KR102583974B1 - Method for Manufacturing and Reflectors for satellite antennas - Google Patents

Abstract

The present invention relates to a reflector for a satellite antenna and a method of manufacturing the same.
The reflector for a satellite antenna of the present invention and its manufacturing method include a mold coating step of spraying a release agent on a parabolic mold and then polishing it; A metal mold coating step of polishing the inner surface of the center metal mold of the mold coated in the above step and then clear coating it; A carbon skin step of stacking 8 pieces of carbon sheets in close contact with the mold and metal fitting coated in the above step to form a reflector shape, filling the space between the carbon sheets with carbon putty, and clear coating; A reinforcing material skin step of stacking 8 pieces of reinforcing sheets to form a reflector shape so that they are 2/3 the size of the reflector formed in the above step, and then filling the spaces between the reinforcing sheets with carbon putty; The carbon skin step is repeated once on the reflector formed in the above step, but when stacking the carbon sheets, the carbon skin repeat step is stacked alternately with the reinforcing sheet of the reinforcing skin step; After attaching a heat-resistant silicone pad so that the entire reflector formed in the above step is wrapped, vacuum working, molding at 100 degrees for 160 minutes with a hot air gun, demolding, and a finishing step of cutting the octagonal reflector into a circular reflector; do.
According to the present invention, when molding a large-sized reflector for an antenna, several layers are formed with carbon sheets and reinforcement sheets, so that heat resistance is maintained even at high temperatures and for long periods of time, and mold release is excellent, allowing for errors in the curvature and shape of the molded reflector. Provides a reflector for a satellite antenna and a method of manufacturing the same, which have low radio frequency and excellent durability, thereby increasing radio wave transmission and reception efficiency.

Description

Reflectors for satellite antennas and their manufacturing method. {Method for Manufacturing and Reflectors for satellite antennas}

The present invention relates to a reflector for a satellite antenna and a method of manufacturing the same. More specifically, when molding a reflector for a large-sized antenna, several layers are formed with carbon sheets and reinforcing sheets to maintain heat resistance even at high temperatures and for long periods of time. It relates to a reflector for a satellite antenna and a method of manufacturing the same, which has excellent release properties, small errors in the curvature and shape of the molded reflector, and is excellent in durability, thereby increasing radio wave transmission and reception efficiency.

In general, satellite antennas are used for microwave transmission of broadcast communication signals, data communication transmission for wireless networks, and transmission with satellites for satellite communication.

Among these satellite antennas, the large-sized satellite antenna consists of a reflector that reflects radio waves and focuses them, and an antenna feed that collects and transmits the radio waves. It transmits and receives signals according to the curvature of the reflector and the antenna feed that is precisely installed at the center of the reflector. Due to the large deviation in curvature, much research is needed to produce products with less change in curvature even in large sizes.

For example, Korean Patent Publication No. 10-1384312 includes a first layer forming one side of a parabolic shape; a second layer facing the first layer and forming a parabolic surface; and an inner layer provided between the first layer and the second layer, wherein an edge of the first layer and an edge of the second layer are formed to directly contact the first layer and the second layer. A reflector for an antenna is disclosed in which the edge of the layer is formed to have a radius of curvature center opposite to the center of the radius of curvature of the center of the first layer and the second layer.

However, the above technology not only causes curvature errors due to the reflectors being stacked in layers along the curvature, but also cannot precisely combine the antenna feed and the antenna feed without curvature correction by a skilled expert, and has the problem of gap between the reflector and antenna feed when used for a long time. there is.

Korean Patent Publication No. 10-1384312, ‘Reflector for antenna’

The present invention is intended to solve this problem. When molding a large-sized reflector for an antenna, several layers are formed of carbon sheets and reinforcing sheets, so that heat resistance is maintained even when molded at high temperatures and for long periods of time and molded with excellent mold release. The aim is to provide a reflector for a satellite antenna and a method of manufacturing the same, which has minimal errors in the reflector's curvature and shape, is excellent in durability, and increases radio wave transmission and reception efficiency.

