KR101404195B1 - Satellite communication antenna having preset balancer - Google Patents

Abstract

A satellite communication antenna having a preset balancer according to an embodiment of the present invention includes: a reflection plate; A reflection plate flange provided at the center of the rear surface of the reflection plate and rotated together with the reflection plate; A cross level arm rotatably connected to the reflector flange such that an elevation angle of the reflector is variable; A main post having an upper end connected to a center portion of the cross level arm so that the cross level arm is rotatable; And a Ku band processing module or a Ka band processing module mounted on the reflector flange or provided to be separated from the reflector flange to receive or transmit radio waves of different frequency bands, wherein the Ku band processing module or the Ka band processing A preset balancer for maintaining load balance in the process of mounting the module on the reflector flange may be formed in the Ku band processing module or the Ka band processing module. By providing the preset balancer, there is no need to perform a post-operation to balance the load applied to the antenna for satellite communication after the Ku band processing module or the Ka band processing module is replaced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an antenna for a satellite communication having a preset balancer,

The present invention relates to an antenna for satellite communication, and more particularly, it relates to an antenna for a satellite communication, and more particularly to a method of adjusting a weight balance in a process of exchanging between Ku band processing modules and Ka band processing modules so as to receive or transmit all radio waves in Ku band and Ka band A satellite communication antenna having a preset balancer is provided.

Satellite Tracking Antenna or Satellite Communication Antenna mounted on a mobile body such as a car or a ship does not need to adjust the antenna even when the mobile body moves because it automatically tracks the satellite.

The satellite tracking antenna or the satellite communication antenna mounted on the moving body must be capable of transmitting and receiving both the circularly polarized wave and the linearly polarized wave transmitted from the satellite in a state of being mounted on the moving object. For this purpose, Band multi-band transceiver.

In the case of a satellite communication antenna mounted on a moving object such as a ship, that is, a satellite satellite for marine communication, it travels on an unbounded sea, so that it can receive or transmit radio waves from satellites in various frequency bands Should be able to. For this purpose, it is necessary to have a satellite communication antenna capable of transmitting and receiving radio waves of each band, which is practically impossible. Therefore, a method of attaching or detaching a low noise block down converter (LNB), a block up converter (BUC), or the like that matches the frequency band is used when the frequency band of the radio wave is changed while using one satellite communication antenna.

However, at present, it is very cumbersome to replace a low-noise block down converter or a block up converter according to the frequency band of the radio wave, and it is difficult to replace the low-noise block down converter or the block up converter.

In addition, depending on the frequency band, the size or weight of the low-noise block down-converter or the block up-converter is changed. Therefore, the load applied to the reflector changes, so that the load applied to the reflector is balanced after the replacement operation, It is inconvenient to additionally perform weight balancing operation in order to adjust and to stop the operation of the satellite communication antenna during the replacement operation. However, there is also a problem that the replacement operation takes a long time, .

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a method and apparatus for adjusting a weight balance in a process of replacing modules such as a low noise block down converter and a block up converter, The antenna for satellite communication is provided.

The present invention provides a satellite communication antenna having a plug and play type radio wave processing module that can be easily replaced even if it is not a skilled person.

Disclosure of Invention Technical Problem [10] The present invention provides a satellite communication antenna capable of minimizing the operation stoppage time of the antenna because it can reduce the time required for replacing the radio wave processing module.

According to an aspect of the present invention, there is provided a satellite communication antenna including a preset balancer, A reflection plate flange provided at the center of the rear surface of the reflection plate and rotated together with the reflection plate; A cross level arm rotatably connected to the reflector flange such that an elevation angle of the reflector is variable; A main post having an upper end connected to a center portion of the cross level arm so that the cross level arm is rotatable; And a Ku band processing module or a Ka band processing module mounted on the reflector flange or provided to be separated from the reflector flange to receive or transmit radio waves of different frequency bands, wherein the Ku band processing module or the Ka band processing A preset balancer for maintaining load balance in the process of mounting the module on the reflector flange may be formed in the Ku band processing module or the Ka band processing module.

