KR100662733B1 - The slot antenna for waveguide - Google Patents

Abstract

The present invention relates to a waveguide slot antenna for transmitting and receiving frequencies from a satellite by placing the frequencies transmitted and received through an antenna in a horizontal state without installing them at the same angle as that of the satellite. Characterized in that the radiator having a slot and a radiator to receive the feed and the feeder coupled with the radiator to collect frequencies into one place are positioned in a horizontal state and receive a predetermined angle to receive from the satellite. It is possible to transmit and receive frequencies from satellites by placing them in a horizontal state without installing the frequencies transmitted and received through antennas at the same angle as the angles of satellites. Freely adjust the element size and height to receive all frequency bands It receives the signal from each element, gathers the frequency by using the waveguide line, and increases the number of element arrays, which can easily increase the gain.

Antennas, waveguides, slots, projections, satellites,

Description

The slot antenna for waveguide

1 is a perspective view showing a radiation portion of the waveguide slot antenna according to the present invention.

Figure 2a is a rear view showing a feeder of the waveguide slot antenna according to the present invention.

Figure 2b is a plan view showing a feeder of the waveguide slot antenna in accordance with the present invention.

Figure 3 is a coupled state of the radiation unit and the power supply unit of the waveguide slot antenna according to the present invention coupled.

4 is an embodiment showing another configuration of FIG.

5 is an embodiment showing another configuration of FIG.

Figure 6 is a plan view showing a state in which n radiating parts are formed in the feed section of the waveguide slot antenna according to the present invention.

7 is an embodiment showing another configuration of FIG.

Figure 8a is a side view showing the radiation angle of the waveguide slot antenna according to the present invention.

Figure 8b is an embodiment showing another configuration of Figure 8a.

Figure 9 is a graph showing the antenna gain ratio of the waveguide slot antenna according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: copy unit 11: body

12: copy line 13: slot

14: copying projection 15: fixing member

16: coupling hole 20: feeder

21: feeding hole 21a: first feeding hole

21b: Power Feeder Hall 21c: Power Feeder Hole 3

21d: 4th Feed Hole 22: Waveguide

22a: first waveguide line 22b: second waveguide line

22c: third waveguide line 23: inductive post

23a: first inductive post 23b: second inductive post

23c: third inductive post

24: fastening hole

The present invention relates to a slot antenna for waveguides, and more particularly, to transmit and receive frequencies from a satellite by placing the frequencies transmitted and received through the antenna in a horizontal state without installing them at the same angle as the angle of the satellite. It relates to a slot antenna for waveguides.

In general, a waveguide is a kind of transmission line for transmitting electromagnetic energy of high frequency over microwaves, and is formed of an electrical conductor such as copper to transmit electromagnetic waves inside a pipe. There is a kind of high-pass filter, and radio waves with a wavelength longer than the cutoff wavelength cannot be transmitted. In addition, the wavelength of the wave transmitted along the axis of the waveguide is called the inner tube wavelength and is longer than the aftershock wave.

It is a hollow metal tube, a kind of high-pass filter. The mode of the tube has a certain cutoff wavelength, and the basic mode is determined by the size of the waveguide. In low frequency, the transmission path by two copper wires is usually used. Due to this, the loss of the conductor is increased and the dielectric loss of the surrounding insulator is increased, but the transmission of electromagnetic waves in the waveguide reflects each other between the walls of the inside of the waveguide.

In addition, the waveguide has the advantage of low attenuation compared to the parallel two-wire or coaxial cable has been used mainly for high power in the microwave transmission line. The waveguide has various cross-sectional shapes and is divided into a circular waveguide, a square waveguide, an elliptical waveguide, and the like according to the cross-sectional shape.

In addition, after the development of a dielectric material having a low loss even at a high frequency, a microstrip patch array antenna using a dielectric substrate is put into practical use, and a small antenna is manufactured and used. However, the dielectric loss due to the characteristics of the dielectric substrate inevitably occurs, and the resistance loss of the conductor occurs, which makes it difficult to manufacture a high-gain antenna and has a limitation in commercialization due to the high price of the dielectric substrate.

The waveguide slot antenna, which uses slotted holes in a conventional waveguide without using such a dielectric material, has a longer history than a planar antenna using a dielectric material, but has a large size, weight, precision in manufacturing process, and difficulty in working with the dielectric. The situation is pushed by a plane antenna using a material.

In particular, waveguide slot antennas are more difficult to design than planar antennas using dielectric materials, and are more likely to exhibit grating lobe characteristics, making it difficult to produce high gain antennas.

