KR20000060565A - Satellite Antenna with Means for Installment and Method of Installing the Same - Google Patents

Abstract

PURPOSE: A satellite antenna and mounting thereof with means is provided to set an angle of azimuth simply and exactly without a compass or an electric field intensity measuring device in addition to an elevation measurement without a divider. CONSTITUTION: A satellite antenna and mounting thereof with means includes a reflector(1), a feed horn(2) and a fixed pivot(5) for fixing the reflector(1). A sunbeam shadow formation means(6) installed in an antenna, connects the middle of a holding bond of the feed horn(2) with the middle in the upper part of the reflector(1). An azimuth chart(7a) is attached to the inside of the reflector(1). A cruciform member(11) is formed in a single body on a position of the sunbeam shadow formation means(6). The cruciform member(11) is installed parallel with the azimuth chart(7a) from a side view. The sunbeam shadow formation means(6) and the cruciform member(11) make a shadow(8) and a cruciform member shadow(12) respectively by a sunbeam.

Description

Satellite antenna with installation means and installation method thereof {Satellite Antenna with Means for Installation and Method of Installing the Same}

Field of invention

The present invention relates to a satellite antenna. More specifically, the present invention relates to a satellite antenna coupled to the installation means and to a method for installing the satellite antenna to facilitate installation.

Background of the Invention

Satellite antennas are used as part of a device for transmitting to or receiving from satellites. 1 is a perspective view schematically showing a case used for the most common satellite broadcasting reception of various aspects of the conventional satellite antenna. 1 includes a reflector 1 for reflecting a signal, a feed horn 2, a fixed shaft 5 for fixing the reflector, and the like.

In order to install a satellite antenna, first, the fixed shaft 5 should be installed and fixed at an appropriate position to be installed, and the antenna reflector 1 should be installed on the fixed shaft. However, the installation of the antenna reflector 1 on the fixed shaft 5 has only been possible by a technician with considerable installation technology. This is because when the satellite antenna is to be installed, the antenna reflector 1 must be installed so that the elevation angle and the azimuth angle are exactly matched. The elevation angle refers to the angle of inclination of the antenna reflector 1 in FIG. 1, and the azimuth angle refers to the angle of the antenna reflector formed in the rotational direction about the fixed shaft 5. In FIG. 1, the movement in the direction of arrow A adjusts the elevation angle, and the movement in the direction of arrow B adjusts the azimuth angle. The elevation angle and azimuth angle are determined by the position of the antenna and the position of the satellite. For example, if you want to receive the signal of Mugunghwa satellite in Seoul area, the elevation angle and azimuth angle have their own values.

When installing a satellite antenna, this elevation angle and azimuth angle should be installed. The elevation angle can be installed more easily than the azimuth angle. The fixed shaft 5 is installed vertically, and the inclination of the antenna reflector 1 is adjusted by using an angle meter such as a protractor to an elevation angle in the area, and then fixed. That is, in Fig. 1, the antenna reflector 1 is free to move in the direction of arrow A, but is fixed at the correct elevation position.

However, it is not easy to accurately match the azimuth angle of the antenna reflector 1. In particular, consumers who want to install a satellite antenna is difficult to find the exact azimuth. Therefore, if a satellite antenna is to be installed, almost all of them will be referred to a professional engineer, thereby increasing the installation cost.

So far, the expert installing the satellite antenna confirms the approximate azimuth by means of a compass, and then uses the field strength measuring device to carry out trial and error to set the correct azimuth. The general consumer who wants to install a satellite antenna is not equipped with a compass or field strength measurement device is usually unable to install the satellite antenna by themselves.

The present invention solves the above-mentioned problems when installing the satellite antenna completely, without using a compass or electric field strength measuring device, the satellite antenna is combined with the installation means that can be easily and accurately set the azimuth to install the satellite antenna And an installation method thereof and filed as a patent application No. 98-53530 (filed Dec. 8, 1998).

However, the patent application of the present invention can conveniently measure the azimuth angle, but when measuring the elevation angle, an angle meter such as a protractor is still required. In addition, sometimes the satellite antenna needs to check whether there is an obstacle within the angle to which the antenna is directed.

In order to solve the above problems, the present inventor developed a satellite antenna that can measure the elevation angle by installing a goniometer on the rear surface of the antenna reflector and filed as patent application No. 99-451 (January 11, 1999) There is a bar.

