KR101046208B1 - Satellite antenna apparatus - Google Patents

Abstract

PURPOSE: A satellite antenna apparatus is provided to reduce an antenna size by integrating controlling units for an azimuth, an elevation angle, and a polarization angle with an antenna unit. CONSTITUTION: An antenna unit receives signals transmitted from a satellite. A connecting unit comprises a first connecting part(131), which engage on the back of the antenna unit, and a second connecting part, which is formed by extension to both side of the first connecting part. An antenna polarization angle controlling unit(120) is settled in the connecting unit and is rotatable. A pair of an elevation angle controlling unit is respectively combined with a pair of the second connecting unit. The azimuth controlling unit(150) connects a pair of the elevation angle controlling unit between another pair of the elevation angle controlling unit.

Description

Satellite Antenna Unit {SATELLITE ANTENNA APPARATUS}

Embodiments of the present invention relate to a satellite antenna device, and more particularly, to a technology capable of adjusting the azimuth, elevation, and polarization angle of a satellite antenna.

Recently, with the advent of digital satellite broadcasting, satellite broadcasting has become popular, and the demand for satellite antennas for transmitting and receiving satellite signals is increasing. The satellite antenna is classified into a parabola antenna, a cassgrain antenna, a Gregorian antenna, and the like according to a method of focusing a signal reflected by the reflector and a shape of the reflector.

The parabolic antenna has a radiator disposed at a focal point of a parabolic reflector. Here, the radio wave from the copy machine is reflected by the reflecting plate and transmitted to the outside, or the radio wave from the outside is reflected by the reflecting plate and focused on the copy machine, thereby making satellite communication.

The casein antenna and the Gregorian antenna have a sub-reflector disposed at the focal point of the parabolic main reflector. Here, the radio wave from the copy machine passes through the sub reflector and is reflected by the main reflector to be transmitted to the outside, or the radio waves from the outside are reflected from the main reflector to focus the copier through the sub reflector, thereby performing satellite communication.

Since the parabolic antenna is small in size but has a relatively short communication distance, the casee grain antenna and the Gregorian antenna are mainly used for long distance communication.

The satellite antenna needs to track the position of the target satellite to maintain the orientation of the antenna in the target satellite direction. For example, signals transmitted by satellites floating over the earth and rotating with the earth are highly directional, requiring the antenna to be precisely oriented towards the satellite.

Since the degree of directivity of the satellite antenna is set within about 2 to 3 °, when the satellite antenna is out of this range, communication is often completely cut off unlike general airwave broadcasting. In particular, this orientation has deepened along with digital satellite broadcasting. Therefore, it is required to install the satellite antenna precisely in the target satellite direction for high directivity of the satellite antenna.

In this case, the azimuth and elevation of the satellite antenna should be adjusted. 1 is a view showing the concept of azimuth and elevation. Referring to FIG. 1, the azimuth angle indicates in which direction the target satellite is located on the compass, and the elevation angle indicates the vertical angle at which the satellite antenna faces the target satellite.

In addition, when a satellite transmits a signal with linear polarization, since the linear polarization signal transmitted from the satellite is diffracted due to Faraday Rotation phenomenon passing through the ionosphere of the atmosphere, the satellite antenna and the receiver of the transmitting side are received. Skew occurs between the side satellite antennas. In this case, the strength of the signal is attenuated due to the polarization loss.

2 is a diagram illustrating a concept of a polarization angle due to skew of linear polarization. Referring to FIG. 2, when a satellite transmits a vertical polarization, the first antenna has a polarization angle of 0 ° with a vertical polarization transmitted from the satellite, but no polarization loss occurs, but the second antenna transmits the satellite. It can be seen that polarization loss occurs with a polarization angle of 15 ° to the vertical polarization.

The polarization angle is caused by the roundness of the earth. For example, when a vehicle equipped with a satellite antenna moves a long distance, the polarization angle is changed even when the polarization angle is adjusted at the starting point. In this case, it is necessary to adjust the polarization angle of the satellite antenna from time to time.

