KR100878136B1 - Quadrifilar helical antenna - Google Patents

Abstract

A satellite transmitting/receiving antenna mounted in communication terminal is provided to increase durability by preventing deformation of an antenna radiator. A plurality of fillers is included in outer circumference of a bobbin. A micro strip line part matches antenna impedance and a power source impedance, is connected to the fillers in outer surface of the bobbin, and includes a dielectric, outer side pattern parts(32a, 32b), and a ground part. The outer side pattern part and the ground part are connected by a penetration hole passing through the dielectric. The outer side pattern part is connected to the fillers. A signal pattern part including a plurality of extension parts is connected to the fillers. The outer side pattern part includes a signal supplying part connected to a signal line from a communications terminal.

Description

Satellite transmitting and receiving antenna {Quadrifilar Helical Antenna}

The present invention relates to an antenna, and more particularly, to a satellite transmit and receive antenna mounted to a communication terminal for transmitting and receiving a signal from a satellite.

In general, a satellite transmit / receive antenna is a device for transmitting and receiving a signal from a satellite operated according to a satellite digital multimedia broadcasting (DMB) system.

DMB (Digital Multimedia Broadingcasting) is a broadcasting service that provides a variety of multimedia signals such as voice and video digitally and provides it to mobile phones, car receivers, PDA phones, etc., and is currently widely used in Korea. Since high-quality sound and high-definition broadcasting are possible, the structure of the receiver itself is being developed to simplify the volume.

As an example of a conventional satellite transmit / receive antenna, a quadrefill spiral antenna includes four pillars spirally installed to operate at about 1575 MHz. Such quad refiller spiral antennas provide a drive point impedance of about 50 ohms because they are typically suitable for matching 50 ohms characteristic impedance coaxial cables.

Conventional quad-refiller spiral antennas are self-radiating structures that operate without ground planes or counterpoises, but when placed in close proximity to a wireless transmit / receive handset, the handset structure is very similar to the antenna's radiation pattern. Electromagnetic wave reflection may affect the impedance, and these effects have a negative effect on the performance of the antenna. Therefore, the structure includes an impedance matching unit to solve this problem.

An example of such an impedance matching unit is disclosed in Korean Patent No. 0553555, "Antenna having four spiral radiator structures."

Since a conventional impedance matching unit needs to select and mount a tuning device suitable for testing antenna operating characteristics, a printed circuit board for mounting the tuning device has been used.

Since the printed circuit board for the impedance matching unit is soldered (soldering) to the bottom of the filler and coupled, there is a problem that the manufacturing process is complicated and not easy.

On the other hand, the conventional filler is provided in the film of the thin plate, there is a problem that such a film is broken, such as easily bent or buckled to form a tube without a core material.

In addition, the flexible tubular body is formed by rolling a flat film and attaching it in a cylindrical shape, and it is difficult to connect the front ends of the flat film to each other, and production is not easy.

Therefore, the present invention has been created to improve the problems of the conventional satellite transceiver antenna as described above, can easily match the antenna characteristic impedance can simplify the manufacturing process, reduce the parts and increase the durability Its purpose is to provide a satellite transmit and receive antenna.

In order to achieve the above object, an antenna according to the present invention comprises: a bobbin; A plurality of fillers provided on an outer circumferential surface of the bobbin; And a microstrip line part electrically connected to the pillars on an outer surface of the bobbin and matching an antenna impedance with a power supply impedance.

Preferably, the microstrip line portion comprises a dielectric having a predetermined dielectric constant; An outer pattern portion attached to an outer side of the dielectric; And a ground portion attached to the opposite side of the outer pattern portion with respect to the dielectric.

Preferably, the outer pattern portion and the ground portion are electrically connected by through holes penetrating through the dielectric.

The outer pattern part may include: a signal pattern part electrically connected to the pillars and having a plurality of extension parts; And a signal supply unit electrically connected to the pillars and connected to a signal line from a communication terminal.

Preferably, the contact portion extends from the filler toward the signal pattern portion for contact between the signal pattern portion and the filler, and the contact portion is formed adjacent to the extension portions at a predetermined distance.