In order to achieve the above object, the reflector for a satellite antenna of the present invention and its manufacturing method include a mold coating step of spraying a release agent on a parabolic mold and then polishing it; A metal mold coating step of polishing the inner surface of the center metal mold coated in the above step and then clear coating it; A carbon skin step of stacking 8 pieces of carbon sheets in close contact with the mold and metal fitting coated in the above step to form a reflector shape, filling the space between the carbon sheets with carbon putty, and clear coating; A reinforcing material skin step of stacking 8 pieces of reinforcing sheets to form a reflector shape so that they are 2/3 the size of the reflector formed in the above step, and then filling the spaces between the reinforcing sheets with carbon putty; The carbon skin step is repeated once on the reflector formed in the above step, but when stacking the carbon sheets, the carbon skin repeat step is stacked alternately with the reinforcing sheet of the reinforcing skin step; After attaching a heat-resistant silicone pad so that the entire reflector formed in the above step is wrapped, vacuum working, molding at 100 degrees for 160 minutes with a hot air gun, demolding, and a finishing step of cutting the octagonal reflector into a circular reflector; do.

In the mold coating step, it is preferable to first apply a liquid mold release agent and polish, and then secondly apply a silicone mold release agent and then polish.

In addition, after applying the secondary silicone mold release agent in the mold coating step, it is desirable to repeat polishing once more.

Additionally, the metal fitting coating step is preferably repeated three times at 20-minute intervals.

In addition, the metal fitting coating step, carbon skin step, and carbon skin repeat step are preferably coated with a clear coating made by mixing 3% of a heat-resistant hardener with 100 parts by weight of unsaturated polyester.

Additionally, it is preferable that the reflector for a satellite antenna is manufactured using the above methods.

The present invention according to the above solution, when molding a reflector for a large-sized antenna, forms several layers of carbon sheets and reinforcing sheets, so that heat resistance is maintained even at high temperatures and for long periods of time, and the mold release is excellent, reducing the curvature and shape of the molded reflector. The shape error is small and durability is excellent, which has the effect of increasing radio wave transmission and reception efficiency.

Figure 1 is a system diagram of a reflector for a satellite antenna of the present invention.
Figure 2 is an overall diagram of a method of manufacturing a reflector for a satellite antenna of the present invention.

The reflector for a satellite antenna and its manufacturing method of the present invention form multiple layers of carbon sheets and reinforcing sheets when molding a reflector for a large-sized antenna, so that heat resistance is maintained even when molded at high temperatures and for long periods of time, and molded with excellent mold release properties. The reflector's curvature and shape errors are small and its durability is excellent, increasing the efficiency of radio wave transmission and reception.

In this application, terms such as ~include~ or ~consist of~ are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains.

Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless explicitly defined in the present application, should not be interpreted in an ideal or excessively formal sense. No.

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

Figure 1 is a system diagram of a reflector for a satellite antenna of the present invention, and Figure 2 is a diagram showing an overall diagram of a manufacturing method of a reflector for a satellite antenna of the present invention.

As shown in Figures 1 and 2, the reflector for a satellite antenna of the present invention and its manufacturing method include a mold coating step (S10), a metal fitting coating step (S20), a carbon skin step (S30), a reinforcing material skin step (S40), It consists of a carbon skin repetition step (S50) and a finishing step (S60).

The mold coating step (S10) is a step of spraying a release agent on a parabola-shaped mold and then polishing it.

In this mold coating step (S10), a liquid release agent is first applied to the entire surface of the parabola mold and polished, and then, after 20 to 30 minutes, a silicone mold release agent is secondarily applied to the entire surface of the parabola mold, followed by polishing. After 20 to 30 minutes, it is advisable to wipe the entire surface of the parabola mold to remove the release agent.

Meanwhile, after applying the secondary silicone mold release agent in the mold coating step, it is preferable to repeat the polishing process once more after 20 to 30 minutes.

Through the mold coating step (S10), heat resistance is maintained even during molding at high temperatures and for long periods of time, and the mold release effect is increased.

The metal mold coating step (S20) is a step of polishing and then clear coating the inner surface of the center metal mold of the mold coated in step S20.

In this metal fitting coating step (S20), it is preferable that the cylindrical metal fitting into which the antenna feed is inserted is bolted to the center of the mold, and the inner surface of the metal fitting is polished and then clear coated.

At this time, it is desirable to repeat the metal fitting coating step three times at 20-minute intervals.

Meanwhile, the clear coating agent used in the clear coating is made by mixing 100 parts by weight of unsaturated polyester with 3% of a heat-resistant curing agent, which has the effect of making the surface of the reflector beautiful, highly glossy, and increasing durability when molding the reflector.

In the carbon skin step (S30), eight pieces of carbon sheets are stacked to form a reflector in close contact with the coated mold and metal fittings.

At this time, the space between the laminated carbon sheets is filled with carbon putty to make it flat, and then a clear coating agent is meticulously applied to the carbon sheets to impregnate the spaces between the carbon fabrics to clear coat them.