In the related art, a low noise block (LNB), which is a low noise amplification changer that amplifies a high frequency signal received from a reflector of a satellite antenna and converts it into an intermediate frequency, is fixed to the satellite antenna. There was an inconvenience to move.

An embodiment of the present invention is to provide a satellite antenna device capable of adjusting the elevation angle and azimuth angle of the satellite antenna and at the same time the polarization angle due to the skew of the linear polarization.

Other technical problems by the embodiments of the present invention can be understood by the following description, which can be realized by the means and combinations thereof shown in the claims.

Satellite antenna apparatus according to an embodiment of the present invention, the antenna unit for receiving a signal transmitted from the satellite; A coupling part coupled to the rear of the antenna part; And a low noise block (LNB) rotatably seated in the coupling unit and receiving and processing the satellite signal, and including an antenna polarization angle adjusting unit configured to adjust the polarization angle of the satellite signal by rotating the LNB. do.

The coupling part may include: a first coupling part coupled to the rear of the antenna part and on which the antenna polarization angle adjusting part is seated; And a pair of second coupling parts extending from both sides of the first coupling part.

The satellite antenna device may be coupled to the pair of second coupling units, respectively, and a pair of elevation control units for adjusting the elevation angle of the antenna unit; An azimuth angle adjusting unit which is formed between the pair of elevation angle adjusting units and connects the pair of elevation angle adjusting units, and adjusts an azimuth angle of the antenna unit; And a support plate formed to be coupled to the azimuth control unit at a lower portion of the azimuth control unit.

The satellite antenna device may be coupled to the pair of second coupling units, respectively, and a pair of elevation control units for adjusting the elevation angle of the antenna unit; An azimuth angle adjusting unit which is formed between the pair of elevation angle adjusting units and connects the pair of elevation angle adjusting units, and adjusts an azimuth angle of the antenna unit; A support plate fixedly attached to a predetermined plane; And an auxiliary coupling member for vertically coupling the azimuth adjustment unit and the support plate.

The antenna polarization angle control unit, the LNB lower cover is rotatably seated on the back of the first coupling portion; A polarization angle stopper seated on a rear surface of the LNB lower cover and coupled to the first coupling part to stop rotation of the LNB lower cover by a predetermined angle unit; A Low Noise Block (LNB) received in the LNB lower cover and receiving a signal from the antenna unit to process a signal; And an LNB top cover coupled with the LNB bottom cover.

According to the embodiments of the present invention, not only can easily adjust the azimuth and elevation angle of the antenna, but also the polarization angle can be adjusted when the polarization angle of the satellite signal occurs according to the long-distance movement, reducing the polarization loss and improve the performance of the antenna You can. In addition, by forming the means for adjusting the azimuth, elevation, and polarization integrally with the antenna unit, the size of the satellite antenna device can be reduced. In this case, the portability of the satellite antenna device can be improved.

1 is a view showing the concept of azimuth and elevation.
2 shows the concept of a polarization angle due to skew of linear polarization.
3 is a front perspective view showing a satellite antenna device according to an embodiment of the present invention.
Figure 4 is a rear perspective view showing a satellite antenna device according to an embodiment of the present invention.
5 is a partial perspective view of a satellite antenna device according to an embodiment of the present invention.
6 is a partially exploded perspective view of a satellite antenna device according to an embodiment of the present invention.
7 is a view showing an LNB lower cover and a polarization angle control unit according to an embodiment of the present invention.
8 is a view showing a rotating state of the antenna polarization angle control unit according to an embodiment of the present invention.
9 is a perspective view of a satellite antenna device according to another embodiment of the present invention.

Hereinafter, specific embodiments of the satellite antenna device of the present invention will be described with reference to FIGS. 3 to 9. However, this is only an exemplary embodiment and the present invention is not limited thereto.

In describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

The technical spirit of the present invention is determined by the claims, and the following embodiments are merely means for effectively explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains.

