 20 because it does not pass through the lower portion of the rectangular polarization filtering portion 20 having a rectangular cylindrical shape. , The passage is formed in a central region along the width direction of any one of the walls, and the width of the lower portion of the polarization filtering part 20 is narrowed in one direction and is formed in a rectangular shape.

However, the above-described prior art is composed of a plurality of horns, so that even if the antenna characteristics are improved, various members such as the first polarization guide 30 and the second polarization guide 50 are added, which inevitably occurs during the assembly process. There is a problem in that it is difficult to implement an antenna having a certain antenna characteristic due to a physical tolerance.

The present invention was created to solve the problems of the prior art as described above, and an object of the present invention is to provide a horn antenna and a method of manufacturing the radio wave transmission unit having a waveguide and an electrode coupled to an outer circumferential surface and being connected to the waveguide without any step difference. It is to provide a horn antenna and a method of manufacturing the same as the electrode feeders formed with furnaces, thereby reducing tolerances, improving antenna characteristics, and processing for a predetermined period of time to facilitate mass production.

The horn antenna according to the present invention for achieving the above object includes an electrode feeder provided with an electrode end on one side so that the electrode (P) is transmitted and received radio waves in the air; A radio wave transmission unit integrally provided with a mixed waveguide extending forward and tapered to facilitate transmission and reception of the radio wave, and a mixed extension pipe extending rearward from the rear surface of the hybrid waveguide so as to be coupled to a front end of the electrode feeder; It is made of; and the rear coupling fastener having a coupling hole through four corners in close contact with the rear surface of the electrode feeding portion and integrally coupled with the electrode feeding portion and the radio wave transmission portion.

The electrode feeder has an electrode exposed end pierced in a quadrangular shape so that an end of an electrode coupled to the electrode end is exposed, and an electrode end horn that extends forward and extends an inner surface at an end of the electrode exposed end so as to communicate with the mixed extension tube. It is provided, characterized in that the front center of the rear coupling fastener is provided with a reflective protrusion that protrudes forward so as to fit inside the rear surface of the electrode exposure end.

The radio wave transmission unit is characterized in that a width-deformed end tapered at one edge of the hybrid wave tube and the mixed extension tube is formed so as to extend to the transmission / reception band of the radio wave, and the width-deformed end is provided in pairs at corners corresponding to each other. .

The electrode end horn is characterized in that it is provided with an electrode width extension end tapered to correspond to the width deformation end.

The manufacturing method of the horn antenna according to the present invention includes an electrode feeding unit to which an electrode is coupled, and a transmission tube processing step of processing a transmission path by MCT inside a radio wave transmission unit through which radio waves emitted from the electrode are transmitted; An EDM blending step of more precisely EDM processing so as to reduce a tolerance between the electrode end horn and the curved surface of the horn waveguide among the transmission lines processed in the transmission tube processing step; A coupling end processing step of processing such that a tolerance is minimized in a cross section in close contact when the electrode feeding part and the radio wave transmission part are combined; A coupling hole through which the reflective protrusions inserted into the rear surface of the electrode feeder are formed so as to be integrally coupled with the rear coupling hole formed in the center of the front, the electrode feeder and the radio wave transmission part, and the tapping process of the electrode end into which the electrode is inserted into an EDM super drill. It is characterized by consisting of; step.

In the EDM blending step, a modification of processing a width-deformed end tapered at one edge of the mixed wave tube and the mixed length tube of the radio wave transmission part and an electrode width-extended end tapered to correspond to the width-deformed end of the electrode feeder of the electrode feeder It is characterized by having a single processing step.

Thus, the effects of the horn antenna and its manufacturing method according to the present invention are as follows.

First, since the electrode feeder having the electrode end and the radio wave transmitting unit having the mixed waveguide and the mixed extension tube are integrally processed and provided, the tolerances are reduced and the antenna characteristics are constant as compared to the conventional horn antenna which is disassembled and screwed. Lose,

Second, it is possible to mass-produce products with stable antenna characteristics for a predetermined time by making the band of the frequency transmitted by EDM processing the mixed wave tube of the radio wave transmission part, the electrode feeder part and the electrode single horn,

Third, by providing a width-deformed end tapered at a corner of the mixed wave tube and the mixed extension tube provided in the radio wave transmission unit, the bandwidth of the transmitted frequency is extended to improve antenna performance,

Fourth, by simplifying and provided with an electrode feeding part, a radio wave transmitting part, and a rear coupling fastener constituting the horn antenna, the assembly process is simplified, durability is enhanced, and the tolerance is reduced, thereby improving the characteristics of the antenna at high frequencies.

1 is a view for explaining a dual linear polarization horn array antenna according to the prior art,
2 is a view for explaining the horn antenna according to the present invention,
3 is a front view and a cross-sectional view of the horn antenna according to the present invention,
4 is a view for explaining the combined state of the horn antenna according to the present invention and the electrode feeder and the radio wave transmitting unit,
5 is a view for explaining a method of manufacturing a horn antenna according to the present invention.

