KR20040073714A - Omnidirectional receive type satellite antenna - Google Patents

Abstract

PURPOSE: An omnidirectional receive type satellite antenna is provided to reduce costs by eliminating the necessity of using a device for tracking position of a satellite. CONSTITUTION: An omnidirectional receive type satellite antenna comprises a dome shaped support portion having a hollow interior; and a pattern layer(60) formed into a constant thickness all over the outer surface of the dome shaped support portion, in such a manner that satellite signals are received in all directions. The support portion is formed into a semi-spherical shape having a convex upper side, and made of an insulating material for preventing interferences with the satellite signal received at the pattern layer.

Description

Omnidirectional receive type satellite antenna}

The present invention relates to the structure of the omni-directional receiving satellite antenna, and in particular, because the device used to direct the satellite to the satellite so that the satellite signal transmitted from the satellite can be received in all directions because of this because The present invention relates to an omni-directional receiving satellite antenna structure in which the cost is reduced.

In general, satellite antennas are installed so that the direction of the main beam always enhances the satellites during installation. In particular, a moving object such as a vehicle adjusts the direction of the satellite antenna according to the satellite signal received from the satellite so that the main beam can always face the satellite.

As shown in FIG. 1, the conventional first satellite antenna structure includes a rotary plate 21 rotated to the left and a right, a drive motor 13 to drive the rotary plate 21, and the rotary plate 12. And a control unit (not shown) for controlling the driving motor according to the satellite signal received from the satellite and the planar antenna 11 installed above.

Here, the planar antenna 11 is formed such that the main beam has an oblique beam pattern, and the control unit drives the driving motor 13 according to the satellite signal received from the satellite, so that the rotating plate 12 is left and right. When rotated, the planar antenna 11 always faces the satellite.

However, the conventional first satellite antenna structure configured as described above has a low overall height because the planar antenna 11 is installed in parallel on the rotating plate 12, but the planar antenna 11 has an inclined beam pattern. Therefore, the antenna gain is low, and because of having a large side beam, there is a problem that it is vulnerable to the ambient interference.

As shown in FIG. 2, the second satellite antenna structure according to the related art for solving the above problems is located in a hemispherical dome and receives an antenna unit 20 for receiving satellite signals from the satellite, and the antenna A satellite position tracking unit (not shown) for identifying the position of the satellite through the satellite signal received from the unit 20 and generating and outputting a satellite tracking signal, and according to the satellite tracking signal output to the satellite position tracking unit. It is configured to include a rotating unit 30 for rotating the antenna unit 20.

Here, the rotation unit 30 receives a motor driving signal from the satellite position tracking unit driving motor 32 for driving the pulley 31 coupled with the drive shaft, and the driving motor 32 is coupled to the upper surface The rotating force generated by driving the rotating body 33 to which the antenna unit 20 coupled to a predetermined angle and the pulley 31 coupled to the driving motor 32 is transmitted through the timing belt 34. It consists of a fixed pulley 35 to receive and transfer to the rotating body (33).

However, the structure of the conventional second satellite antenna structure as described above is fixedly installed through the bracket, which is fixed in a flat horizontal area such as a vehicle. Not only does it work properly, but the antenna unit 20 is fixed in a state of maintaining a predetermined angle, when moving the inclined place, the antenna unit 20 is further inclined by the inclined angle effect of the ambient interference There is a problem that the satellite signal is not properly received by.

In addition, the first and second satellite antenna structure according to the prior art as described above is a satellite tracking that is used to move the planar antenna 11 and antenna unit 20 toward the satellite in accordance with the satellite signal. There is a problem that not only the configuration is complicated by the apparatus for the purpose, but also the cost accordingly.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and its object is to enable the antenna to receive satellite signals in all directions so that devices for moving the antenna towards the satellite are not used. Accordingly, the present invention provides a omni-directional receiving satellite antenna structure that can reduce cost and improve price competitiveness.

1 is a view showing a structure of a first satellite antenna according to the prior art;

2 is a view showing a structure of a second satellite antenna according to the prior art;

3 is a plan view showing the omni-directional receiving satellite antenna structure according to the present invention;

4 is a side view showing the omni-directional receiving satellite antenna structure according to the present invention;

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

<Explanation of symbols on main parts of the drawings>

50: support portion 60: pattern layer

The omnidirectional satellite antenna structure according to the present invention for solving the above problems is formed with a dome-shaped support portion having a hollow inside and having a constant thickness over the entire area of the outer surface of the support portion so that the satellite signal is in all directions. It is configured to include a pattern layer to be received for.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. For reference, the embodiments disclosed herein are only presented by selecting the most preferred embodiment in order to help those skilled in the art from the various possible examples, the technical spirit of the present invention is necessarily limited or limited only by this embodiment It is not to be understood that various modifications and changes can be made without departing from the spirit of the present invention, as well as other equivalent embodiments.

3 and 5, the omnidirectional satellite antenna structure according to the present invention has a hemispherical shape of which the upper side is convex and has an empty dome-shaped support part 50 and the entire area of the outer surface of the support part 50. It is formed to have a predetermined thickness and comprises a pattern layer 60 to receive a satellite signal received from the satellite in all directions.

Here, the support unit 50 is fixed to the roof panel of the vehicle by a bracket or the like when installed on a moving object such as a vehicle.

In addition, the support part 50 is made of an insulating material, and when the satellite signal is received by the pattern layer 60 formed on the outer surface of the support part 50, interference occurs in the received satellite signal by the support part 50. This can be prevented in advance.

On the other hand, the pattern layer 60 having a predetermined thickness on the outer surface of the support 50 allows the satellite signal to be received in all directions.

In other words, the satellite signal is divided into a horizontal polarization and a vertical polarization according to its propagation type. The horizontal polarization means a radio wave emitted from a vertical antenna by a radio wave whose polarization plane is perpendicular to the earth. Therefore, in the case of receiving the vertical polarization, the antenna must be vertical to receive the vertical polarization.

The horizontally polarized wave is an electromagnetic wave whose polarization plane is constant and is directed in the horizontal direction. Therefore, when receiving the radio wave of the horizontal polarization, the element of the antenna should be horizontal.

Therefore, since the pattern layer 60 is formed over the entire area of the outer surface of the support part 50, since the horizontal polarization and the vertical polarization can be received, the satellite tracking device or the like is not used. Since the cost can be reduced, it is possible to use not only a moving object such as a vehicle, but also a ground fixed type and a personal portable type.

The omni-directional receiving satellite antenna structure according to the present invention configured as described above comprises an empty dome-shaped support portion and a pattern layer formed having a predetermined thickness over the entire area of the outer surface of the support portion, thereby preventing from the satellite. Since both horizontal and vertical polarization transmitted can be received, a device for tracking the position of the satellite used to direct the antenna to the satellite is unnecessary, and thus, the cost required can be reduced.

In addition, since the horizontal polarization and the vertical polarization can be received, not only a moving object such as a vehicle, but also can be used as a ground fixed type and a personal portable type, so that the application range can be expanded.

Claims (2)

Dome-shaped support part with empty inside, And a pattern layer formed to have a predetermined thickness over the entire area of the outer surface of the support part to receive satellite signals in all directions. The method of claim 1, The support portion is formed in a hemispherical convex upwards, The omni-directional reception satellite antenna structure, characterized in that made of an insulating material to prevent interference with the satellite signal received by the pattern layer.