However, the satellite antennas of patent applications 98-53530 and 99-451 can be installed very accurately when the sun is located at or near the center of the antenna, whereas the sun is far from the center, i.e. the azimuth angle of the antenna with respect to the satellite. In the case of distant azimuth angles with the sun, significant errors are involved. In this case, there is considerable inaccuracy in setting the installation position of the satellite antenna.

Therefore, the present inventors have begun to develop a method for installing a satellite antenna with high accuracy even at a time when the azimuth angle to the satellite and the sun is far from the antenna, and to develop a satellite antenna having such a structure.

An object of the present invention is to provide a satellite antenna coupled to the installation means for installing a satellite antenna by simply and accurately setting the azimuth angle without using a compass or a field strength measuring device.

Another object of the present invention is to provide a satellite antenna that can be easily installed by a general consumer without a professional technician.

Still another object of the present invention is to provide a satellite antenna coupled to the installation means that can be installed by the general consumer to reduce the installation cost.

Still another object of the present invention is to provide a method for easily and accurately installing a satellite antenna by a general consumer without using a compass or a field strength measuring device.

Still another object of the present invention is to provide a satellite antenna, in which a goniometer for measuring elevation angles is installed on the rear side of the antenna reflector.

Still another object of the present invention is to provide a satellite antenna with an obstacle identification device consisting of a scale and a scale for identifying an obstacle within an angle directed by the satellite antenna.

Still another object of the present invention is to provide a satellite antenna having such a structure and a method capable of installing a satellite antenna with high accuracy even at a time when the azimuth angle of the antenna and the azimuth angle of the sun are far from each other.

The above and other objects of the present invention can all be achieved by the present invention described below.

1 is a perspective view schematically showing an installation form of a satellite antenna according to the present invention.

Figure 2 is a schematic side view of a satellite antenna coupled to the installation means according to the present invention.

Figure 3 is a schematic front view of a satellite antenna coupled to the installation means according to the present invention.

FIG. 4 is a diagrammatic plan view of one embodiment 7a of a diagram representing azimuth / time / shadow in accordance with the present invention (hereinafter referred to as an azimuth chart).

5 is a table plan view showing another embodiment 7b for setting the elevation angle and azimuth angle of the satellite antenna.

FIG. 6 is a diagrammatic plan view 7c showing a combination of the azimuth chart 7a of FIG. 4 and the azimuth chart 7b of FIG. 5.

FIG. 7 is a diagram schematically illustrating a goniometer installed at the rear side of the antenna reflector to measure the elevation angle of the antenna reflector.

FIG. 8 is a side view schematically showing an obstacle identifying device including a scale 13 and a scale 14 for identifying obstacles within an angle to which the satellite antenna is directed.

* Brief description of the major symbols in the drawings *

1: antenna reflector 2: feed horn

3: cable 4: receiver

5: fixed shaft 6: shadow forming means

7: Azimuth Chart 8: Solar Shadow

9: goniometer 10: obstacle checking device

11: cross member 12: cross member shadow

13: scale 14: scale

One aspect of the satellite antenna combined with the installation means of the present invention is to install a solar shadow forming means (6) connecting the center of the support of the horn horn (2) and the upper center of the antenna reflector (1), the shadow forming means In one position of (6), an integrally formed cruciform member 11 is formed, and the cruciform member 11 is installed to be substantially parallel to the azimuth diagram 7a when viewed from the side, and inside the antenna reflector 1 To determine the azimuth angle by attaching an azimuth chart to determine the elevation angle by installing a goniometer (9) on the rear of the antenna reflector, the azimuth line (71) determined according to the location of the antenna and the area where the antenna is to be installed ) Is shown in the horizontal direction, the time when installing the satellite antenna is shown by the diagonal line 72, the shadow of the vertical portion of the cross member 11 in the vertical direction (73), Based on the viewing angle the facing table (hereinafter referred to as a reference irradiation angle) indicated by the dotted line 74 in the transverse direction.

According to the present invention, the method for adjusting the azimuth angle checks the time at the time of installation of the antenna, and adjusts the shadow of the horizontal portion of the cross member 11 to the dotted line 73 representing the reference irradiation angle, but preferably as close to the corresponding time as possible. Fit to And the shadow of the vertical part of the cross member 11 is matched with the longitudinal line 73 which passes the intersection of the horizontal line 71 which shows the said azimuth angle, and the diagonal line 72 which shows the said time. And the angle of elevation is adjusted by a separate goniometer (9). In addition, the satellite antenna of the present invention is characterized in that the obstacle identification device consisting of a scale and a scale for identifying the obstacle within the angle directed by the satellite antenna is attached.