It is preferable that the filler is connected to one end of the signal pattern part and the other end to the signal supply part.

The dielectric may be formed of polyimide.

The outer pattern portion and the ground portion may be formed of copper (Cu).

The bobbin may be made of a rigid body.

The filler is preferably provided on the outside of the dielectric having a predetermined dielectric constant.

Preferably, the present invention further includes a printed circuit board provided on the bobbin and configured to combine the plurality of fillers into a plurality of pairs.

As described above, according to the antenna according to the present invention, the introduction of the microstrip line design method allows the antenna characteristic impedance to be easily matched without the use of a tuning element, and the rigid core can be used to prevent deformation of the antenna radiator. It is effective to increase the durability by preventing.

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

1 to 5, an antenna according to an embodiment of the present invention includes a bobbin 10, a plurality of fillers 20 provided on an outer circumferential surface of the bobbin 10, and an outer surface of the bobbin. It includes a microstrip line portion 30 is provided in electrical connection with the pillars.

The bobbin 10 is a rigid body made of a tubular shape.

The filler 20 is provided outside the dielectric 25 having a predetermined dielectric constant.

The microstrip line unit 30 serves to match the antenna impedance with the power supply impedance and is manufactured by a design method of a microstrip line.

That is, the microstrip line portion 30 has a dielectric constant having a predetermined dielectric constant, outer pattern portions 32a and 32b attached to the outer side of the dielectric 31, and an outer side with respect to the dielectric 31. And a ground portion 33 attached to the opposite side of the pattern portions 32a and 32b.

The dielectric 25 provided with the filler 20 and the dielectric 31 of the microstrip line part 30 are formed of the same polyimide.

Polyimide is flame retardant, has high mechanical strength and impact strength, good dimensional stability, and good electrical insulation and wear resistance. The dielectric constant of polyimide is 2.5-2.9. The outer pattern portions 32a and 32b and the ground portion 33 are made of copper (Cu).

The microstrip line unit 30 allows the antenna impedance and the power supply impedance to be matched by a combination of the impedance value calculated by the characteristic impedance calculation formula of the microstrip line and the impedance of the filler 20.

As shown in FIG. 5, the microstrip line portion is formed by the dielectric constant ε _r and the thickness h of the dielectric 31 and the width W and the thickness t of the outer pattern portions 32a and 32b. A characteristic impedance value of 30 is determined.

Due to the characteristics of the polyimide, in particular, the dielectric constant and the conductivity of copper, the use of polyimide as the dielectric and copper as the material for the outer pattern portions 32a, 32b and the ground portion 33 is suitable for the microstrip line. Suitable for designing.

The outer pattern portions 32a and 32b and the ground portion 33 are electrically connected to each other by through holes 32ab and 32ba passing through the dielectric 31 as conductors.

The outer pattern portions 32a and 32b include a signal pattern portion 32a having a plurality of extension portions 32aa, and a signal supply portion 32b to which the signal line 1 is connected from the communication terminal. The signal line 1 is connected to the communication terminal by the connector 2.

The signal pattern part 32a and the signal supply part 32b are electrically connected to the fillers 20, respectively.

The extension parts 32aa of the signal pattern part 32a change the impedance value according to the extended width and length.

As shown in FIG. 4, the contact portion 20a extends from the filler 20 toward the signal pattern portion 32a for contact between the signal pattern portion 32a and the filler 20.

The contact portion 20a is formed adjacent to the extension portions 32aa at a predetermined distance.

The impedance value varies according to the junction 32ac of the extension part 32aa and the contact part 20a. Therefore, by adjusting the position of the junction portion 32ac of the extension portion 32aa and the contact portion 20a, it is possible to match the impedance value to match the antenna characteristics.

The signal supply unit 32b is connected to and connected to the signal line 1 from the communication terminal, and supplies an electric signal to the filler 20.

Since the impedance value varies depending on the position of the junction portion 32bb between the signal supply part 32b and the filler 20, the junction position can be adjusted to indicate an impedance value suitable for the antenna characteristic.