3 is a front perspective view showing a satellite antenna device according to an embodiment of the present invention, Figure 4 is a rear perspective view showing a satellite antenna device according to an embodiment of the present invention.

3 and 4, the satellite antenna device includes an antenna unit 110, an antenna polarization angle adjusting unit 120, a coupling unit 130, a pair of elevation angle adjusting units 140, and an azimuth angle adjusting unit 150. , And a support plate 160.

The antenna unit 110 includes a main reflector 111, a sub reflector 113, and a horn radiator 115.

The main reflector 111 has a surface made of a conductive material and has a cross-section of a secondary curve such as a parabola or a hyperbola. The main reflector 111 reflects the radio wave incident from the outside to the focal point or reflects the radio wave radiated from the focal point to the outside in parallel.

The sub reflector 113 is formed at the focal position of the main reflector 111. The sub reflector 113 concentrates external radio waves reflected by the main reflector 111 into the horn copier 115 or directs radio waves transmitted from the horn copier 115 to the main reflector 111. It serves to reflect. The sub-reflection plate 113 has a cross-section of a secondary curve such as a parabola or a hyperbola, and the sub-reflection plate 113 may be formed to have a curvature opposite to that of the main reflection plate 111.

The horn radiator 115 is formed under the sub reflector 113 to receive radio waves reflected by the sub reflector 113 or to radiate radio waves to the sub reflector 113. . The horn copier 115 has a waveguide structure in which one end is opened to form an opening, and the open end is formed in the form of a horn in which its cross-sectional area becomes larger as it approaches the sub reflector 113. The horn copier 115 is connected to a low noise block (LBN) installed on the rear surface of the main reflector 111.

The antenna polarization angle adjusting unit 120 accommodates the Low Noise Block (LBN) and is coupled to the rear surface of the main reflector 111 through the coupling unit 130. In this case, the antenna polarization angle adjusting unit 120 is rotatably coupled to the rear surface of the main reflector 111. Therefore, when a polarization angle is generated between the antenna unit 110 and the linear polarization transmitted by the satellite, the polarization angle adjustment unit 120 may be rotated to readjust the polarization angle. In this case, the antenna polarization angle adjusting unit 120 may rotate the LNB to readjust the polarization angle of the antenna, or may adjust the polarization angle of the antenna by rotating the horn copier 115 together with the LNB. Detailed description thereof will be described later.

The coupling part 130 is installed on the rear surface of the main reflector 111, and is coupled to the pair of elevation angle adjusting parts 140. The coupling part 130 includes a first coupling part 131 and a pair of second coupling parts 134.

The first coupling part 131 is installed on the rear surface of the main reflector 111, and the antenna polarization angle adjusting part 120 is mounted on the rear surface of the first coupling part 131. In this case, the antenna polarization angle adjusting unit 120 is rotatably coupled to the rear surface of the first coupling unit 131. When the antenna polarization angle adjusting unit 120 rotates, a first goniometer 133 may be displayed on the rear surface of the first coupling unit 131 to check the rotation angle of the antenna polarization angle adjusting unit 120. Can be.

The pair of second coupling parts 134 extend from both ends of the first coupling part 131 vertically, respectively. Ends of the pair of second coupling parts 134 are rotatably coupled to the pair of elevation control parts 140. The pair of second coupling parts 134 are rotatably coupled to the pair of elevation angle adjusting parts 140 to adjust the elevation of the antenna unit 110.

The pair of elevation controllers 140 includes a pair of elevation connector 141, a pair of elevation control plates 144, and a pair of elevation fasteners 147.

The pair of elevation connectors 141 are respectively coupled to the pair of second coupling parts 134. For example, the pair of elevation connectors 141 may be inserted into the ends of the pair of second coupling parts 134 to be coupled to the pair of second coupling parts 134, respectively. A pair of coupling portions 142 and the pair of insertion coupling portions 142 that extend perpendicularly to the pair of insertion coupling portions 142, respectively, and are coupled to the pair of elevation control plates 144. And a vertical connection 143.