The carbon sheet has a triangular shape and is made up of 8 pieces, which are stacked on a mold and metal fitting to form an octagonal shape.

Meanwhile, the clear coating agent used in the clear coating is made by mixing 100 parts by weight of unsaturated polyester with 3% of a heat-resistant curing agent, which has the effect of making the surface of the reflector beautiful, highly glossy, and increasing durability when molding the reflector.

The reinforcing material skin step (S40) is a step of stacking 8 pieces of reinforcing sheets to form a reflector shape so that they are 2/3 the size of the reflector formed in the above step, and then filling the space between the reinforcing sheets with carbon putty.

The reinforcement sheet is made up of 8 pieces in a triangular shape and is laminated on the flat reflector carbon sheets formed through the carbon skin step (S30) to form an octagonal shape.

At this time, it is preferable that the reinforcement sheets are stacked alternately on the carbon sheets.

Meanwhile, the reinforcement sheet is a typical foam mat and preferably has a thickness of 1.5T to 2.0T.

The carbon skin repetition step (S50) is a step in which the carbon skin step is repeated once on the reflector formed in the above step, but when the carbon sheets are stacked, they are stacked alternately with the reinforcement sheets laminated in the previous reinforcement skin step.

The finishing step (S60) is a step of attaching a heat-resistant silicone pad so that the entire reflector formed in the above step is wrapped, vacuum working, molding at 100 degrees for 160 minutes with a heat gun, demolding, and cutting the octagonal reflector into a circular shape.

In addition, it is preferable that the reflector for a satellite antenna is made of the above steps.

In this way, the present invention forms multiple layers of carbon sheets and reinforcement sheets when molding a large-sized reflector for an antenna, so that heat resistance is maintained even at high temperatures and for long periods of time, and the mold release is excellent, so that the curvature and shape of the molded reflector can be adjusted. Errors are small and durability is excellent, which has the effect of increasing radio wave transmission and reception efficiency.

According to the present invention, when molding a large-sized reflector for an antenna, several layers are formed with carbon sheets and reinforcement sheets, so that heat resistance is maintained even at high temperatures and for long periods of time, and mold release is excellent, allowing for errors in the curvature and shape of the molded reflector. Provides a reflector for a satellite antenna and a method of manufacturing the same, which have low radio frequency and excellent durability, thereby increasing radio wave transmission and reception efficiency.

S10: Mold coating step
S20: Metal coating step
S30: Carbon skin stage
S40: Reinforcement skin stage
S50: Carbon skin repetition step
S60:Finishing stage
1:Mold
3: Metal fittings
5: Carbon sheet
7:Reinforcement sheet

Claims (6)

A mold coating step (S10) of spraying a release agent on a parabolic mold and then polishing it;
A metal mold coating step (S20) of polishing the inner surface of the center metal mold coated in the mold coating step and then clear coating it;
A carbon skin step (S30) of stacking 8 pieces of carbon sheets in close contact with the mold and metal fittings coated in the metal fitting step to form a reflector shape, filling the space between the carbon sheets with carbon putty, and clear coating;
A reinforcing material skin step (S40) of stacking 8 pieces of reinforcing sheets to form a reflector shape so that they are 2/3 the size of the reflector formed in the carbon skin step, and then filling the space between the reinforcing sheets with carbon putty;
A carbon skin repetition step (S50) in which the carbon skin step is repeated once on the reflector formed in the reinforcing material skin step, but when the carbon sheets are stacked, they are stacked alternately with the reinforcing sheet in the reinforcing material skin step;
After attaching a heat-resistant silicone pad so that the entire reflector formed in the carbon skin repetition step is wrapped, vacuum work, molding at 100 degrees for 160 minutes with a hot air gun, demolding, and a finishing step of cutting the octagonal reflector into a circular reflector (S60) ), consisting of;
Method of manufacturing a reflector for a satellite antenna. The method of claim 1, wherein the mold coating step includes first applying a liquid release agent and polishing, and then secondly applying a silicone release agent and then polishing. The method of claim 2, wherein after applying the secondary silicone mold release agent in the mold coating step, polishing is repeated one more time. The method of manufacturing a reflector for a satellite antenna according to claim 1, wherein the metal fitting step is repeated three times at 20-minute intervals. The method of manufacturing a reflector for a satellite antenna according to claim 1, wherein the metal fitting coating step, carbon skin step, and carbon skin repeat step are coated with a clear coating made by mixing 100 parts by weight of unsaturated polyester with 3% of a heat-resistant hardener. . The reflector for a satellite antenna according to any one of claims 1 to 5, manufactured by the above method.