KR200266292Y1 - Turning device for satellite antenna - Google Patents

Abstract

The present invention relates to a rotating device for a satellite antenna,

The conventional satellite antenna is a means for rotating the antenna in the horizontal direction. The second motor is installed vertically on the inner bottom of the main body so that the antenna rotates in a desired direction according to the rotation direction of the second motor. If the wire continues to rotate in one direction, the wires connecting the antenna unit and the board are twisted, and in some cases, the wire is disconnected. In order to prevent this, a separate connection is required to prevent the wire from being twisted in the middle of the wire. The device must be installed, but the price of the device is so high that the production cost of the product was increasing.

Accordingly, the present invention for solving the above problems is to install a guide that is rotated several times in a spiral on the bottom surface of the rotating plate, the moving surface to form a moving projection to move along the guide, the moving protrusions are adjacent to both ends of the guide By installing the sensor to detect the position of the satellite antenna, the rotating plate rotates forward and reverse every time the moving protrusion is detected by the sensors on both sides, so that the twist of the wire connecting the antenna unit and the board The present invention relates to a rotary antenna for a satellite antenna, which can be prevented and expected to simplify the structure of the product and reduce the production cost.

Description

Turning device for satellite antennas

The present invention relates to a rotating device for a satellite antenna, in particular a guide that is rotated several times in a spiral shape on the bottom surface of the rotating plate, forming a moving projection to move along the guide on the upper surface of the fixing plate, moving near the both ends of the guide By installing the sensor to detect the projection, when the rotating plate rotates to set the position of the satellite antenna, the rotating plate repeats forward and reverse rotation whenever the moving protrusion is detected by both sensors. The present invention relates to a rotary antenna for a satellite antenna, which can prevent twisting and expect an effect of simplifying a product structure and reducing a production cost.

Satellite antennas receive various signals such as video signals and audio signals from satellites. Satellite antennas are an indispensable device in satellite broadcasting.

1 shows a conventional satellite antenna,

A predetermined space is formed inside the main body 1, and a support jaw 11 protrudes inwardly in the main body 1, and a bearing 12 is formed on an upper surface of the support jaw 11.

The upper surface of the main body 1 is coupled to the rotating plate 3, and the lower surface of the rotating plate 3 is provided with a mounting portion 6 having a predetermined size for mounting the first motor 7, and the mounting portion 6 is combined with the bearing 12 so that the rotating plate 3 can rotate smoothly.

On one side of the upper surface of the rotating plate 3, the vertical plate 4 is coupled to rotate upward at a predetermined angle, and the thin film satellite antenna 5 is attached to the surface of the vertical plate 4, and the satellite antenna 5 Is connected to the distribution via the LNB.

In the mounting portion 6, a vertical adjusting means for transferring the vertical plate 4 in the vertical direction is provided, and the vertical adjusting means has a first motor 7 formed in the mounting portion 6, and The screw 8 is held by the first motor 7, and the conveying part 9 is coupled to the screw 8 so that the conveying part 9 is rotated forward and backward according to the driving direction of the first motor 7. ) Is configured to advance back and forth.

In addition, a separate connecting table 10 is formed at the bottom of the transfer unit 9 and the vertical plate 4 so that the vertical plate 4 rotates upward or downward at an angle according to the forward and backward movement of the transfer unit 9.

A rectangular guide hole 2 is formed on the upper surface of the rotating plate 3 to allow the connecting table 10 to penetrate therethrough, and a second motor 13 is vertically installed on the inner bottom of the main body 1. The rotary shaft of the second motor 13 is coupled to the bottom of the mounting portion 6.

Accordingly, as the second motor 13 rotates forward and backward, the rotating plate 3 rotates in the horizontal direction, thereby allowing the antenna 5 to rotate in a desired direction.

However, the conventional satellite antenna is a means for rotating the antenna in the horizontal direction. Since the second motor is vertically installed on the inner bottom of the main body, the antenna rotates in the desired direction according to the rotation direction of the second motor. 2 If the motor continues to rotate in one direction, the wires connecting the antenna and the board are twisted, and in some cases, the wires are disconnected. To prevent this, separate wires are not allowed to be twisted in the middle of the wires. Had to install a connecting device, but the price of this device was so expensive that the production cost of the product was increasing.

