KR100947239B1 - Antenna using the reflector of a multitude - Google Patents

Abstract

The present invention relates to an antenna using multiple reflectors. More specifically, a printed element is formed on the substrate by using a printed board, a reflection unit, a radiation unit, a waveguide unit is formed, and a plurality of reflecting plates are provided, so that the front and rear ratio is very good and it is used for a special relay such as high-gain mobile communication. It relates to an antenna using a plurality of reflectors.

According to the present invention, an antenna using a plurality of reflectors includes: a reflector (10) installed at a rear side of a radiator (20) at a predetermined interval and reflecting the radio waves radiated from the radiator (20) to the front; A third reflecting plate 15 which reflects the radio wave radiated backward from the radiator 20 radiating the radio wave forward and is installed flatly at a predetermined distance from the rear surface 19; A fourth reflecting plate 16 which starts at the rear surface 19 positioned at the rear of the third reflecting plate 15 to be inclined to reflect the radio wave received directly from the outside to seek F / B and high gain; Starting from the rear surface 19, the fourth reflecting plate 16 is installed to be inclined at a predetermined interval and serves to dissipate the remaining radio waves passing through the fourth reflecting plate 16 so that the F / B is very high. 5 reflector plate 17; A radiating unit 20 installed at a front end of the reflecting unit 10 at a predetermined interval to radiate the electric wave fed from the feed line 22; And a waveguide part 30 installed at the front of the radiation unit 20 to induce forward and reflected radio waves forward from the radiation unit 20 to the front.

Reflector, Printed Element, Short Bar, Substrate, Radiant, Barun, Waveguide

Description

ANTENNA USING THE REFLECTOR OF A MULTITUDE

The present invention relates to an antenna using multiple reflectors. More specifically, a printed element is formed on the substrate by using a printed board, a reflection unit, a radiation unit, a waveguide unit is formed, and a plurality of reflecting plates are provided, so that the front and rear ratio is very good and it is used for a special relay such as high-gain mobile communication. It relates to an antenna using a plurality of reflectors.

In general, the present antenna is used for a mobile communication antenna. The substrate used for the antenna has the advantage of good propagation characteristics and delicate manufacturing. Dipole antennas are also widely used in mobile communication antennas. Dipole antenna is an element installed inside the antenna has the letter T shape and radiates the supplied electric wave vertically or horizontally with polarization. It is widely used for mobile communication relay.

The current mobile communication is making a lot of development, and the direction of the development is miniaturization and simplicity.

In other words, the size of the antenna is getting smaller and the production is simplified and the installation is pursued.

In addition, antennas with good radio emission characteristics are preferred.

Due to this background, many antennas have been developed. However, conventional antennas have a large size and are large in size, and using an element made of a conductive material is inconvenient to manufacture and difficult to obtain characteristics suitable for use.

In addition, there is a problem that the radio wave radiation characteristics are not good.

In addition, the conventional antenna has a problem in that expensive supplementary equipment is required because the F / B (front and rear ratio) is bad and the close distance can not be relayed at the same frequency.

In addition, there is a problem that interference occurs by the antenna and the equipment.

Accordingly, the present invention has been made to solve the above problems, by forming a printed element on the substrate using a printed substrate, forming a reflecting portion, a radiation portion, a waveguide portion and having a plurality of reflecting plates, the front and rear ratio is very good and gain Its purpose is to provide an antenna that is easily adapted to its use and used for special relays, such as high-gain mobile communications.