By providing the preset balancer as described above, there is no need to perform a post-operation to balance the load applied to the satellite communication antenna after the Ku band processing module or the Ka band processing module is replaced.

The Ku band processing module includes: a bearing guide plate provided to face the reflector flange and rotating together with the reflector flange; And a skew plate mounted on the bearing guide plate so as to be positioned opposite to the reflection plate with respect to the bearing guide plate and capable of relative rotation with respect to the bearing guide plate, A block-up converter, and a diplexer and a waveguide that connect the low-noise block down-converter and the block-up converter, and the preset balancer includes a balance weight provided on the other side of the skew plate so as to face the block- .

The Ka band processing module includes a module plate provided to face the reflector flange and rotating together with the reflector flange; A low noise block down converter provided on the module plate; And a block up converter connected to the low noise block down converter and provided on the module plate, wherein the module plate includes a first bracket for mounting the low noise block down converter, a first bracket for mounting the block up converter, A pair of second brackets and a third bracket are formed and one end of each of the pair of second brackets is fixed to the module plate so as to be positioned on both sides of the first bracket and the third bracket is fixed to the other end And the block-up converter may be mounted on one surface of the third bracket.

Wherein the low noise block down converter and the block up converter are located on the same side and include a module weight positioned on one side opposite to the low noise block down converter or the block up converter with respect to the center of the module plate can do.

The preset balancer may include a bracket weight mounted on an outer surface of any one of the second brackets, and the module weight may be formed to be positioned between the second brackets.

The preset balancer may further include a weight bracket formed on an outer surface of the block up converter of the Ku band processing module or the Ka band processing module. The weight bracket may be formed to be variable in weight according to a load of the reflector.

A plurality of weight holes may be formed in the weight bracket.

The preset balancer may further include an arm weight formed on the cross level arm, and the arm weight may be formed to be symmetrical with respect to the center of the cross level arm.

As described above, since the low noise block down converter and the block up converter according to the frequency band of the radio wave are modularized, the mobile body mounted with the antenna moves Even if the frequency band changes, the radio wave processing module can be replaced easily.

Since the satellite communication antenna having the preset balancer according to the embodiment of the present invention uses the plug and play type radio wave processing module, it is possible to easily replace the radio wave module even if it is not a skilled technician.

The satellite communication antenna having the preset balancer according to the embodiment of the present invention does not need to adjust the weight balance even after the radio wave processing module is replaced according to the frequency band of the radio wave.

The satellite communication antenna having the preset balancer according to an embodiment of the present invention can reduce the time required for replacing the radio wave processing module and minimize the operation stop time of the antenna.

1 is a perspective view illustrating a satellite communication antenna having a preset balancer according to an embodiment of the present invention.
Fig. 2 is a perspective view showing the rear surface of the antenna for satellite communication according to Fig. 1. Fig.
FIG. 3 is a perspective view illustrating a state in which the Ku-band processing module is separated from the antenna for satellite communication according to FIG. 1. FIG.
FIG. 4 is a perspective view showing a Ku band processing module mounted on or separated from the antenna for satellite communication according to FIG. 1. FIG.
5 to 7 are perspective views illustrating a Ka-band processing module mounted on or separated from the satellite communication antenna according to FIG.
FIG. 8 is a perspective view showing a state in which the Ka-band processing module according to FIGS. 5 to 7 is mounted on the antenna for satellite communication according to FIG.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments. Like reference symbols in the drawings denote like elements.

FIG. 1 is a perspective view showing a satellite communication antenna having a preset balancer according to an embodiment of the present invention, FIG. 2 is a perspective view showing a rear surface of the satellite communication antenna according to FIG. 1, FIG. 4 is a perspective view showing a Ku band processing module mounted on or separated from the satellite communication antenna according to FIG. 1, FIGS. 5 to 7 are perspective views showing a Ku band processing module FIG. 8 is a perspective view illustrating a state in which the Ka-band processing module according to FIGS. 5 to 7 is mounted on the antenna for satellite communication according to FIG. 3, according to an embodiment of the present invention.