Another aspect of the satellite antenna coupled to the installation means of the present invention is to install a solar shadow forming means (6) connecting the center of the support of the horn horn (2) and the upper center of the antenna reflector (1), the shadow forming means In one position of (6), an integrally formed cruciform member 11 is formed, and the cruciform member 11 is installed to be substantially parallel to the azimuth chart 7b when viewed from the side, and the position of the cruciform member shadow is x-coordinated. Calculated by and y coordinates, the satellite antenna is installed by placing the shadow of the intersection of the horizontal and vertical portions of the cross member 11 at the calculated position (x, y).

Hereinafter, with reference to the accompanying drawings will be described in detail the contents of the present invention.

1 includes a reflector 1 for reflecting a signal, a feed horn 2, a fixed shaft 5 for fixing the reflector, and the like.

The satellite antenna coupled to the installation means of the present invention is installed with the shadow shadow forming means (6) connecting the center of the support of the whid horn (2) and the upper center of the antenna reflector (1) and the inside of the antenna reflector (1) An azimuth chart 7a is attached thereto, and an integrally formed cross member 11 is formed at one position of the shadow forming means 6, and the cross member 11 is viewed from the side as an azimuth chart 7a. And the shadow forming means 6 and the cross member 11 form the shadow 8 and the cross member shadow 12 respectively by sunlight.

The sun shadow forming means 6 is preferably flexible, such as strings, ropes and the like. The shadow forming means 6 is preferably made of a yarn made of chemical fibers having low resistance to propagation, and may be made of metal. The cross member 11 is formed integrally with the shadow forming means 6. FIG. 2 is a schematic side view of the satellite antenna showing the installation form of the cross member 11, and FIG. 3 is a schematic front view. As shown in FIG. 2, the reason why the cross member 11 is installed so as to be inclined with the shadow forming means 6 on the side and substantially parallel to the azimuth chart 7 is that the above-mentioned azimuth angle of the antenna is not only close to the time but also farther away. This is to maintain high accuracy even in the time zone.

The azimuth diagram shown in FIG. 4 is a diagram representing azimuth, vision and sunlight shadow. The azimuth chart is made differently according to the size and type of satellite antenna, the position of the satellite and the region where the antenna is used, and is attached inside the antenna reflector 1. In this diagram, the azimuth is indicated by the horizontal line 71, the time by the oblique line 72, and the longitudinal line 73 so as to coincide with the vertical shadow of the cross member 11.

And the reference irradiation angle with respect to the diagram of the sun is shown by the dotted line 74 of the horizontal direction.

The above azimuth chart is produced by the formula using the following principle.

The azimuth is fixed to a specific satellite for the antenna in which the cross member 11 is installed, and one horizontal dotted line 74 is set on the reflecting plate, and the elevation control is moved to raise the shadow of the horizontal portion of the cross member 11. Consistent with the dotted line 74, a reference irradiation angle with respect to the azimuth chart of the sun is formed.

The longitudinal line 73 is displayed in the same direction as the shadow of the vertical portion of the cross member 11.

After a certain time has elapsed (for example, after 2 to 3 minutes), the shadow of the vertical portion of the cross member 11 moves to the left or right, and the shadow of the horizontal portion moves to the up or down. Then, the reference irradiation angle is again adjusted, and the vertical direction line 73 is displayed in the same direction as the shadow of the vertical portion of the cross member 11.

Repeat this method several times. It is also repeated several times for different azimuth regions.

The horizontal line 71 is drawn in the order of the respective azimuth values, and when the portions corresponding to the same time of the vertical line 73 passing through the horizontal line 71 are connected up and down, the diagonal line 72 is formed. The corresponding time is displayed on the diagonal line 72.

FIG. 7 is a diagram schematically showing a goniometer 9 installed on the rear surface of the antenna reflector for measuring the elevation angle of the antenna reflector 1. The antenna reflector 1 is moved in the direction of arrow A to fix the elevation angle corresponding to the area and satellite to be received. Since the goniometer 9 is installed on the rear surface of the antenna reflector 1 around the fixed shaft 5, the satellite antenna can be easily installed without the provision of a separate protractor. After fixing the elevation angle, fix the azimuth angle.

The method for setting the azimuth angle of the satellite antenna in the present invention is as follows.

Check the time at the time of installation of the antenna, and move the elevation control device up and down to match the shadow of the horizontal portion of the cross member 11 to the dotted line 74 indicating the reference irradiation angle, but as close as possible to the corresponding time. The shadow of the vertical portion of the cross member 11 on the vertical direction line 71 passing through the intersection of the horizontal direction line 71 indicating the azimuth angle corresponding to the area where the antenna is installed and the vertical direction line 73 indicating the time. To match.