According to the present invention, an antenna using a plurality of reflectors includes: a reflector (10) installed at a rear side of a radiator (20) at a predetermined interval and reflecting the radio waves radiated from the radiator (20) to the front; A third reflecting plate 15 which reflects the radio wave radiated backward from the radiator 20 radiating the radio wave forward and is installed flatly at a predetermined distance from the rear surface 19; A fourth reflecting plate 16 which starts at the rear surface 19 positioned at the rear of the third reflecting plate 15 to be inclined to reflect the radio wave received directly from the outside to seek F / B and high gain; Starting from the rear surface 19, the fourth reflecting plate 16 is installed to be inclined at a predetermined interval and serves to dissipate the remaining radio waves passing through the fourth reflecting plate 16 so that the F / B is very high. 5 reflector plate 17; A radiating unit 20 installed at a front end of the reflecting unit 10 at a predetermined interval to radiate the electric wave fed from the feed line 22; And a waveguide part 30 installed at the front of the radiation unit 20 to induce forward and reflected radio waves forward from the radiation unit 20 to the front.

In addition, the reflector 10 includes a substrate 13 formed of a resin; An element 11 formed on an upper surface of the substrate 13 and having a circular shape and made of copper; And a short bar 12 shorting the two side-by-side elements 11 which are folded in the central portion of the element 11.

In addition, the radiation unit 20 forms a plate 13 made of a resin; An element 11 formed on an upper surface of the substrate 13 and having a circular shape and made of copper; A short bar 12 positioned at an electronic proper point of the two side-by-side elements 11 folded at the center of the element 11 and shorting the element 11; A balun (21) installed in the middle of the two side-by-side elements (11) folded in the central portion of the element (11) to feed radio waves; And a feeder line 22 connected to the balun 21 and coupled to the connection connector to supply radio waves.

In addition, the circular element 11 is characterized in that a wide thickness.

In addition, the radiation unit 20 is characterized in that it generates a vertical polarization and a horizontal polarization at the same time.

In addition, the short bar 12 adhered to the element 11 and the balun 21 are characterized in that the reactance.

In addition, it is characterized in that the reaction between the end of the two side-by-side of the element 11 and the short bar 12, which is bent at the central portion of the element 11 is a reactance.

In addition, it is characterized in that the tuning section (R) that is responsible for the tuning of the entire antenna between the end of the two parallel element 11, which is bent at the center of the element 11 and the short bar 12.

In addition, the waveguide 30 may include a substrate 13 formed of a resin; And a waveguide part 14 formed on the upper surface of the substrate 13 and having a circular or rhombus shape and made of copper.

As described above, according to the present invention, a printed element is formed on the substrate to form a printed element, a reflecting portion, a radiation portion, a waveguide portion, a plurality of reflecting plates, and the front-to-back ratio is very good. The antenna used for the special relay is easy to manufacture and install because the printed board is used, and the gain and the front and rear ratio (F / B) outperforms the parabola.

In addition, due to the reflection plate is blocked from the outside radio waves do not cause interference and the directivity is high enough not to cause interference with the relay device, the system can be installed in the same place without installing the transmitter and the receiver separately from each other to reduce the installation cost It also works.

In addition, since the antenna of the present invention generates a vertical wave and a horizontal wave at the same time, it is easy to refraction and diffraction, which is advantageous in eliminating the hearing loss region.

As well as. While the general loop antenna has a gain in the first reflector, the antenna of the present invention has an effect of increasing the apparent gain in both the reflector and the reflector.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention.

In this case, detailed description thereof will be omitted.

1 is a perspective view of an antenna using multiple reflectors according to a preferred embodiment of the present invention.

Referring to FIG. 1, the present invention includes a reflector 10 installed at a rear of the radiator 20 at a predetermined interval and reflecting the radio waves radiated from the radiator 20 to the front; A third reflecting plate 15 which reflects the radio wave radiated backward from the radiator 20 radiating the radio wave forward and is installed flatly at a predetermined distance from the rear surface 19; A fourth reflecting plate 16 which starts at the rear surface 19 positioned at the rear of the third reflecting plate 15 to be inclined to reflect the radio wave received directly from the outside to seek F / B and high gain; Starting from the rear surface 19, the fourth reflecting plate 16 is installed to be inclined at a predetermined interval and serves to dissipate the remaining radio waves passing through the fourth reflecting plate 16 so that the F / B is very high. 5 reflector plate 17; A radiator 20 installed at a front end of the reflector 10 at a predetermined interval and radiating radio waves fed from the feed line 22; It is installed in front of the radiation unit 20 is composed of a wave guide portion 23 for guiding the radio wave forward and reflected radio wave forward from the radiation unit 20 to the front.