1 to 8, an antenna 100 for a satellite communication according to an embodiment of the present invention includes a reflector 101, a reflector 101 disposed at the center of the rear of the reflector 101, A cross level arm 104 rotatably connected to the reflector flange 151 such that the angle of elevation of the flange 151 and the reflector 101 is variable and an upper end of the cross level arm 104, A Ku-band processing module 120 or Ka-band processing module 120, which is mounted on the main post P and the reflector flange 151 connected to the center of the reflector flange 151 or separated from the reflector flange 151 to receive or transmit radio waves of different frequency bands, A preset balancer for maintaining a load balance in the process of mounting the Ku band processing module 120 or the Ka band processing module 220 on the reflector flange 151 includes Ku Band processing module Module 120 or the Ka-band processing module 220. [

It is not necessary to perform a post-operation for balancing the load applied to the satellite communication antenna after replacing the Ku band processing module or the Ka band processing module by providing the preset balancer having the size, weight or load set in advance as described above .

In addition, even when the object on which the satellite communication antenna 100 is installed moves or receives radio waves of different frequency bands using the removable Ku band processing module 120 and the Ka band processing module 220 It is not necessary to replace the antenna itself or to provide a plurality of antennas in order to cope with radio waves having different frequency bands.

A feed horn (not shown) for receiving a satellite signal or a radio wave may be formed on the front surface of the reflection plate 101. The reflection plate 101 must be able to rotate about the X axis, the Y axis, and the Z axis so that the feed horn of the satellite communication antenna 100 according to the embodiment of the present invention can track the satellite. An azimuth pulley 103 may be formed on the pedestal 102 so that the reflector 101 can be rotated about the Y axis. The azimuth pulley 103 is driven by an azimuth motor (not shown) to rotate the reflection plate 101 about the Y axis. Thus, the azimuth angle of the reflection plate 101 can be adjusted while rotating around the Y-axis.

The main posts P are provided on one side of the pedestal 102. A cross level arm 104 having a substantially U shape is provided on the upper end of the main post P. Cross level arms 104, The reflection plate 101 may be rotatably installed at both ends of the reflection plate 101. [

The cross level arm 104 can rotate about the Z axis passing through the upper end of the main post P. [ To this end, a cross-level pulley 165 is provided at the center portion of the cross-level arm 104. Also, the reflection plate 101 can adjust the elevation angle while rotating around the X-axis passing through both ends of the cross-level arm 104. [ The elevation angle pulley 106 may be provided at one end of the cross level arm 104 so that the reflection plate 101 can perform elevation angle movement.

A reflector flange 151 may be provided for connection of the reflector 101 and the cross level arm 104. The reflector flange 151 is a substantially disc-shaped member provided at the center of the rear surface of the reflector 101.

An elevation block 115 connected to the cross level arm 104 can be formed rotatably with respect to the cross level arm 104 at both ends (diametrically opposite ends) of the reflector flange 151. That is, the elevation angle block 115 is a member connecting the reflector flange 151 and the cross level arm 104, and the elevation angle block 115 is rotatable with respect to the cross level arm 104. The elevation angle block 115 is installed at both ends in the radial direction of the reflector flange 151 and the elevation bearing housing 117 is provided at both ends of the elevation angle block 104 facing the elevation angle block 115, 117 may be provided with an elevation bearing (not shown). The elevation angle bearing may be connected to an elevation shaft 116 connecting the elevation angle block 115 and the cross level arm 104. [ The reflector flange 151 and the cross level arm 104 are rotatably connected by the elevation angle block 115, the elevation angle shaft 116 and the elevation angle bearing 117 to adjust the elevation angle of the reflection plate 101 .