Hereinafter, a horn antenna and a method of manufacturing the same according to the present invention will be described in detail with reference to the accompanying drawings.

The horn antenna of the present invention, as shown in Figures 2 to 4, the electrode feeder 10 is provided with an electrode terminal 11 on one side so that the electrode (P) to transmit and receive radio waves in the air; The elongated waveguide 21, which is tapered forward to facilitate the transmission and reception of the radio wave, and the elongated tube 22 extending rearward from the rear surface of the conduit waveguide 21 so as to be coupled to the front end of the electrode feeder 10 ) Is integrally provided with a radio wave transmission unit 20; A rear coupling fastener 30 having coupling holes 31 at four corners in close contact with the back surface of the electrode feeding part 10 and integrally coupled with the electrode feeding part 10 and the radio wave transmitting part 20; Is done.

Here, the outer shape of the electrode feeding portion and the radio wave transmission portion 20 is formed in a square pillar shape.

In addition, the electrode feeder 10 is exposed to the electrode end 11 of the electrode P coupled to the electrode end 11 in a rectangular shape so as to communicate with the electrode exposed end 12 and the mixing tube 22. The inner surface is extended forward from the end of the electrode exposure end 12, and an extended electrode end horn 13 is provided, and is fitted inside the rear surface of the electrode exposure end 12 at the front center of the rear coupling fastener 30. The reflection protrusion 32 protruding forward is provided as much as possible. That is, the outer circumferential surface of the reflective protrusion 32 is fitted to the inner circumferential surface of the electrode exposure end 12.

On the other hand, the radio wave transmission unit 20 is formed in a width-deformed end 23 tapered at one edge of the mixed wave tube 21 and the mixed extension tube 22 so as to extend to the transmission / reception band of the radio wave, and the width-deformed end 23 is provided as a pair at the corners corresponding to each other.

That is, the radio wave transmission unit 20 is provided in a form in which the width deforming end 23 formed at the corner of the rectangular mixed extension tube 22 extends to the circular mixed wave tube 21.

In addition, the electrode end horn 13 is provided with an electrode width extension end 13a tapered to correspond to the width deforming end 23, thereby facilitating transmission and reception of radio waves at the electrode P.

On the other hand, the manufacturing method of the horn antenna according to the present invention is an electrode feeder 10 to which the electrode P is coupled, and a transmission path inside the radio wave transmitting unit 20 through which radio waves emitted from the electrode P are transmitted. Transmission pipe processing step of processing (S10) and; An EDM mixing step (S20) in which the electrode end horn 13 of the transmission path processed in the transmission pipe processing step (S10) and the curved portion of the conduit waveguide 21 are EDM-processed; When the electrode feeder 10 and the radio wave transmission unit 20 is coupled, a combined end processing step (S30) of processing a cross-section that is in close contact with a plane; The coupling protrusion 30 inserted into the rear surface of the electrode feeding part 10 is penetrated so that the rear coupling hole 30 and the electrode feeding part 10 and the radio wave transmitting part 20 are integrally combined. It consists of a ball 31 and a tap processing step (S40) of EDM super-drilling the electrode end 11 into which the tab and the electrode P provided in the coupling hole 31 are inserted.

Here, in the EDM blend processing step (S20), the surfaces of the electrode end horn 13 and the waveguide 21 are precisely processed into curved surfaces of a predetermined angle, thereby improving directionality when transmitting radio waves, reducing resistance, and reducing antenna radiation efficiency. This will increase.

In addition, in the EDM blend processing step (S20), the width deformed end 23 tapered at one edge of the mixed wave tube 21 and the mixed tube 22 of the radio wave transmission section 20, and the electrode feeding section 10 ) Is provided with a modified end processing step (S21) for processing the tapered electrode width expansion end (13a) to correspond to the width deformation end 23 in the electrode end horn (13), the range of the transmission and reception frequency is expanded.

Looking at the operation of the horn antenna and the manufacturing method according to the present invention having the above configuration is as follows.

The horn antenna of the present invention includes an electrode feeder 10 having an electrode end 11 to which an electrode P is coupled, a radio wave transmitting unit 20 having an extended horn waveguide 21 tapered therein, and The coupling extension hole is extended to communicate with the coupling hole 31 of the rear coupling fixture 30 is coupled to the rear surface of the electrode feeder 10 and radiates radio waves emitted backward to the front. By being integrally coupled (not shown), it serves as an antenna.

In addition, the assembly process is simplified so that the step is minimized when the rear of the radio wave transmission unit 20 and the mixing tube 22 are combined with the electrode single horn 13, thereby increasing the radiation efficiency of the antenna.

In addition, the reflection protrusion 32 provided in the front center of the rear coupling fastener 30 is coupled to the rear surface of the electrode exposure end 12, and the outer circumferential surface of the reflection protrusion 32 is of the electrode exposure end 12. By being fitted in close contact with the inner circumferential surface, it is possible to prevent the antenna efficiency from being reduced due to tolerance.

