KR101314269B1 - Phase shifter for array antenna - Google Patents

Abstract

The present invention relates to an antenna phase shifter having improved characteristics by improving contact performance by equal force and enabling stable driving without backlash. The device of the present invention, the pinion gear for converting the linear motion of the rack gear into rotational motion; A first phase variable substrate having a first coupling pattern formed thereon and fixed to the reflective plate; A second phase variable substrate having a second coupling pattern formed therein and varying a phase by varying a coupling position of the first coupling pattern and the second coupling pattern according to the rotation of the pinion gear; A cushion plate for applying a uniform force to the entire surface of the second phase variable substrate to enable stable coupling with the first phase variable substrate; And a fixing plate for supporting the cushion plate, wherein the cushion plate is made of an elastic foam or a buffer plate to which an even force is applied to the entire surface of the phase change substrate, and the first phase change substrate and the second plate. The opposite patterned surface of the phase change substrate is coated with an insulating material to improve coupling characteristics.

Description

Antenna Phase Shifter {PHASE SHIFTER FOR ARRAY ANTENNA}

The present invention relates to a phase shifter of an antenna, and more particularly, to an antenna phase shifter which improves contact performance by an equal force and enables stable driving without backlash.

In general, an antenna used in a mobile communication base station may be implemented as an omni-directional omni-directional antenna or a directional sector antenna. A sector antenna is provided with a reflector or radio behind the antenna after installing an antenna composed of a radiating element and a reflector as a support. By installing an absorber, it is possible to transmit and receive radio signals only in a certain direction. In addition, each sector antenna has an array antenna in which a plurality of unit antennas are arranged vertically to communicate with a mobile communication terminal in a specific region by beam pattern characteristics and directivity characteristics. For example, an array antenna for a base station needs to tilt a beam pattern in a vertical direction in order to solve a shadow area, but is electrically tilted using a phase shifter without physically tilting the antenna.

The phase shifter and the array antenna, which are filed by the present applicant and registered in Korean Patent No. 1016681, have a swing driver which rotates left and right according to an operator's operation, and a phase shift that outputs a variable phase of a feed line according to the rotation of the swing driver. The phase shifter is configured to change the phase of the worm gear, including a worm gear that is rotated according to a driving force, and a worm wheel that rotates the rotary needle to change the phase of a signal passing through the track when the worm gear is rotated by the rotation of the worm gear.

The contact characteristics of two coupling plates facing each other in order to change the phase in the phase shifter are very important. Conventionally, since the spring is used, the force is applied unevenly to the coupling stage, resulting in poor characteristics. There is a problem that is not precise due to the backlash.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide an antenna phase shifter having improved characteristics by improving contact performance and enabling stable driving by an equal force.

In order to achieve the above object, the device of the present invention, the pinion gear for converting the linear motion of the rack gear into rotational motion; A first phase variable substrate having a first coupling pattern formed thereon and fixed to the reflective plate; A second phase variable substrate having a second coupling pattern formed therein and varying a phase by varying a coupling position of the first coupling pattern and the second coupling pattern according to the rotation of the pinion gear; A cushion plate for applying a uniform force to the entire surface of the second phase variable substrate to enable stable coupling with the first phase variable substrate; And a fixing plate for supporting the cushion plate.

The phase shifter includes a phase adjuster for converting the rotation of the handle into a linear motion, a connecting plate for transmitting the linear motion of the phase adjuster to the rack gear, and a rotation of the pinion gear according to the linear motion of the connecting plate. Driven by a drive member comprised of a rack gear, the rack gear and pinion gear are threaded rounded.

In addition, the cushion plate is made of an elastic foam or a buffer plate that can be applied evenly to the entire surface of the phase variable substrate, the pattern surface facing the first phase variable substrate and the second phase variable substrate is a coupling It is coated with insulating material to improve its properties.

According to the present invention, an even force is applied to the entire surface of the phase-variable substrate by the cushion plate to stabilize the characteristics, and an insulating material is coated on the coupling surface to improve the coupling characteristics.

1 is a perspective view of the antenna to which the present invention is applied;
2 is a perspective view of the antenna to which the present invention is applied;
3 is an enlarged view of a part of the antenna shown in FIG. 2;
4 is an exploded perspective view illustrating an antenna phase shifter according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features, and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings. The following examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention.

1 is a perspective view of the antenna to which the present invention is applied.

In the antenna 100 to which the phase shifter according to the present invention is applied, as shown in FIG. 1, five copiers 104 are vertically arranged in front of the reflector plate 102, and the power supplied to each copier 104 is As shown in FIG. 2, the phase is changed and fed through a phase shifter 120 installed on the rear surface of the reflector 102 to form a beam in a vertical direction, and the tilt angle of the beam is adjusted through the phase adjuster 106. It is adjustable.

2 is a perspective view of the antenna to which the present invention is applied, and FIG. 3 is a partially enlarged view of the antenna shown in FIG. 2, and FIG. 4 is an exploded perspective view of the antenna phase shifter according to the present invention.

Phase shifter 120 according to the present invention is installed on the back of the antenna reflector 102 as shown in Figure 2 is to be able to vary the phase of the signal fed to the copier 104 of the antenna, the present invention In the embodiment of the present invention, two phase shifters 120-1 and 120-2 are installed so that the phase can be changed by one driving member 110.