At this time, the pair of vertical connecting portion 143 is coupled to the inner surface of the pair of elevation control plates 144 through the fastening member 143-1, respectively. Therefore, the pair of second coupling parts 134 are positioned between the pair of elevation control plates 144.

The pair of elevation control plates 144 are formed to be spaced apart from each other by a predetermined distance. The pair of elevation control plates 144 are each formed perpendicular to the bottom surface, and are formed in a semicircle shape. However, the shape of the pair of elevation control plates 144 is not limited thereto, and may be formed in various shapes other than that.

The pair of elevation control plates 144 are formed with arc-shaped elevation control slits 145, respectively. The pair of elevational fasteners 147 are coupled to the pair of second coupling portions 134 in a state of being inserted into the elevation adjustment slit 145.

The pair of elevational fasteners 147 may move along the elevation adjustment slit 145, in which case the pair of second coupling portions 134 may be configured as the axis of the fastening member 143-1. The elevation angle of the antenna unit 110 can be adjusted by rotating along the elevation angle adjustment slit 145.

For example, when the pair of elevation fasteners 147 are in a tightened state, the pair of second coupling parts 134 are fixed at a predetermined position, but the pair of elevation fasteners 147 is fixed. Loosening the tightening state of the pair of elevation fasteners 147 can be moved along the elevation control slit 145. In this case, after moving the pair of elevation fasteners 147 by a desired angle, and then tightening the pair of elevation fasteners 147 again, the pair of second coupling parts 134 It will be fixed at that position. At this time, the elevation angle of the antenna unit 110 is adjusted by the shifted angle of the pair of elevation fasteners 147.

A second goniometer 146 may be displayed on the pair of elevation control plates 144 to check the rotation angle of the antenna unit 110. For example, when the second goniometer 146 is displayed below the elevation control slit 145, the user can easily check the rotation angle of the antenna unit 110 to adjust the elevation angle of the antenna unit 110. Will be.

The azimuth adjustment unit 150 connects the lower ends of the pair of elevation control plates 144 to form a horizontal rotation plate 151 and the rotation plate 151 rotatably coupling the support plate 160 with the azimuth jaw A pregnant woman 154 is included.

The rotating plate 151 is rotatably coupled to the support plate 160 by the azimuth tightening unit 154, and the azimuth angle of the antenna unit 110 can be adjusted by rotating the rotating plate 151. . That is, when the rotating plate 151 is rotated together, the antenna unit 110 rotates together, so that the azimuth angle of the antenna unit 110 can be adjusted according to the rotation angle of the rotating plate 151.

For example, when the azimuth tightening unit 154 is in a tightened state, the rotating plate 151 is fixedly coupled to the support plate 160, but when the azimuth tightening unit 154 is loosened The rotating plate 151 may be rotated on the supporting plate 160. In this case, after the rotating plate 151 is rotated by the user's desired angle, and then tightening the azimuth tightening unit 154 again, the rotating plate 151 is fixed at the corresponding position. In this case, the azimuth angle of the antenna unit 110 is adjusted as much as the rotated angle of the rotating plate 151.

The support plate 160 is coupled to the rotating plate 151 under the rotating plate 151. The support plate 160 supports the pair of elevation control parts 140 and the azimuth adjustment part 150. Here, the support plate 160 is shown in a circular plate shape, but is not limited thereto. In addition, the support plate 160 may have various shapes.

A third goniometer 161 may be displayed on the support plate 160 to check the rotation angle of the rotating plate 151. In this case, not only the azimuth angle but also the names of satellites (eg, ASTRA1, ASTRA2, HOTBIRD, etc.) at the azimuth may be displayed on the third goniometer 161.

The support plate 160 is formed by combining a plurality of adsorption parts 164. The adsorption part 164 allows the support plate 160 to be fixedly attached to the bottom surface. The adsorption part 164 includes a handle part 165 coupled to the support plate 160 at an upper portion of the support plate 160, and an adsorption plate 166 coupled to the handle part 165 at a lower side of the support plate 160. Include. Here, when the user grasps the handle part 165 and descends downward, the lower end of the handle part 165 depresses the support plate 160 so that the suction plate 166 is adsorbed on the bottom surface.