The reflector 10 is located at the front end of the third reflector 15 and is provided with two printed substrates in parallel with two substrates at a predetermined interval.

The two reflectors 10 installed serve to reflect the radio waves emitted from the radiator 20 to the front.

The third reflecting plate 15 is supported and installed by the support pillar 18 flatly at a predetermined distance from the rear surface 19, and the radio wave propagated backward from the radiation unit 20 is reflected by the reflecting unit 10. And the non-reflected radio waves are reflected by the third reflector 15.

The fourth reflector 16 is inclined starting from the rear surface 19 positioned behind the third reflector 15 and is installed around the third reflector 15. To reflect forward radiation.

The fifth reflector plate 17 is installed at an inclined interval with the fourth reflector plate 16 starting from the rear surface 19.

The fifth reflector 17 plays a main role of blocking the radio waves coming from the outside in addition to reflecting the transmitted radio waves again without being reflected from the fourth reflector 16.

The third reflecting plate 15, the fourth reflecting plate 16, and the fifth reflecting plate 17 can be made of various materials, but can be made of aluminum, copper, iron, or the like.

The reflector 10 and the third, fourth, and fifth reflector plates 15, 16, and 17 described so far reflect the radio waves emitted from the radiator 20 forward, and the reflectance is very high, so that the front and rear ratio is parabolic. It is characterized by high as an antenna.

In addition, the interference is not generated by blocking the radio waves coming from the outside by the fourth and fifth reflector plates 16 and 17 surrounded by the hat, and is used as a relay antenna in the repeater.

In addition, the directivity is so high that it does not interfere with the relay, it can be installed in the near distance without installing the system has the advantage of low installation cost.

The radiation unit 20 is located at the front end of the reflector 10 and consists of one printed board. And it receives a radio wave fed from the feed line 22 through the bar 21 serves to radiate the radio wave to the element (11).

Although the waveguide 30 will be described with reference to FIG. 6, but only the element 11 without the short bar 12, the waveguide 30 is positioned at the front end of the radiation unit 20 and the same shape substrate can be continuously installed to increase the gain of the antenna. have.

2 is a side cross-sectional view of an antenna using multiple reflectors in accordance with a preferred embodiment of the present invention.

Referring to FIG. 2, as described with reference to FIG. 1, the fourth reflecting plate 16 and the fifth reflecting plate 17 having a hat shape are provided, and the fourth reflecting plate 16 and the fifth reflecting plate 17 are provided. The space is formed in between.

The support pillar 18 is installed in the center of the support pillar 18 has a form that is coupled to the rear (19) is standing.

The third reflecting plate 15 is installed at a predetermined distance from the rear surface 19, and the reflecting unit 10 is installed at the front end of the third reflecting plate 15, and the copying is provided at the front end of the reflecting unit 10 at a predetermined interval. The unit 20 is installed.

As described above, a feature of the present antenna is that a plurality of reflecting plates are provided.

As a result, the front-to-back ratio (F / B) of the radio wave is good and does not cause interference.

3 is a plan view of a reflector of an antenna using multiple reflectors according to a preferred embodiment of the present invention.

Referring to FIG. 3, the reflector 10 shown in the drawing may include a substrate 13 formed of a resin and forming a plate; An element 11 formed on the upper surface of the substrate 13 and having a circular shape and made of copper; And a short bar 12 for shorting the two side by side elements 11 that are folded in the center of the element 11.

The substrate 13 is a circuit board generally used, and a copper layer is usually formed on a plate such as synthetic resin or silicon.