As shown in Fig. 1, arm weight 190 may be attached to one surface of cross level arm 104. As shown in Fig. The arm weight 190 is for uniformly adjusting the load applied to both sides of the arm 104 with respect to the center of the cross level arm 104. The arm weight 190 is symmetric with respect to the center of the cross level arm 104, It is preferable to adhere it to the surface. Here, the arm weight 190 is included in the above-described preset balancer, and the size or the weight of the arm weight 190 is predetermined.

On the other hand, various electronic components may be installed on the rear surface of the reflection plate 101. At this time, the satellite communication antenna 100 according to the embodiment of the present invention can be modularized by mounting various electronic components in the radio wave processing module.

Here, the radio wave processing module may include a Ku band processing module 120 or a Ka band processing module 220. The antenna for satellite communication in which the Ku band processing module 120 is mounted can receive or transmit the radio wave of the satellite corresponding to the Ku band in the frequency band and the antenna for satellite communication in which the Ka band processing module 220 is mounted has the frequency band It is possible to receive or transmit the radio wave of the satellite corresponding to the Ka band.

The antenna for satellite communication 100 according to an embodiment of the present invention may be configured such that a Ku band processing module 120 is provided to easily replace the Ku band processing module 120 with the Ka band processing module 220 or vice versa, 120 and the Ka band processing module 220 may be formed in a plug and play type. For example, when the Ku band processing module 120 attached to the satellite communication antenna 100 is removed and the Ka band processing module 220 is mounted at the same position, the Ka band can be received or transmitted. No additional work is required after changing the processing module.

Hereinafter, the Ku band processing module 120 and the Ka band processing module 220 will be described with reference to the drawings. 2 and 4 show a state in which the Ku band processing module 120 is mounted on the satellite communication antenna and the Ku band processing module 120 and FIGS. 5 to 8 show the state in which the Ka band processing module 220 and the Ka band processing module 120, (220) is mounted on the satellite communication antenna.

The Ku band processing module 120 is provided to face the reflector flange 151 and is disposed opposite to the reflector 101 with respect to the bearing guide plate 141 and the bearing guide plate 141 that rotate together with the reflector flange 151 And a skew plate 121 mounted on the bearing guide plate 141 and capable of rotating relative to the bearing guide plate 141. The reflection plate 101, the reflector flange 151, and the bearing guide plate 141 rotate together, but the skew plate 121 may not rotate together.

The Ku band processing module 120 includes a bearing guide plate 141 mounted on the rear surface of the reflection plate 101 and rotating integrally with the reflection plate 101, And a skew plate 121 mounted on the plate 141 and capable of relative rotation with respect to the bearing guide plate 141.

In addition, a low-noise block down-converter 124, a block up-converter 110, a diplexer 126 for connecting the low-noise block down-converter 124 and the block up-converter 110 to the rear surface of the skew plate 121, (127) may be provided.

The Ku band processing module 120 is mounted on the reflector flange 151 on the rear side of the reflector 101 and can be mounted detachably on the reflector flange 151. The Ku band processing module 120 may be mounted on the reflector flange 151 so as to be positioned opposite the reflector 101 with respect to the reflector flange 151. [

Various components installed in the Ku band processing module 120 may be installed in the skew plate 121 provided to be rotatable with respect to the reflector flange 151. At this time, the reflector flange 151 and the skew plate 121 are not directly connected, but the skew plate 121 can be connected to the bearing guide plate 141 provided on the rear surface of the reflector flange 151. The skew plate 121 may be rotatably mounted on the bearing guide plate 141.