The satellite antenna device according to the embodiment of the present invention can not only easily adjust the azimuth and elevation angles of the antenna, but also can control the polarization angle when the polarization angle of the satellite signal occurs due to the long-distance movement, thereby reducing the polarization loss and performance of the antenna. Can improve. In addition, by forming the means for adjusting the azimuth, elevation, and polarization integrally with the antenna unit, the size of the satellite antenna device can be reduced. In this case, the portability of the satellite antenna device can be improved.

Meanwhile, the descriptions of the first, second, and third in the first and third goniometers 133 to 161 are merely to distinguish each goniometer, and thus, the first goniometer ( 133, the second goniometer 146, and the third goniometer 161 should not be limited to the descriptions of the 'first', 'second', and 'third'. For example, without departing from the scope of the present invention, the first goniometer may be called a second goniometer, and likewise, the second goniometer may be called a first goniometer.

5 is a partial perspective view of a satellite antenna device according to an embodiment of the present invention, Figure 6 is a partially exploded perspective view of a satellite antenna device according to an embodiment of the present invention. Here, the coupling relationship between the antenna unit, coupling unit, and antenna polarization angle control unit is shown.

5 and 6, the coupling part 130 is installed on the rear surface of the main reflector 111, and the antenna polarization angle adjusting part 120 is mounted on the rear surface of the coupling part 130 so as to be rotatable. do. The rear surface of the coupling portion 130 is formed with a seating groove 132 on which the antenna polarization angle adjustment unit 120 is seated. In addition, the back of the coupling unit 130, when the antenna polarization angle adjustment unit 120 is rotated, a goniometer 133 that can determine the rotation angle of the antenna polarization angle adjustment unit 120 is displayed.

The antenna polarization angle adjusting unit 120 includes an LNB lower cover 121, a polarization stopper 124, a low noise block (LNB) 128, and an LNB upper cover 129.

The LNB lower cover 121 is seated in the seating groove 132 formed on the rear surface of the coupling part 130. The seating groove 132 has a shape corresponding to the LNB lower cover 121. In this case, the LNB lower cover 121 is rotatable left and right in the seating groove 132.

An upper part of the LNB lower cover 121 is provided with an indicator 122 indicating the rotation angle when the LNB lower cover 121 rotates in the seating groove 132. For example, when the LNB lower cover 121 is rotated by a predetermined angle in the seating groove 132, the indicator 122 instructs the goniometer 133 formed on the rear surface of the coupling part 130. By reading the angle indicated by the indicator 122, it is possible to check the rotation angle of the LNB lower cover 121 is rotated.

A locking groove 123 is formed at a rear surface of the LNB lower cover 121 at a predetermined angle interval (for example, 5 °). Specifically, the locking groove 123 is formed in a circular shape on the back of the LNB lower cover 121 and is periodically formed at predetermined angle intervals.

The polarization stopper 124 is coupled to the coupling part 130 in a state of being seated on the rear surface of the LNB lower cover 121. Specifically, a plurality of first fastening holes 135 are formed around the mounting groove 132 of the coupling part 130, and the polarization stopper 124 corresponds to the first fastening holes 135. Second fastening holes 125 are formed. In the state where the polarization stopper 124 is seated on the rear surface of the LNB lower cover 121, the fastening means 126 such as a bolt passes through the second fastening hole 125 and the first fastening hole 135. By coupling the polarization stopper 124 and the coupling portion 130.

One or more locking protrusions (not shown) are formed on the front surface of the polarization stopper 124. The locking protrusions (not shown) are formed when the LNB lower cover 121 rotates in the seating groove 132. It is caught in the locking groove 123 formed in the LNB lower cover 121. In this case, the LNB lower cover 121 is rotated by the spaced angle unit of the locking groove 123. A detailed description thereof will be described later.