After adjusting the elevation angle by a separate goniometer 9, the antenna is finally fixed.

For example, if the current time is "T12 o'clock", the cross member 11 is aligned with the dotted line 74 indicating the reference irradiation angle, but close to the portion corresponding to "T12 o'clock".

And if the azimuth angle is D006, the shadow of the vertical portion of the cross member 11 on the longitudinal line 73 passing through the point where the horizontal line 71 corresponding to D006 and the diagonal line 72 corresponding to T12 meet in the azimuth angle diagram. Match with.

Then, the elevation angle is finally adjusted by the goniometer 9 and the antenna is completely fixed.

FIG. 8 schematically shows an obstacle identifying apparatus 10 composed of a scale and a scale for identifying an obstacle within an angle to which the satellite antenna is directed. Obstacle identification device 10 is composed of a scale (13) and a scale (14), by aiming through the scale and the scale can easily check whether the obstacle exists within the angle to which the satellite antenna is directed. Obstacle identification device consisting of a scale and a scale can be easily implemented by those skilled in the art.

Another aspect of the satellite antenna coupled to the installation means of the present invention is to install a solar shadow forming means (6) connecting the center of the support of the horn horn (2) and the upper center of the antenna reflector (1), the shadow forming means In one position of (6), an integrally formed cruciform member 11 is formed, and the cruciform member 11 is installed to be substantially parallel to the azimuth chart 7b when viewed from the side, and the position of the cruciform member shadow is x-coordinated. And a satellite antenna are installed by positioning the cross member shadow 12 at this calculated position (x, y).

In this method of the present invention, instead of adjusting the elevation angle and then adjusting the azimuth angle, the position of the cross member shadow 12 is calculated, and the cross member shadow 12 is positioned at the position of the azimuth chart 7b corresponding to the calculated position. ) To adjust the elevation angle and azimuth angle at the same time. In this method, the elevation angle and the azimuth angle of the satellite antenna will eventually receive the type of satellite, the coordinates on the earth (antenna location), the installation time (date and time), and the specified azimuth chart 7b with the cross-shaped member 11. It applies the theory that it is determined by relations. That is, the x coordinate and the y coordinate are displayed in the table 7b, and the position where the satellite antenna is to be installed is set. For example, in the azimuth chart 7b of FIG. 5, when the positions A15 and B10 where the x coordinate is A15 and the y coordinate is B10 are determined by the above factors, the cross member shadow 12 is placed on the azimuth chart 7b. Placed at positions A15 and B10, the elevation and azimuth angles of the antenna are determined.

The method of calculating the position of the cross member shadow 12 can be expressed as follows.

In the above formula, x means the x coordinate in the azimuth chart 7b and on the azimuth chart 7b, A ₁ , A ₂ , A ₃ . And y denotes the y-coordinate in the azimuth chart 7b, B ₁ , B ₂ , B ₃ . And the like.

In the above formula, the position (x, y) of the cross member shadow 12 is a function of k, f ₁ (g, h), f ₂ (d, t), and f ₃ (c, m), where k is intended to receive Where f ₁ (g, h) is a function of the coordinates of the place where the antenna is to be installed, and f ₂ (d, t) is a function of the date and time of installation of the satellite antenna. F ₃ (c, m) is a function determined by the azimuth chart 7b and the cross member 11.

For example, k determined by the position of the satellite can select a name already entered in the case of an existing satellite, and enter the position of the satellite as 116 degrees long in the case of a newly launched satellite. F ₁ (g, h) according to the installation place can basically enter the longitude and latitude of the installation place or use the longitude and latitude input by entering an address, and f ₂ (d, t) according to the installation time. Is for checking the change of the sun according to the date and time. The date and time can be entered, and f ₃ (c, m) determined by the azimuth chart 7b and the cross member shadow 12 is shown in the chart 7b. X and y coordinates are calculated in the azimuth chart 7b by inputting the model number and the type according to the position of the cross member 11 according to the type.

A shadow position (x, y) calculator (not shown) includes an input device for inputting the data, an arithmetic device for processing the input data, and an output device for outputting the calculated shadow position (x, y). It consists of.

The input device may input necessary data by using a keyboard formed in the receiver 4, and may also use a device such as a remote controller, which can be easily implemented by a person skilled in the art. have.

The computing device inputs data through the input device by the formula (x, y) = F (k, f ₁ (g, h), f ₂ (d, t), f ₃ (c, m)). It is a device to be operated by a microprocessor.