A low noise block down converter 124, a diplexer 126, a block up converter 110, a wave guide 127, and the like may be provided on the rear surface of the skew plate 121. Here, the block up converter 110 is larger than the other components, and is located at one side of the skew plate 121. Therefore, in order to balance the load on the skew plate 121, the balance weight 130 may be mounted on the rear surface of the skew plate 121 so as to be positioned at a position opposite to the block up-converter 110. Here, the balance weight 130 is included in the preset balancer. It is possible to determine the size or weight of the balance weight 130 in consideration of the loads of various electronic components installed in the skew plate 121 such as the block up converter 110 and the low noise block down converter 124, 120, it is not necessary to adjust the weight of the balance weight 130 again.

When the satellite communication antenna 100 receives linearly polarized waves, the skew plate 121 can be rotated with respect to the bearing guide plate 141 for skew compensation. A skew motor 122 and a skew pulley (not shown) may be formed on the skew plate 121 for rotational movement of the skew plate 121. [

The skew plate 121 can be rotated in a state where a plurality of parts are mounted on the rear surface thereof, and it can be rotated by an operator as well as rotated by the skew motor 122. In other words, the operator can grasp the handle 123 formed at one end of the skew plate 121 to forcibly rotate the skew plate 121.

The Ku band processing module 120 can replace the entire module by attaching or detaching the bearing guide plate 141 to or from the reflector flange 151. [ A positioning pin 154 may be formed on the reflector flange 151 to attach or detach the Ku band processing module 120 to the reflector flange 151 and the positioning guide pin 141 may be provided with a positioning pin 154, A positioning hole 143 can be formed.

The positioning pin 154 and the positioning hole 143 allow the operator to easily find the correct mounting position of the Ku band processing module 120 in the process of mounting the Ku band processing module 120 on the reflector flange 151 I will let you. The fastening holes 142 formed in the vicinity of the four corners of the bearing guide plate 141 in the state in which the positioning pins 154 are inserted into the positioning holes 143 of the Ku band processing module 120, So that the Ku band processing module 120 can be mounted on the reflector flange 151. 4, the positioning pin 154 is formed on the reflector flange 151 so as to be in line with both ends of the cross level arm 104, and a flange fastening hole 153 communicating with the fastening hole 142 is formed And may be formed on the reflector flange 151.

As described above, the block-up converter 110 of the Ku-band processing module 120 is provided on one side of the skew plate 121, and on the other side of the skew plate 121 facing the block-up converter 110, (130) may be formed. At this time, the block up-converter 110 and the balance weight 130 may be provided on the same plane with respect to the skew plate 121. [ It is possible to prevent the eccentric load from being caught by the skew plate 121 when the skew plate 121 rotates by attaching a preset balancer such as the balance weight 130 at a position facing the block up-

When the Ku band processing module 120 is detached or detached from the reflected wave flange 151, the state shown in FIG. 3 is obtained. In the state of FIG. 3, when the Ka band processing module 220 is attached or attached instead of the Ku band processing module 120, it is possible to receive or transmit a radio wave of the Ka frequency band.

5 to 8, the Ka band processing module 220 includes a module plate 241 provided to face the reflector flange 151 and rotated together with the reflector flange 151, A block up converter 250 connected to the low noise block down converter 260 and the low noise block down converter 260 and provided to the module plate 241. Unlike the Ku band processing module 120, the Ka band processing module 220 can rotate the low noise block down converter 260 and the block up converter 110 together with the reflector flange 151. That is, the Ka band processing module 220 does not have a configuration corresponding to a separate skew plate.

The Ka band processing module 220 is smaller in size than the Ku band processing module 120, but has an advantage in that it can process more data than the Ku band processing module 120.

The module plate 241 may be provided with a catch hole 243 into which the catch pin 154 formed in the reflector flange 151 is inserted.

The positioning pin 154 and the positioning hole 243 allow the operator to easily find the correct mounting position of the Ka band processing module 220 in the process of mounting the Ka band processing module 220 on the reflector flange 151 I will let you. A fastening member such as a bolt is fastened to the fastening holes 242 formed near the four corners of the module plate 241 in the state where the positioning pins 154 are inserted into the positioning holes 243 of the Ka band processing module 220 So that the Ka band processing module 220 can be mounted on the reflector flange 151. The fastening holes 242 can be engaged with the flange fastening holes 153 formed in the reflector flange 151.