Accordingly, the present invention for solving the above problems is to install a guide that is rotated several times in a spiral on the bottom surface of the rotating plate, the moving surface to form a moving projection to move along the guide, the moving protrusions are adjacent to both ends of the guide By installing the sensor to detect the position of the satellite antenna, the rotating plate rotates forward and reverse every time the moving protrusion is detected by the sensors on both sides, so that the twist of the wire connecting the antenna unit and the board It is an object of the present invention to provide a rotary antenna for a satellite antenna, which can prevent and reduce the structure of the product and reduce the production cost.

The present invention for achieving the above object

In the satellite antenna is mounted to the upper side of the fixed plate, the case is equipped with a satellite antenna on the upper end of the rotating plate,

A fixed gear fixed to a center of an upper surface of the fixed plate;

A rotor coupled to the upper part of the fixed gear so as to be capable of rotating independently, and the rotor plate coupled to the upper end thereof as a bolt;

A guide having a predetermined length in parallel to protrude in a predetermined length on a bottom surface of the rotating plate, and being formed spirally toward the center from the outer surface of the rotating plate so that the moving protrusion moves between the guide protrusions when the rotating plate rotates;

First and second sensors installed at both ends of the guide to sense that the moving protrusion is close to each other and to supply the detection signal to the control device;

A guide rod which is formed on the upper surface of the fixed plate in a straight line from the outer shell to the center;

A moving protrusion inserted into the guide rod so as to be movable and having an upper end inserted between the guide protrusions of the guide to move along the guide when the rotating plate rotates;

A drive motor installed downward on one side of the fixed gear and driven by a control voltage supplied from a control device by rotating the shaft thereof in a drive gear to rotate the drive gear forward and backward to rotate the rotating plate; Characterized in that consisting of.

1 is a cross-sectional view showing a conventional rotary device for a satellite antenna.

2 is a perspective view showing a satellite antenna of the present invention.

Figure 3 is a cross-sectional view showing a rotary device for a satellite antenna of the present invention.

Figure 4 is an exploded perspective view showing a rotating device of the present invention.

※ Explanation of code for main part of drawing

20: fixing plate, 21: seating groove,

22: fixed gear, 23: rotor,

24: drive gear, 25: drive motor,

26: guide rod, 27: moving protrusion,

30: turntable, 31: guide,

32: first sensor, 33: second sensor,

40: case, 50: antenna

2 to 4 illustrate a rotary device for a satellite antenna of the present invention for achieving the above object, the preferred embodiment of the present invention with reference to the drawings as follows.

In the satellite antenna of the present invention, the antenna 50 for receiving radio waves from the satellite is coupled to the upper surface of the case 40 so as to be movable in the vertical direction, and the rotating plate 30 is provided below the case 40. Combined.

The rotating plate 30 is coupled to an upper side of the separate fixing plate 20, and a rotating device for rotating the antenna 50 in a desired direction is installed between the fixing plate 20 and the rotating plate 30.

As shown in FIG. 3, a fixed gear 22 having a predetermined size is fixedly installed in the seating groove 21 formed in the center of the upper surface of the fixing plate 20, and the rotor 23 is disposed on the upper surface of the fixing gear 22. ) And the rotor 23 to rotate independently from the upper side of the fixed gear 22 by the bearing coupling, and the rotor 23 and the rotor 23 by bolting the rotating plate 30 to the upper side of the rotor 23 Together, the rotating plate 30 was able to rotate.

The drive motor 25 is installed downward in the vertical direction at the center upper end of the rotating plate 30, and the rotary shaft 28 of the drive motor 25 is extended downward, and the drive gear is disposed at the end of the rotary shaft 28. (24) is moistened.

As shown in FIGS. 3 and 4, the drive gear 24 is engaged with the outer circumferential surface of the fixed gear 22 so that the drive gear 24 rotates when the rotational force is transmitted from the drive motor 25. ) To move along the outer circumferential surface, and the rotating plate 30 is rotated by the movement of the drive gear 24.

In the present invention, the guide plate 31, the sensors 32 and 33, the moving protrusions 27, and the like are configured as a means for rotating the rotating plate 30 to the opposite direction once the rotary plate 30 is rotated to one direction to some extent.