The low noise block (LNB) 128 is coupled to the rear surface of the main reflector 111 in a state of being accommodated in the LNB lower cover 121. More specifically, the LNB 128 is coupled to the lower end of the horn copier 115 at the rear surface of the main reflector 111.

The LNB 128 converts the signal received by the horn copier 115 into an intermediate frequency. That is, since the signal received from the satellite is a high frequency signal, a lot of loss occurs when the received signal is transmitted through the cable. Thus, by converting a high frequency signal to an intermediate frequency through the LNB 128, the loss in the cable is reduced.

Since the LNB 128 is accommodated in the LNB lower cover 121, the LNB 128 rotates together when the LNB lower cover 121 rotates. Therefore, when a polarization angle is generated between the LNB 128 and the signal received from the satellite, the polarization angle may be readjusted by rotating the LNB lower cover 121.

Here, although the polarization angle of the antenna is adjusted by rotating the LNB 128 through the antenna polarization angle adjusting unit 120, the horn copier 115 is also rotated together with the LNB 128 to adjust the polarization angle of the antenna. It can also be implemented. That is, after the antenna polarization angle adjusting unit 120 and the horn copier 115 are coupled, the antenna polarization angle adjusting unit 120 is rotated so that the horn copier 115 together with the LNB 128 is also rotated. It may be implemented to adjust the polarization angle of the antenna by rotating.

The LNB top cover 129 is coupled to the LNB bottom cover 121 at the top of the LNB bottom cover 121. In this case, the LNB 128 is safely protected from an external environment within the LNB lower cover 121 and the LNB upper cover 129.

As described above, since the antenna polarization angle adjusting unit 120 is rotatably coupled in the seating groove 132 of the coupling unit 130, the antenna polarization angle is polarized between the antenna unit 110 and the signal received from the satellite. When the angle occurs (for example, when moving a long distance while the satellite antenna device is mounted on the vehicle), by rotating the antenna polarization angle adjustment unit 120 by a predetermined angle, it is possible to readjust the polarization angle. .

7 is a view showing the LNB lower cover and polarization angle control unit according to an embodiment of the present invention.

Referring to FIG. 7A, a circular opening 121-1 is formed in the LNB lower cover 121, and a predetermined angular interval is formed along the edge of the opening 121-1 from the rear surface of the LNB lower cover 121. The locking grooves 123 are formed at (eg, 5 °). At this time, the locking groove 123 is formed in a circular shape along the edge of the opening (121-1).

Referring to FIG. 7B, one or more locking protrusions 127 protrude from the front surface of the polarization stopper 124. For example, three locking projections 127 may be formed at a front surface of the polarization stopper 124 with a distance of 120 ° from each other. In addition, a plurality of second fastening holes 125 are formed in the polarization stopper 124.

Referring to FIG. 7C, the front surface of the polarization stopper 124 is seated on the rear surface of the LNB lower cover 121, wherein the locking protrusions 127 are inserted into the locking groove 123 and locked. Here, when the LNB lower cover 121 is rotated at a predetermined angle, the locking projections 127 are rotated while being caught by the locking grooves 123, the corresponding position at the position where the rotation of the LNB lower cover 121 stops. The rotation is stopped by the locking groove 123 formed in the position. The fastening means 126 penetrates through the second fastening hole 125 to be coupled to the first fastening hole 135 of the coupling part 130 through the opening 121-1.

8 is a view showing a rotating state of the antenna polarization angle control unit according to an embodiment of the present invention.

Referring to FIG. 8, when the antenna polarization angle adjusting unit 120 is rotated in a predetermined direction, the polarization angle stopper 124 seated on the rear surface of the LNB lower cover 121 may be coupled to the coupling unit 130. Therefore, only the LNB lower cover 121 is rotated in the mounting groove 132 of the coupling portion 130.