The module plate 241 is provided with a first bracket 262 for mounting the low noise block down converter 260, a pair of second brackets 244 and a third bracket 245 for mounting the block up converter 250, Can be formed.

The low noise block down converter 260 and the block up converter 250 of the Ka band processing module 220 need to be installed so as to overlap with each other because the Ka band processing module 220 is relatively smaller than the Ku band processing module 120 Do. To this end, the pair of second brackets 244 are fixed to the module plate 241 at one end so as to be positioned on both sides of the first bracket 262 on which the low-noise block down converter 260 is mounted, 245 may be fixed to the other end of the second bracket 244 and the block up converter 250 may be mounted on one side of the third bracket 245.

5 to 7, the pair of second brackets 244 have a sufficient length in a direction orthogonal to the module plate 241 so as not to cause interference with the low-noise block down-converter 260, The pair of second brackets 244 can be fixed to the module plate 241 in a sufficiently separated state so that the low noise block down converter 260 can be positioned between the second brackets 244. [

On the other hand, the low-noise block down-converter 260 and the block-up converter 250 are located on the same side of the module plate 241, and the low-noise block down-converter 260 or the block- The module weight 230 positioned on one side can be mounted on the module plate 241. [ Since the module weight 230 is included in the preset balancer and the size or weight of the module weight 230 is determined in advance, , There is no need to adjust the weight again.

5 to 7, it can be seen that the low-noise block down-converter 260 and the block-up converter 250 are biased to the same side (left side in the drawing). The module weight 230 may be attached to the module plate 214 so as to be opposite to the low noise block down converter 260 or the block up converter 250 in order to balance the load applied to the module plate 241. [

7, the module weight 230 is located between the second brackets 244, and the bracket weight 225 may be mounted on the outer surface of any one of the second brackets 244, And the handle 223 may be formed on the other outer surface. Here, the bracket weight 225 is also a preset balancer.

2, the Ku band processing module 120 may further include a weight bracket 136 formed on the outer surface of the block up-converter 110, and the weight bracket 136 may include a load of the reflector 101 The weight can be changed according to the weight of the body. That is, the weight bracket 136 can be reduced or extended in accordance with the load of the reflection plate 101 caught by the bearing guide plate 141 or the skew plate 121. Therefore, a load balancing with the load of the reflection plate 101 can be caught by the bearing guide plate 141 or the skew plate 121. Here, the weight bracket 136 is a preset balancer.

Similarly, the Ka-band processing module 220 may further include a weight bracket 246 formed on an outer surface of the block up-converter 250, and the weight bracket 246 may be weight-variable according to the load of the reflection plate 101 . Here, the weight bracket 246 is a preset balancer.

In addition, the weight brackets 136 and 246 may be formed with a plurality of weight holes 137 and 247. The weight of the weight brackets 136 and 246 can be adjusted according to the shape and size of the weight holes 137 and 247 and the length of the cable can be reduced by connecting various cables (not shown) through the weight holes 137 and 247.

The weight brackets 136 and 246 may be connected to the Ku band processing module 120 and the Ka band processing module 220, respectively, by the weight supports 138 and 248.

2, a first connector bracket (not shown) to which a first cable connector 171 connected to a cable 172 of the radio wave processing module 120 or 220 is connected and a first connector bracket And a second connector bracket 178 connected to a second cable connector 176 connected to a cable 177 of a control box (not shown)

A gender (not shown) may be provided between the first connector bracket and the second connector bracket 178 to be connected to the first cable connector 171 and the second cable connector 176.

The first cable connector 171 may be provided at one end of the cable 172 of the Ku band processing module 120 and the Ka band processing module 220, respectively.