In the case of a general waveguide antenna, the antenna is directed at the angle at which the satellite is located to transmit and receive frequencies from the satellite. There is also a problem that the antenna does not come out of a uniform shape.

An object of the present invention can be easily manufactured as a waveguide-type antenna, and can freely adjust the size and height of the element to enable reception of all frequency bands, and receives a signal from each element to collect frequencies using waveguide lines, The objective is to provide a slot antenna for waveguides that allows for easy gain gains by increasing the number of element arrays.

In addition, there is another object to provide a waveguide slot antenna that can be freely formed in the shape of the antenna, and is not limited by space at the time of installation.

The present invention for achieving the above object is a waveguide antenna for receiving a frequency from a satellite, the radiation unit having a slot and a radiator to receive the frequency from the satellite combined with the radiation unit to the frequency in one place It is an object of the present invention to provide a slotted antenna for waveguides, characterized in that the feeder for collecting is positioned in a horizontal state and has a predetermined direction angle so as to be received from the satellite.

Radiation consisting of a body formed to penetrate the radiation line in the longitudinal direction to receive a frequency from the satellite, and a fixed member having a coupling hole formed integrally at one end of the body to be fixed to the following feeding section part; And having a same size as the radiation line of the body so that the frequency received from the satellite can be received by the slot member for waveguides, characterized in that it comprises a feeding member fixed to the fixing member and the bolt have.

Hereinafter, the waveguide slot antenna according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a plan view showing a radiating part of the waveguide slot antenna according to the present invention, Figure 2a is a plan view showing a feeder of the waveguide slot antenna according to the present invention, Figure 2b is a feed of the waveguide slot antenna according to the present invention Figure 3 is a front view showing all, Figure 3 is an installation state showing a state in which two slots installed in the copying unit according to the invention, Figure 4 is an embodiment showing another configuration of Figure 3, Figure 5 is another of Figure 3 FIG. 6 is a plan view showing a state in which n radiating parts are formed in a feeding part of a waveguide slot antenna according to the present invention, FIG. 7 is an embodiment showing another configuration of FIG. 6, and FIG. 8 is a side view showing the radiation angle of the waveguide slot antenna according to the present invention, Figure 8b is an embodiment showing another configuration of Figure 8a, Figure 9 is a graph showing the antenna gain ratio of the waveguide slot antenna according to the present invention.

In describing the configuration of the present invention according to the drawings, the configuration of the additional components such as the LNB, the antenna control panel, etc. installed in the antenna is a general configuration, and thus, the present invention does not refer to the configuration of the additional components. Only the configuration will be mentioned.

1 to 9, the radiation unit 10 having a slot 13 and a radiation projection 14 so as to receive a frequency from the satellite, combined with the radiation unit 10 where the frequency It is characterized in that the feeder 20 to be collected in a horizontal state is positioned in a horizontal state and the directivity of the frequency received from the satellite is a predetermined angle, the frequency directivity can receive satellites and satellite signals in each country By adjusting the width and length of the slot 13, it can be configured by adjusting the orientation angle received from the satellite at any angle.

The waveguide slot 13 antenna according to the present invention is integrally formed at one end of the body 11 and the body 11 formed so as to penetrate the radiation line 12 in the longitudinal direction in order to receive the frequency from the satellite. And a radiation unit 10 made up of a fixing member 15 having a coupling hole 16 so that the body 11 can be fixed to the power supply unit 20 to be described below, and a frequency received from the satellite. It has the same size as the radiation line 12 of the body 11 and is configured to include a feeder 20 is fixed to the fixing member 15 and the bolt.

A slot 13 is formed on the side of the body 11 in the longitudinal direction to receive and transmit a frequency from the satellite, and a slot 13 is formed on the side of the body 11 of the radiator 10 to be received from the satellite. Radiation projections 14 to adjust the reception angle of the frequency is formed, the radiation projections 14 formed on the body 11 is bent at one side of the position where the slot 13 is formed 'c' letter (dejaja) A groove is formed.

And, by adjusting the width and the length of the slot 13 formed in the radiator 10 can be arbitrarily adjusted the direction angle received from the satellite, and the height of the radiation projection 14 formed in the radiator 10 and By adjusting the width, the directivity angle received from the satellite can be arbitrarily adjusted.

The feeding hole 21 and the waveguide line 22 are formed at an angle of 90 degrees in the longitudinal direction of the feeding portion 20, and the waveguide line 22 is formed at one side of the feeding hole 21 in a right direction.

When the waveguide line has an angle of 90 degrees in the horizontal direction in the longitudinal direction of the feed section 20, the first feed hole 21a is formed inward.