The driving member 110 for adjusting the phase by driving the phase shifter 120 includes a first connecting plate 112 and a first connecting plate 112 reciprocating in a linear direction according to the operation of the phase adjuster 106. A first rack gear 114 interlocked with 112 to drive the pinion gear of the first phase shifter, a second connecting plate 116 for transmitting the reciprocating motion of the first rack gear 114, and a second It consists of a second rack gear 118 in conjunction with the reciprocating motion of the connecting plate 116 to drive the pinion gear of the second phase shifter.

The rack gears 114 and 118 and the pinion gear 122 are rounded at the vertices of the threads 114a, 118a and 122a to remove the back lash. The motion is converted into a reciprocating motion to reciprocate the first connecting plate 112 up and down. The reciprocating motion of the first connecting plate 112 linearly moves the rack gear 114, and the linear motion of the rack gear 114 is converted into rotational motion through the pinion gear 122, thereby shifting the phase shifters 120-1 and 120-. The contact angle of 2) is changed.

Meanwhile, as illustrated in FIGS. 3 and 4, the phase shifter 120 according to the present invention includes a pinion gear 122 for converting a linear motion of the rack gear 114 into a rotational motion, and a first coupling pattern. A first phase variable substrate 124-1 formed on the reflective plate 102 and fixed to the reflecting plate 102, and a second coupling pattern is formed, and a coupling position between the first coupling pattern and the second coupling pattern is formed according to the rotation of the pinion gear 122. The second phase variable substrate 124-2 for varying the phase to vary the phase and the first phase variable substrate 124-1 with an equal force applied to the entire surface of the second phase variable substrate 124-2. Cushion plate 126 to enable a stable coupling, and a fixed plate 128 for supporting the cushion plate 126.

The cushion plate 126 is for improving the characteristics by applying an equal force to the entire surface of the phase-variable substrates, and is made of a foam or a buffer plate having the curved slit 126a formed thereon, and the first phase variable substrate 124-1. The opposite pattern surface of the second phase-variable substrate 124-2 is coated with an insulating material to improve coupling characteristics, and thus, the pattern may not be worn by rotation, thereby ensuring stable characteristics for a long time.

The pinion gear 122, the first phase variable substrate 124-1, the second phase variable substrate 124-2, the cushion plate 126, and the fixing plate 128 are provided with a rotating shaft (not shown) inserted into the through hole. The through hole of the second phase variable substrate 124-2 is integrally coupled to each other, and the protrusion 122b of the pinion gear 122 penetrates through the curved slit 124a of the first variable phase substrate 124-1. When the pinion gear 122 is rotated when the pinion gear 122 is rotated, the second phase variable substrate 124-2 is rotated within the allowable range of the curved slit 124a, so that the engagement position with the first phase variable substrate 124-1 is improved. It is intended to be variable.

When the phase shifter 120 according to the present invention adjusts the phase adjuster 106 when the antenna is installed, the rotational movement of the adjuster is converted into a reciprocating motion to reciprocate the first connecting plate 112 up and down. 1 The reciprocating motion of the connecting plate 112 linearly moves the rack gear 114, and the linear motion of the rack gear 114 is converted into rotational motion through the pinion gear 122, and when the pinion gear 122 is rotated, the reflector plate The second phase-variable substrate 124-2 is rotated within the allowable range of the curved slit 124a of the first phase-variable substrate 124-1 fixed to the 102 and the first phase-variable substrate 124-1. The coupling position of is varied so that the phase fed to the copier 104 is variable.

Thus, according to the present invention, the cushion plate 126 is applied to the entire surface of the phase-variable substrate by the equal force to stabilize the characteristics, the insulating material is coated on the coupling surface can improve the coupling characteristics.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

100: antenna 102: reflector
104: copier 106: phase adjuster
110: drive member 112, 116: connecting plate
114,118: rack gear 114a, 118a, 122a: thread
120,120-1,120-2: Phase shifter 122: Pinion gear
122b: protrusion 124-1: first phase variable substrate
124-2: second phase-variable substrates 124a and 126a: curved slit
126: cushion plate 128: fixed plate

Claims (5)

A pinion gear for converting linear motion of the rack gear into rotational motion;
A first phase variable substrate having a first coupling pattern formed thereon and fixed to the reflective plate;
A second phase variable substrate having a second coupling pattern formed therein and varying a phase by varying a coupling position of the first coupling pattern and the second coupling pattern according to the rotation of the pinion gear;
A cushion plate made of an elastic material foam or a buffer plate for applying a uniform force to the entire surface of the second phase variable substrate to enable stable coupling with the first phase variable substrate; And
An antenna phase shifter, characterized in that consisting of a fixed plate for supporting the cushion plate. The method of claim 1, wherein the phase shifter
A phase adjuster for converting the rotation of the handle into a linear motion, a connecting plate for transmitting the linear motion of the phase adjuster to the rack gear, and a rack gear for rotating the pinion gear according to the linear motion of the connecting plate. An antenna phase shifter, characterized in that driven by a drive member. The method of claim 2, wherein the rack gear and pinion gear
An antenna phase shifter characterized in that the threads are rounded. delete The patterned surface of claim 1, wherein the first phase variable substrate and the second phase variable substrate face each other.
An antenna phase shifter characterized by being coated with an insulating material to improve coupling characteristics.

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