The substrate 13 as described above is installed in parallel with the flat surface, the element 11 is formed on the upper surface.

The element 11 is formed in the shape shown in the drawing in which the circle and one side are separated and the other side is separated and folded in the copper layer of the substrate 13 to form the element 11 through etching.

The element 11 thus formed is used for the reflecting portion 10 and the radiating portion 20, and the circular element 11 is formed to be thicker than the waveguide portion 14 of the waveguide 30.

The short bar 12 serves to form the element 11 as a circuit, and is installed in a short form at an electronic proper point of the folded element 11 of the element 11 having a circular shape. .

In addition, the short bar 12 should be installed by adjusting its position according to the characteristics of the antenna.

4 is a plan view of a radiator of an antenna using multiple reflectors according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the radiation unit 20 shown in the drawing includes a substrate 13 formed of a resin and forming a plate; An element 11 formed on the upper surface of the substrate 13 and having a circular shape and made of copper; A short bar 12 which short-circuits the ends of two side-by-side elements 11 broken in the center of the element 11; A balun 21 which is installed in the middle of two side by side elements 11 folded in the center of the element 11 and feeds radio waves; A feeder line 22 connected to the balun 21 and coupled to the connection connector to supply radio waves.

 The substrate 13, the element 11, and the short bar 12 are as described with reference to FIG. 2, and the feature elements further configured in the present radiation unit 20 are the balun 21 and the feed line 22.

The balun 21 is connected to the duplex of the feeder line 22 to the element 11 of the duplex which is bent, respectively, and is coupled.

Radio waves are supplied to the connected line and transmitted to the element 11 to radiate radio waves.

The feeder line 22 is a special line used for high frequency and serves to receive the radio wave generated by the radio wave generator and supply it to the balun 21.

In addition, the tuning section R shown in the drawing is a section that does not exist in the conventional antenna and the concept is not established, and it can be seen that its length is long, unlike the conventional antenna.

The tuning section R has a unique function of tuning the entire antenna so that the gain can be increased in the same shape and stacking of the waveguide 30.

In addition, the radiation unit 20 is a vertical wave and a horizontal wave at the same time, the refractive and diffraction is easy to be suitable for eliminating the hearing loss.

5 is an equivalent circuit of an antenna using multiple reflectors according to a preferred embodiment of the present invention.

Referring to FIG. 5, when the element 11 is fed through the balun 21, the position of the short bar 12 is determined by the Q matching at the electronic proper point. Similarly, a series and parallel connection of inductance L and capacitance C is formed.

As described above, the inductance L and the capacitance C become reactance, and the tuning circuit is formed by the reactance, so that resonance occurs in the radiation unit 20, thereby generating radio waves.

The resonance generated as described above also affects the reflector 10 and the waveguide 30 to maintain the radio wave transmission characteristics with the element 11 having the same shape.

6 is a plan view of a waveguide of an antenna using multiple reflectors according to a preferred embodiment of the present invention.

Referring to FIG. 6, as shown in the drawing, the waveguide 30 forms a plate and includes a substrate 13 made of resin; It is formed on the upper surface of the substrate 13 and has a circular shape, made of copper, and a thin waveguide element 14; consists only of.

The waveguide element 14 of the waveguide 30 forwards the radio waves radiated from the third, fourth, and fifth reflector plates 15, 16, 17, the reflector 10, and the radiator 20. It plays a role in inducing good radiation.