A first waveguide line 22a having a predetermined length on both sides with respect to the first feed hole 21a and transmitting and receiving frequencies is formed, and is bent in a perpendicular direction to the first waveguide line 22a. A second feed hole 21b is formed, and a second waveguide line 22b having a predetermined length on both sides around the second feed hole 21b and transmitting and receiving frequencies is formed. A third feed hole 21c is formed in a direction perpendicular to the waveguide line 22b, and a fourth feed hole 21d is formed in which a frequency is transmitted and received from the satellite in a direction perpendicular to the third feed hole 21c. .

Inductive posts 23 are formed in the centers of the first, second, and third feed holes 21a, 21b, and 21c formed inside the feed part 20 so that the frequency to be transmitted can be divided. The inductive post is composed of first, second and third inductive posts 23a, 23b, 23c.

Then, one side of the feeder 20, the copy unit 10 is installed to face each other is installed symmetrically.

In addition, the feed hole 21, the waveguide line 22, and the inductive post 23 are formed symmetrically with respect to the first feed hole 21a formed in the feed part 20.

In addition, the material of the radiation unit 10 and the power supply unit 21 is coated on the surface of the coating unit (not shown, the radiation unit and the feed unit is coated with a metallic material that can receive a frequency to the metal, synthetic resin) ) Is formed of a material, characterized in that the coating is formed by mixing with Ni, Cu, H₂SO₄, CuSO₄, EX, 5H₂OH₃BO₃, NISO₄, 6H₂O.

Looking at the effect of the waveguide slot 13 antenna according to the present invention configured as described above are as follows.

First, referring to the manufacturing process of the waveguide slot 13 antenna according to the present invention, the waveguide antenna typically has a process of manufacturing the antenna by casting, but the process by the casting is already known and publicly known technology, and specific technology is mentioned. I never do that.

The manufacturing process of the waveguide slot 13 antenna is performed by casting and injection. In the case of injection, the radiation unit 10 and the power feeding unit 20 of the present invention are formed by using a synthetic resin. Metallic coating parts (not shown, the outer and inner surfaces of the radiating part and the feeding part, which can receive a frequency, etc. in each of the holes and lines formed on the outer periphery and the inner side of the radiating part 10 and the feeding part 20 formed therein) Coating on the frequency reception passage) to receive the frequency, and the coating part is made of Ni, Cu, H₂SO₄, CuSO₄, EX, 5H₂OH₃BO₃, NISO₄, 6H₂O, as mentioned above.

The radiation unit 10 and the power supply unit 20 are formed of a metal material or a synthetic resin material, and the coupling hole 16 and the power supply unit formed in the fixing member 15 integrally formed on one side of the radiation unit 10. The radiating part 10 is fixed to the position of the fastening hole 24 formed at 20 so that the copying part 10 cannot be separated from the feeding part 20 by a bolt.

At this time, the position of the radiation line 12 formed in the radiation unit 10 and the position of the fourth feed hole 21d formed in the power supply unit are correctly aligned so that the satellite frequency received through the radiation unit 10 is supplied. It can be received smoothly through the whole (20).
In the state in which the copy unit 10 is fixedly installed in the feed unit 20, the copy unit 10 and the feed unit 20 may receive a frequency from the satellite without maintaining the reception angle toward the satellite. The frequency is received through the slot 13 formed on the side of the copying unit 10, in which the received reception rate depends on the size (length in the longitudinal direction formed on the body 11) and the height (width) of the slot 13. This is regulated.

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And the receiving angle received from the antenna is adjusted according to the height, width of the radiation projection 14 formed on one side of the slot 13, which is desired by the width of the 'c'-shaped groove formed inside the radiation projection 14 As it accepts the frequency, it is possible to design the half wavelength of the frequency to be used and to maintain the flatness to prevent diffuse reflection. The depth of the 'c' groove is very important, which is the width over which the frequency is received.

In addition, the direction of the beam is determined by the depth of the 'c' groove, but in the present invention, the depth is formed as shown in the drawing to direct the 45 degree direction, and according to the depth of the 'c' groove, etc. The direction of the beam can be reversed.

Since the depth of the 'c'-shaped groove depends on the characteristic that the wave is introduced into the waveguide, it should be designed smaller than half wavelength according to the desired frequency, and the position of the slot 13 should be adjusted accordingly. In this case, the beam width is determined by the length of the slot 13.

As described above, the radiation projections 14 formed to receive the half wavelengths are conventional. Anyone skilled in the art can easily design, and this configuration enables the antenna to receive the frequency of the satellite without always facing the satellite at a predetermined angle in order to receive the frequency from the satellite.

As shown in FIG. 9, the direction of the beam receiving the frequency is changed through the designed antenna as described above, and the graph shown in FIG. 9 calculates the data through the 'net analyzer'.