The gap between the signal supply part 32b and the filler 20, the gap between the extension parts 32aa, and the thickness of the dielectric 31 all serve as capacitors to change the impedance value. .

The microstrip line portion 30 can replace the role of a conventional tuning element, thereby eliminating the need for a lower printed circuit board on which the tuning element is mounted.

In addition, since the dielectric material 31 is used as the polyimide, and the microstrip line design method is used, the filler 20 can be supported by using a rigid core such as the bobbin 10. 31 and the filler 20 and the microstrip line portion 30 can be easily coupled.

One end of the filler 20 is connected to the signal pattern part 32a and the other end is connected to the signal supply part 32b.

A printed circuit board 40 is provided on the bobbin 10 to combine the plurality of fillers 20 into a plurality of pairs.

The pillar 20 is composed of two pairs of first pillars 21 and 22 and second pillars 23 and 24 electrically connected across the printed circuit board 40.

The first pillars 21 and 22 are positioned on opposite sides of the printed circuit board 40, respectively, and are spirally wound with the same inclination angle along the outer circumferential surface of the bobbin 10.

The second pillars 23 and 24 are wound at the same inclination angle with a phase difference of 90 degrees with the first pillars 21 and 22.

The first filler 21 and the second filler 23 are connected to the signal pattern part 32a by the contact part 20a, and the other first filler 22 and the second filler 24 are the signal supply part 32b. )

Dielectric 25 and microstrip line portion 30 to which the filler 20 is attached are attached to the outer side of the bobbin 10 by a double-sided tape or an adhesive.

Reference numeral 3 is an antenna case.

1 and 2 are perspective views showing a satellite transmitting and receiving antenna according to an embodiment of the present invention,

3 is a side view of FIG. 2;

4 is an exploded view of the satellite transmit / receive antenna shown in FIG. 2;

FIG. 5 is a schematic cross-sectional view taken along the line A-A of FIG. 4.

※ Explanation of code about main part of drawing ※

10: bobbin 20: filler

21,22: first filler 23,24: second filler

25 Dielectric 30 Microstrip Line Part

31 dielectric 32a signal pattern portion

32aa: extension part 32ab: through hole

32ac: junction 32b: signal supply

32ba: through hole 32bb: junction

33: ground portion 40: printed circuit board

Claims (12)

Bobbin; A plurality of fillers provided on an outer circumferential surface of the bobbin; And And a microstrip line unit electrically connected to the pillars on an outer surface of the bobbin and matching an antenna impedance with a power supply impedance. The microstrip line portion may include a dielectric having a predetermined dielectric constant; Outer pattern portions 32a and 32b attached to the outside of the dielectric; And a ground part attached to an opposite side of the outer pattern parts 32a and 32b about the dielectric. The outer pattern portions 32a and 32b and the ground portion are electrically connected by through holes penetrating through the dielectric. The outer pattern portions 32a and 32b may include: a signal pattern portion electrically connected to the pillars and having a plurality of extension portions; And a signal supply unit electrically connected to the pillars and connected to a signal line from a communication terminal. delete delete delete The method of claim 1, wherein the filler, A satellite transmitting and receiving antenna, characterized in that one end is connected to the signal pattern portion and the other end is connected to the signal supply portion. The method of claim 5, And a contact portion extending from the filler toward the signal pattern portion for contact between the signal pattern portion and the pillar, wherein the contact portion is formed adjacent to the extension portions at a predetermined distance. The method of claim 5, And a printed circuit board provided on the bobbin and configured to combine the plurality of fillers into a plurality of pairs. The method of claim 7, wherein the filler, And two pairs of two pillars connected by the printed circuit board as a pair, one of each pair of pillars connected to the signal pattern unit, and the other to the signal supply unit. The method of claim 1, The dielectric is a satellite transceiver, characterized in that formed of polyimide (Polyimide). The method of claim 1, And the outer pattern portion (32a) and the ground portion are formed of copper (Cu). The method of claim 1, The bobbin is a satellite transmission and reception antenna, characterized in that consisting of a rigid body. The method of claim 1, The filler is a satellite transmitting and receiving antenna, characterized in that provided on the outside of the dielectric having a predetermined dielectric constant.

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