Here, when the LNB lower cover 121 is rotated, the locking projections 127 formed on the front surface of the polarization stopper 124 are formed in the rear surface of the LNB lower cover 121 at a predetermined angular interval. ) Is rotated while being locked to each. Therefore, the antenna polarization angle adjusting unit 120 can rotate by the spaced angle unit of the locking groove 123, it is possible to adjust the polarization angle by the spaced angle unit of the locking groove 123.

Meanwhile, since the first goniometer 133 is displayed on the rear surface of the coupling unit 130, and the indicator unit 122 is formed on the upper end of the LNB lower cover 121, the antenna polarization angle adjusting unit 120 is provided. ), You can check the rotation angle.

9 is a perspective view of a satellite antenna device according to another embodiment of the present invention. 3 and 4 illustrate a case in which the satellite antenna device is installed on a flat floor, another embodiment shown in FIG. 9 illustrates a case in which the satellite antenna device is installed on a vertical wall. Here, description will be given focusing on a part different from the satellite antenna apparatus according to the embodiments of FIGS. 3 and 4.

9, the rotating plate 151 is coupled to the support plate 160 through the auxiliary coupling member 180. The auxiliary coupling member 180 is formed to extend vertically downward from the horizontal plate 181 and the horizontal plate 181 to be coupled to the rotating plate 151 below the rotating plate 151 and the support plate 160 It includes a vertical plate 184 to be coupled, and a pair of supports 187 formed between the horizontal plate 181 and the vertical plate 184.

The horizontal plate 181 is coupled to the rotating plate 151 by the azimuth tightening unit 154, and the vertical plate 184 is coupled to the support plate 160 through a separate fastening means 185. Here, the support plate 160 is fixedly attached to the vertical wall surface through the plurality of adsorption parts 164.

As such, the satellite antenna device may be fixedly attached to a vertical wall by using the auxiliary coupling member 180.

Although the present invention has been described in detail with reference to exemplary embodiments above, those skilled in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. Will understand.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

110 antenna portion 111 main reflector
113: secondary reflector 115: horn copier
120: antenna polarization angle adjusting unit 121: LNB lower cover
122: indicator 123: locking groove
124: polarization angle stopper 125: second fastening hole
126: fastening means 127: locking projection
128: LNB 129: LNB top cover
130: coupling portion 131: first coupling portion
132: mounting groove 133: first goniometer
134: a pair of second coupling portion 135: the first fastening hole
140: a pair of elevation control unit 141: a pair of elevation control
142: a pair of insertion connection 143: a pair of vertical connection
143-1: fastening member 144: a pair of elevation control plate
145: elevation angle slit 146: second goniometer
147: a pair of elevation tightening unit 150: azimuth adjustment unit
151: rotating plate 154: azimuth tightening
160: support plate 161: third goniometer
164: adsorption portion 165: handle portion
166: adsorption plate

Claims (17)

An antenna unit for receiving a signal transmitted from a satellite;
A coupling part including a first coupling part coupled to the rear of the antenna part and a pair of second coupling parts extending from both sides of the first coupling part, respectively;
An antenna polarization angle control unit rotatably seated in the coupling unit, and including a low noise block (LNB) for receiving and processing the satellite signal and adjusting the polarization angle of the satellite signal by rotating the LNB;
A pair of elevation angle adjusting portions respectively coupled to the pair of second coupling portions to adjust an elevation angle of the antenna unit;
An azimuth angle adjusting unit which is formed between the pair of elevation angle adjusting units and connects the pair of elevation angle adjusting units, and adjusts an azimuth angle of the antenna unit; And
And a support plate coupled to the azimuth adjustment unit under the azimuth adjustment unit.