On the other hand, the width deformed end 23 tapered to the radio wave transmission unit 20 is provided at corners corresponding to each other of the mixed wave tube 21 and the mixed tube 22, the mixed wave tube 21 and the mixed tube 22 By adjusting the width of), it serves to adjust the bandwidth of the radio wave transmitted and received.

In addition, the electrode width extension end 13a provided in the electrode end horn 13 is provided in a form of minimizing tolerance when combined with the horn extension tube 22, thereby increasing antenna efficiency.

In this way, the manufacturing method of the horn antenna of the present invention is to process the inner surfaces of the electrode feeding section 10 and the radio wave transmitting section 20 in the transmission pipe processing step (S10), and the electrode single horn in the EDM mixing processing step (S20). (13) and by precisely processing the curved surface of the mixed waveguide (21), by combining the tolerance between the electrode feeder 10 and the radio wave transmission unit 20, and by processing the mixed waveguide (21) to extend at a predetermined angle , It is possible to increase the efficiency of radio wave radiation.

In addition, the coupling end processing step (S30) is a process for minimizing the tolerance when the electrode feeding section 10 and the radio wave transmission section 20 are combined, and the coupling hole 31 and the electrode in the tap processing step (S40). By processing the electrode end 11 into which the (P) is inserted into the EDM super drill, the accuracy of the horn antenna is increased.

On the other hand, the EDM blend processing step (S20) is provided with a modified end processing step (S21), thereby processing the width deforming end 23 and the electrode width expanding end 13a to manufacture a horn antenna with an extended frequency band. There will be.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be implemented by any person skilled in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, such changes are within the scope of the claims.

<Description of reference numerals for main parts of drawings>
10: electrode feeding part 11: electrode end
12: electrode exposed end 13: electrode single horn
13a: electrode width extension stage 20: radio wave transmission unit
21: Hondo wave tube 22: Honyeon Minister
23: width deformed end 30: rear coupling fastener
31: coupling hole 32: reflection protrusion
S10: Transmission pipe processing step S20: EDM blend processing step
S21: Deformed end processing step S30: Combined end processing step
S40: Tap processing step
P: electrode

Claims (5)

An electrode feeder 10 having an electrode terminal 11 on one side so that the electrodes P through which radio waves are transmitted and received are coupled;
The elongated waveguide 21, which is tapered forward to facilitate the transmission and reception of the radio wave, and the elongated tube 22 extending rearward from the rear surface of the conduit waveguide 21 so as to be coupled to the front end of the electrode feeder 10 ) Is integrally provided with a radio wave transmission unit 20;
A rear coupling fastener 30 having coupling holes 31 through four corners in close contact with the back surface of the electrode feeding part 10 and integrally coupled with the electrode feeding part 10 and the radio wave transmitting part 20; Done,
The electrode feeder 10 has an electrode exposed end 12 pierced in a rectangular shape so that an end of the electrode P coupled to the electrode end 11 is exposed, and the electrode so as to communicate with the mixed tube 22. The inner surface is extended forward from the end of the exposed end 12, and an extended electrode end horn 13 is provided.
A reflective protrusion 32 protruding forward so as to fit inside the rear surface of the electrode exposure end 12 is provided at the front center of the rear coupling fastener 30;
The radio wave transmission unit 20 is formed with a width deformed end 23 tapered at one edge of the mixed wave tube 21 and the mixed tube 22 so as to extend to the transmission / reception band of the radio wave,
The width deformation end 23 is a horn antenna, characterized in that provided in a pair at the corners corresponding to each other. delete According to claim 1,
Horn electrode characterized in that the electrode end horn (13) is provided with a tapered electrode width expansion end (13a) to correspond to the width deformation end (23). An electrode feeding section 10 to which the electrode P is coupled, and a transmission pipe processing step (S10) of processing a transmission path inside the radio wave transmitting section 20 to which radio waves emitted from the electrode P are transmitted;
An EDM mixing step (S20) of EDM processing the curved end of the electrode end horn 13 and the conduit waveguide 21 among the transmission paths processed in the transmission tube processing step (S10);
When the electrode feeder 10 and the radio wave transmission unit 20 is coupled, a coupling end processing step (S30) of processing a cross-section that is in close contact with a plane;
The coupling protrusion 30 inserted into the rear surface of the electrode feeding part 10 is penetrated so that the rear coupling hole 30 and the electrode feeding part 10 and the radio wave transmitting part 20 are integrally combined. Consisting of a ball 31 and a tap processing step (S40) of EDM super-drilling the electrode end 11 into which the tab and the electrode P provided in the coupling hole 31 are inserted;
In the EDM blend processing step (S20)
The width deformed end 23 tapered at one edge of the mixed wave tube 21 and the mixed extension tube 22 of the radio wave transmission part 20 and the width of the electrode end horn 13 of the electrode feeding part 10 Method for manufacturing a horn antenna, characterized in that provided with a deformation step processing step (S21) for processing the tapered electrode width expansion end (13a) to correspond to the deformation end (23). delete

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