Therefore, the circuit forming element such as a short bar is formed only of the waveguide element 14 made of copper which can obtain a resonance effect, and the waveguide portion 30 having the same shape without any design change is increased to increase the gain of the antenna. Continued installation can increase its gain.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1 is a perspective view of an antenna using multiple reflectors according to a preferred embodiment of the present invention;

2 is a side cross-sectional view of an antenna using multiple reflectors in accordance with a preferred embodiment of the present invention;

3 is a plan view of a reflector of an antenna using multiple reflectors according to a preferred embodiment of the present invention;

4 is a plan view of a radiator of an antenna using multiple reflectors according to a preferred embodiment of the present invention;

5 is an equivalent circuit of an antenna using multiple reflectors according to a preferred embodiment of the present invention;

6 is a plan view of a waveguide of an antenna using multiple reflectors according to a preferred embodiment of the present invention.

             <Description of Symbols for Main Parts of Drawings>

      10: reflecting portion 11: element

      12: Short Bar 13: Substrate

      14: waveguide element

      15: Third Reflector 16: The Fourth Reflector

      17: Fifth Reflective Plate 18: Support Column

      19: Rear side 20: Copy unit

      21: Barun 22: Feeder

      30: waveguide R: tuning section

Claims (9)

In the antenna using a multiple reflector, A reflector 10 installed at a rear side of the radiation unit 20 at a predetermined interval and reflecting the radio waves radiated from the radiation unit 20 to the front; A third reflecting plate 15 which reflects the radio wave radiated backward from the radiator 20 radiating the radio wave forward and is installed flatly at a predetermined distance from the rear surface 19; A fourth reflecting plate 16 which starts at the rear surface 19 positioned at the rear of the third reflecting plate 15 to be inclined to reflect the radio wave received directly from the outside to seek F / B and high gain; Starting from the rear surface 19, the fourth reflecting plate 16 is installed to be inclined at a predetermined interval and serves to dissipate the remaining radio waves passing through the fourth reflecting plate 16 so that the F / B is very high. 5 reflector plate 17; A radiating unit 20 installed at a front end of the reflecting unit 10 at a predetermined interval to radiate the electric wave fed from the feed line 22; And A waveguide part 30 installed at the front of the radiation unit 20 to guide the radio wave radiated forward and reflected from the radiation unit 20 to the front; Including but not limited to: The reflector 10 includes a substrate 13 that forms a plate and is made of resin; An element 11 formed on an upper surface of the substrate 13 and having a circular shape and made of copper; And A short bar 12 which short-circuits the two side-by-side elements 11 which are folded in the center of the element 11; Antenna using a plurality of reflectors, characterized in that consisting of. delete The method of claim 1, wherein the copy unit 20 A substrate 13 forming a plate and made of resin; An element 11 formed on an upper surface of the substrate 13 and having a circular shape and made of copper; A short bar 12 positioned at an electronic proper point of the two side-by-side elements 11 folded at the center of the element 11 and shorting the element 11; A balun (21) installed in the middle of the two side-by-side elements (11) folded in the central portion of the element (11) to feed radio waves; And A feed line 22 connected to the balun 21 and coupled to a connection connector to supply radio waves; Antenna using a plurality of reflectors, characterized in that consisting of. 4. The element 11 according to claim 1, wherein the element 11 is circular. An antenna using multiple reflectors, characterized in that the thickness is wide. The method of claim 3, wherein the copy unit 20 An antenna using multiple reflectors, characterized in that both vertical and horizontal polarization is generated at the same time. The method of claim 3, wherein An antenna using multiple reflectors, characterized in that there is a reactance between the short bar (12) and the balun (21) bonded to the element (11). The method of claim 3, wherein Antennas using multiple reflectors, characterized in that there is a reactance between the ends of the two side-by-side elements (11) and the short bar (12), which are bent at the center of the element (11). The method of claim 3, wherein Using a plurality of reflectors, characterized in that between the end of the two side-by-side of the element 11 and the short bar 12, which is bent at the center of the element 11 is a tuning section (R) that is responsible for tuning the entire antenna antenna. The method of claim 1, wherein the waveguide 30 A substrate 13 forming a plate and made of resin; And And a waveguide element (14) formed on the upper surface of the substrate (13) and having a circular or rhombus shape and made of copper.

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