The copy unit 10 and the power supply unit 20 is not provided with only one, as shown in FIG. 1, as shown in FIGS. In order to manufacture a variety of antennas.

By installing a plurality of antennas of the radiation unit 10, the gain of the antenna can be increased, so that the reception rate is improved.

As explained above, the antenna is always at a certain angle towards the satellite. Since the antenna can be deviated from the stereotype that it should be facing, there is an advantage in that the antenna can be manufactured in various forms when manufacturing the satellite antenna through the antenna of the present invention.

In addition, since the satellite antenna is manufactured through the antenna of the present invention, the use of the car, bus, airplane, train, ship, company, home and business offices has the advantage of reducing the restriction of the space.

The present invention is not limited as shown in the drawings, the body 11, the radiation projection 14 and the power supply portion 20 of the radiation unit 10 can accept the half-wave frequency through various forms of deformation. Antennas designed to be within the scope of the claims of the present invention.

The present invention has the effect of transmitting and receiving the frequency from the satellite by placing the frequency transmitted and received through the antenna in a horizontal state without installing at the same angle as the satellite angle.

In addition, it can be easily manufactured as a waveguide type antenna, and it is possible to freely adjust the element size and height so as to receive all frequency bands, receive signals from each element, collect frequencies using waveguide lines, and set the number of element arrays. Increasingly, the effect can be easily increased.

Claims (13)

In the waveguide antenna for receiving a frequency from a satellite, A copy unit having a slot and a projection to receive a frequency from the satellite, and a feed unit coupled to the copy unit to collect the frequency in one place is positioned in a horizontal state to be 45 degrees (°) to receive from the satellite A waveguide slot antenna having an angle. In the waveguide slot antenna, A radiation unit including a body formed to penetrate a radiation line in a longitudinal direction to receive a frequency from a satellite, and a fixing member integrally formed at one end of the body and having a coupling hole to fix the body; Waveguide slot antenna, characterized in that it comprises a feeder having the same size as the radiation line of the body and fixed with a bolt so that the frequency received from the satellite can be received. The method of claim 2, Longitudinal hole is formed in the longitudinal side of the body slot slot for waveguides, characterized in that the slot is further formed to transmit and receive frequencies from the satellite. The method of claim 2, Waveguide slot antenna, characterized in that the radiation projection to adjust the receiving angle of the frequency received from the satellite is formed on the body side of the radiator further formed '' 'groove. The method according to claim 2, wherein Waveguide slot antenna, characterized in that the receiving angle of the frequency received from the satellite is adjusted according to the size of the slot formed in the body of the radiator. The method according to claim 2, wherein Radiating projection formed on the body is a waveguide slot antenna, characterized in that formed on one side of the slot is formed. The method of claim 2, When the waveguide line formed in the feeder has an angle of 90 degrees in the horizontal direction in the longitudinal direction of the feeder, a re-feeding hole formed inward is formed, and has a predetermined length at both sides with respect to the feeder hole and has a frequency. A first waveguide line for transmitting and receiving is formed, and a second feed hole bent in a direction perpendicular to the first waveguide line is formed, and has a predetermined length on both sides with respect to the second feed hole and transmits a frequency. And a second waveguide line for receiving is formed, and a third feed hole is formed in a direction perpendicular to the second waveguide line, and a fourth feed hole for transmitting and receiving frequencies from the satellite is formed in the direction perpendicular to the third feed hole. A slot antenna for waveguides. The method according to claim 2 or 7, Waveguide slot antenna, characterized in that the center of the first, second, third feed hole formed inside the feed section further comprises an inductive post so that the frequency to be transmitted is divided. The method of claim 2, Waveguide slot antenna, characterized in that the one side of the feeder is installed symmetrically installed so as to face each other. The method according to claim 2 or 7, The waveguide slot antenna for the waveguide, characterized in that the waveguide line, the rapid contact hole, the inductive post is formed symmetrically about the first feed hole formed in the quick contact portion. The method according to claim 1 or 2, Waveguide slot antenna, characterized in that the direction of the frequency received from the satellite can be arbitrarily adjusted by adjusting the width and length of the slot formed in the radiator. The method of claim 1, Waveguide slot antenna, characterized in that by adjusting the height and width of the radiation projection formed in the radiation portion can be arbitrarily adjusted the direction angle received from the satellite. The method according to claim 1 or 2, The radiation portion and the material of the rapid contact portion is a waveguide slot antenna, characterized in that the metal, synthetic resin is applied to the coating material of a metallic material that can receive a frequency formed of one of the materials to form a coating.

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