The guide 31 allows the moving protrusion 27 to be guided and moved when the rotating plate 30 rotates. As shown in FIG. 4, two guide protrusions 34 are parallel to the bottom of the rotating plate 30. To protrude, but the guide protrusion 34 is spirally formed from the outer surface of the rotating plate 30 toward the inside to form a spiral so that the moving protrusion 27 is inserted between the guide protrusions 34 and the rotating plate 30. When the rotation is to move the moving protrusions 27 between the guide protrusions 34, and eventually to move to either end.

The first sensor 32 and the second sensor 33 are installed at both ends of the guide 31, respectively, the first sensor 32 and the second sensor 33 are moving projections moving along the guide 31. It detects when the (27) is close and transmits to the control device not shown.

The sensors 32 and 33 may use a photocoupler to detect moving protrusions, but may use any sensor capable of detecting moving protrusions in close proximity.

The moving protrusion 27 is coupled to enable a linear movement on the guide rod 26 formed in the upper surface of the fixed plate 20, the guide rod 26 is fixed plate 20 as shown in FIG. A predetermined length is formed toward the center from the outer shell of the moving projection 27 is inserted into the guide rod 26 so as to linearly move.

The moving protrusion 27 is positioned between the guide protrusions 34 of the guide 31 while the upper end thereof is inserted into the guide rod 26.

Therefore, when the rotating plate 30 rotates while the moving protrusion 27 is positioned between the guide protrusions 34, the moving protrusions 27 follow the guide 31 and move inward from the outer side of the guide rod 26. It will move outward or inward.

For example, when the rotating plate 30 rotates in a counterclockwise direction, the moving protrusion 27 moves inward from the outer edge of the guide 31 to move to the inner end of the guide 31, whereby As the second sensor 33 detects the moving protrusion 27 and transmits the detection signal to the control device, not shown, the control device no longer rotates the rotating plate 30 counterclockwise.

That is, after the moving protrusion 27 is detected by the second sensor 33, the driving motor 25 is rotated so that the rotating plate 30 rotates clockwise in the rotation operation for satellite tracking of the antenna 50. In this case, the moving protrusion 27 moves from the inside of the guide 31 to the outside.

In addition, when the moving protrusion 27 moved from the inner side to the outer side is detected by the first sensor 32, the controller starts the driving motor 25 so that the rotating plate 30 rotates counterclockwise again. To allow 50 to follow the satellite.

As described above, when the antenna 50 tracks the satellite, the rotation direction of the rotating plate 30 repeats the normal and reverse rotation, so that the wires connecting the antenna side and the main board are not twisted, thereby increasing the reliability of the product. It will be able to improve further.

As described above, the present invention provides a guide that rotates several times in a spiral shape on the bottom of the rotating plate, and forms a moving protrusion moving along the guide on the upper surface of the fixed plate, and detects a moving protrusion adjacent to both ends of the guide. By installing the system, it is possible to prevent the twisting of the wire connecting the antenna unit and the substrate by repeating the rotation plate forward and reverse whenever the moving protrusion is detected by the sensors on both sides when the rotating plate rotates to set the position of the satellite antenna. In addition, the effect of providing a rotating device for a satellite antenna can be expected to be expected to simplify the structure of the product and reduce the production cost.

Claims (1)

In the satellite antenna is mounted to the upper side of the fixed plate, the case is equipped with a satellite antenna on the upper end of the rotating plate, A fixed gear fixed to a center of an upper surface of the fixed plate; A rotor coupled to the upper part of the fixed gear so as to be capable of rotating independently, and the rotor plate coupled to the upper end thereof as a bolt; A guide having a predetermined length in parallel to protrude in a predetermined length on a bottom surface of the rotating plate, and being formed spirally toward the center from the outer surface of the rotating plate so that the moving protrusion moves between the guide protrusions when the rotating plate rotates; First and second sensors installed at both ends of the guide to sense that the moving protrusion is close to each other and to supply the detection signal to the control device; A guide rod which is formed on the upper surface of the fixed plate in a straight line from the outer shell to the center; A moving protrusion inserted into the guide rod so as to be movable and having an upper end inserted between the guide protrusions of the guide to move along the guide when the rotating plate rotates; A drive motor installed downward on one side of the fixed gear and driven by a control voltage supplied from a control device by rotating the shaft thereof in a drive gear to rotate the drive gear forward and backward to rotate the rotating plate; Rotating device for a satellite antenna, characterized in that consisting of.