delete delete The method of claim 1,
The pair of elevation angle adjusters,
A pair of elevation angle coupling portions respectively coupled to the pair of second coupling portions;
A pair of elevation control plates each having an inner side surface coupled with the pair of elevation angle connecting portions, and an elevation adjustment slit for adjusting the elevation angle of the antenna unit, respectively; And
And a pair of elevational fasteners inserted into the elevation adjustment slit and engaged with the pair of second coupling portions and moving along the elevation adjustment slit.
The method of claim 4, wherein
The pair of elevation angle adjusters,
And a goniometer respectively displayed on an outer surface of the pair of elevation control plates.
The method of claim 4, wherein
The azimuth adjustment unit,
A rotating plate formed to connect a lower end of the pair of elevation control plates between the pair of elevation control plates; And
And an azimuth tightening portion to rotatably couple the rotating plate to the support plate.
The method of claim 6,
The satellite antenna device,
And a goniometer displayed on the support plate at the rear of the rotating plate.
The method of claim 1,
The satellite antenna device,
It is formed in combination with the support plate, the satellite antenna device further comprises one or more adsorption unit for fixedly attaching the support plate to a predetermined plane.
An antenna unit for receiving a signal transmitted from a satellite;
A coupling part including a first coupling part coupled to the rear of the antenna part and a pair of second coupling parts extending from both sides of the first coupling part, respectively;
An antenna polarization angle control unit rotatably seated in the coupling unit and including a low noise block (LNB) for receiving and processing the satellite signal and adjusting the polarization angle of the satellite signal by rotating the LNB;
A pair of elevation angle adjusting portions respectively coupled to the pair of second coupling portions to adjust an elevation angle of the antenna unit;
An azimuth angle adjusting unit which is formed between the pair of elevation angle adjusting units and connects the pair of elevation angle adjusting units, and adjusts an azimuth angle of the antenna unit;
A support plate fixedly attached to a predetermined plane; And
And an auxiliary coupling member for vertically coupling the azimuth adjustment portion and the support plate.
10. The method of claim 9,
The pair of elevation angle adjusters,
A pair of elevation angle coupling portions respectively coupled to the pair of second coupling portions;
A pair of elevation control plates each having an inner side surface coupled with the pair of elevation angle connecting portions, and an elevation adjustment slit for adjusting the elevation angle of the antenna unit, respectively; And
And a pair of elevational fasteners inserted into the elevation adjustment slit and engaged with the pair of second coupling portions and moving along the elevation adjustment slit.
The method of claim 10,
The azimuth adjustment unit,
A rotating plate formed to connect a lower end of the pair of elevation control plates between the pair of elevation control plates; And
And an azimuth tightening portion to rotatably couple the rotating plate to the auxiliary coupling member.
The method of claim 11,
The auxiliary coupling member,
A horizontal plate coupled to the rotating plate through the azimuth tightening portion under the rotating plate;
A vertical plate extending vertically from a distal end of the horizontal plate and coupled to the support plate; And
And a pair of supports formed between the horizontal plate and the vertical plate.
The method according to claim 1 or 9,
The antenna polarization angle adjusting unit,
An LNB lower cover rotatably seated on a rear surface of the first coupling part;
A polarization angle stopper seated on a rear surface of the LNB lower cover and coupled to the first coupling part to stop rotation of the LNB lower cover by a predetermined angle unit;
A Low Noise Block (LNB) received in the LNB lower cover and receiving a signal from the antenna unit to process a signal; And
And an LNB top cover coupled with the LNB bottom cover.
The method of claim 13,
The polarization stopper,
At least one fastening hole formed for fastening with the first coupling part;
And a fastening means penetrating the fastening hole to couple the polarization angle stopper and the first coupling part.
The method of claim 14,
The antenna polarization angle adjusting unit,
An opening formed in the LNB lower cover;
Engaging grooves formed at predetermined angular intervals along an edge of the opening at the back of the LNB lower cover; And
And at least one locking protrusion formed on the front surface of the polarization stopper and inserted into and engaged with the locking groove.
16. The method of claim 15,
The LNB lower cover is
When the rotation in a predetermined direction, the locking projection is locked to the locking groove to rotate by a unit of the spaced apart angle of the locking groove, the satellite antenna device.
16. The method of claim 15,
The satellite antenna device,
A goniometer displayed on the rear surface of the first coupling part; And
And an indicator portion formed on an upper end of the LNB lower cover and indicating an goniometer displayed on the rear surface of the first coupling portion.

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