The position (x, y) where the operation is completed in the computing device is output through the output device. In addition, the shadow calculates the direction and distance along which the shadow moves, for example, about 3 minutes, and displays it on the left side, for example, 3 millimeters, so that the difference between the data input time and the antenna installation time can be corrected. .

The azimuth chart may combine the azimuth chart 7a of FIG. 4 with the azimuth chart 7b of FIG. 5. An example of a combined azimuth chart is shown in FIG. 6. In FIG. 6, the azimuth chart 7a of FIG. 4 is recognized from the coordinates displayed at the upper and left portions, and the azimuth chart 7b of FIG. 5 is recognized from the coordinates displayed at the lower and right portions.

In the present specification, the offset satellite antenna has been described, but is not necessarily limited thereto. The antenna may be applied to other types of antennas, namely, parabolic antenna, planar antenna, or back feed horn antenna.

The satellite antenna according to the present invention does not use a compass or a field strength measuring device, and simply and accurately sets the azimuth angle, measures an elevation angle without using a protractor, and easily checks an obstacle within an angle to which the satellite antenna is directed. As the satellite antenna can be easily installed by the general consumer, the satellite antenna can be installed without using a professional according to the satellite antenna installation method of the present invention, thereby reducing the installation cost.

Simple modifications or changes of the present invention can be easily carried out by those skilled in the art, and all such modifications or changes can be seen to be included in the scope of the present invention.

Claims (8)

Solar shadow forming means (6) connecting the center of the support of the horn horn (2) of the satellite antenna and the upper center of the antenna reflector (1) is provided, and in one position of the shadow forming means (6) is a cross A member 11 is formed, and the cross member 11 is installed to be substantially parallel to the azimuth chart 7 when viewed from the side, and an azimuth chart 7 is attached to the inside of the antenna reflector to determine the azimuth angle, A satellite antenna, characterized in that the elevation angle is determined by installing a goniometer (9) on the rear of the antenna reflector. The azimuth chart according to claim 1, wherein the azimuth chart includes a horizontal line 71 representing azimuth angle, an oblique line 72 representing time, a vertical line 73 coinciding with the sunlight shadow 8, and a reference irradiation angle line 74. Satellite antenna, characterized in that configured. The satellite antenna according to claim 1, wherein an obstacle identification device (10) consisting of a scale (13) and a scale (14) for identifying an obstacle within an angle directed by the satellite antenna is attached to an upper portion of an antenna reflector. . The shadow of the horizontal portion of the cross member 11 is aligned close to the corresponding time of the dotted line 74 representing the reference irradiation angle, and the horizontal direction line 71 in which the azimuth angle corresponding to the area where the antenna is installed is displayed and the diagonal line representing the corresponding time. The method of installing a satellite antenna, characterized in that the shadow of the vertical portion of the cross-shaped member (11) to match the vertical direction line (73) passing through the intersection point, and adjust the elevation angle by the goniometer (9) installed on the rear of the antenna. The azimuth chart according to claim 4, wherein the azimuth chart includes a horizontal line 71 representing azimuth angle, an oblique line 72 representing time, a vertical line 73 coinciding with the sunlight shadow 8, and a reference irradiation angle line 74. Satellite antenna, characterized in that configured. Solar shadow forming means (6) is provided to connect the center of the support of the horn horn 2 and the upper center of the antenna radiation plate (1), and at one position of the shadow forming means (6) a cross-shaped member formed integrally ( 11) is formed, and the cross member 11 is installed to be substantially parallel to the diagram 7b when viewed from the side, and the position of the cross member shadow is calculated in x and y coordinates, and the calculated position (x, y) positioning the cross-shaped member shadow (12). 7. The method of claim 6, wherein the diagram comprises a horizontal line and a vertical line. The method of claim 6, wherein the position (x, y) of the cross member shadow 12 is determined by the following equation: In the above formula, x means x-coordinate in chart 7b and on azimuth chart 7b, A ₁ , A ₂ , A ₃ . And y denotes the y-coordinate in the chart 7b, B ₁ , B ₂ , B ₃ . And the position (x, y) of the cross member shadow 12 is a function of k, f ₁ (g, h), f ₂ (d, t), and f ₃ (c, m). Is a variable that is determined according to the position of the satellite to be received, f ₁ (g, h) is a function of the coordinates of the place where the antenna is to be installed, and f ₂ (d, t) is the date of installation of the satellite antenna. It is a function of time, and f ₃ (c, m) is a function determined by the chart 7b and the cross member 11.