After the first cable connector 171 connected to the cable of the Ku band processing module 120 is separated from the gender or the second cable connector 176 and the Ku band processing module 120 is separated from the reflector flange 151, The first cable connector 171 connected to the cable of the Ka band processing module 220 is connected to the gender or the second cable connector 176 and the Ka band processing module 220 is mounted and fixed to the reflector flange 151 The antenna for satellite communication as shown in Fig. 8 can be obtained, and the radio wave processing module can be replaced in a simple and short time.

As described above, the satellite communication antenna according to one embodiment of the present invention includes a preset including an arm weight 190, a balance weight 130, a module weight 230, weight brackets 136 and 246, and a bracket weight 225 The balancer eliminates the need to rebalance the Ku-band processing module and the Ka-band processing module in order to add or remove the balancer.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention .

100: Satellite communication antenna 101: Reflector
104: Cross level arm 110: Block up converter
120: Ku band processing module 121: Skew plate
124: Low-noise block down converter 130: Balance weight
141: bearing guide plate 151: reflector flange
154: locating pin 171: first cable connector
173: first cable bracket 176: second cable connector
178: second cable bracket 190: arm weight
220: Ka band processing module 241: Module plate
250: Block-up converter 260: Low-noise block down converter

Claims (8)

Reflector;
A reflection plate flange provided at the center of the rear surface of the reflection plate and rotated together with the reflection plate;
A cross level arm rotatably connected to the reflector flange such that an elevation angle of the reflector is variable;
A main post having an upper end connected to a center portion of the cross level arm so that the cross level arm is rotatable; And
A Ku band processing module or a Ka band processing module mounted on the reflector flange or provided to be separated from the reflector flange to receive or transmit radio waves of different frequency bands,
The Ku band processing module or the Ka band processing module is formed with a preset balancer for maintaining a load balance in the process of mounting the Ku band processing module or the Ka band processing module on the reflector flange,
Wherein the preset balancer includes an arm weight formed on the cross level arm.
The method according to claim 1,
The Ku band processing module includes:
A bearing guide plate provided to face the reflector flange and rotating together with the reflector flange; And
And a skew plate mounted on the bearing guide plate so as to be positioned opposite to the reflection plate with respect to the bearing guide plate and being rotatable relative to the bearing guide plate,
A low-noise block down-converter, a block-up converter, and a diplexer and a waveguide that connect the low-noise block down-converter and the block-up converter are provided on a rear surface of the skew plate,
Wherein the preset balancer includes a balance weight provided on the other side of the skew plate so as to face the block-up converter.
3. The method of claim 2,
The Ka-band processing module includes:
A module plate provided to face the reflector flange and rotated together with the reflector flange;
A low noise block down converter provided on the module plate; And
And a block up converter connected to the low noise block down converter and provided on the module plate,
Wherein the module plate includes a first bracket for mounting the low noise block down converter, a pair of second brackets for mounting the block up converter, and a third bracket,
One end of each of the pair of second brackets is fixed to the module plate so as to be positioned on both sides of the first bracket and the third bracket is fixed to the other end of the second bracket,
And the block-up converter is mounted on one surface of the third bracket.
The method of claim 3,
Wherein the preset balancer comprises:
Wherein the low noise block down converter and the block up converter are located at the same side with respect to the center of the module plate and include a module weight located at one side opposite to the low noise block down converter or the block up converter, Antenna for satellite communication.
5. The method of claim 4,
Wherein the preset balancer includes a bracket weight mounted on an outer surface of any one of the second brackets, and the module weight is formed to be positioned between the second brackets.
6. The method of claim 5,
Wherein the preset balancer further comprises a weight bracket formed on an outer surface of the block up converter of the Ku band processing module or the Ka band processing module,
Wherein the weight bracket is formed to be variable in weight according to a load of the reflection plate.
The method according to claim 6,
And a plurality of weight holes are formed in the weight bracket.
8. The method according to any one of claims 1 to 7,
Wherein the arm weight is formed to be symmetrical with respect to the center of the cross level arm.

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