KR100923338B1 - Rim structure of a satellite dish antenna - Google Patents

Abstract

The edge structure of the satellite dish antenna includes a dish body; And a flange disposed around the periphery of the dish-shaped body. The foldable support ring is formed on top of the flange. The flange between the bottom rim of the dish-shaped body and the support ring includes an inwardly recessed receiving groove. Therefore, when several antennas are stacked on each other, the receiving groove of the upper dish type body is disposed at the inner edge of the support ring of the lower dish type body, so that when these antennas are stacked up, the dish antennas fit snugly together. do. In this way, the stability of the stacked structures can be ensured, thereby avoiding unwanted slipping to the floor. In addition, the stacking space can be saved.

Description

Rim structure of a satellite dish antenna {RIM STRUCTURE OF A SATELLITE DISH ANTENNA}

1 is a cutaway view of a conventional edge structure of a satellite dish antenna.

Figure 2 is a schematic diagram showing a conventional satellite dish antenna according to Figure 1 in a stacked state.

3 is a cutaway view of another conventional border structure of a satellite dish antenna;

4 is a schematic diagram showing a conventional satellite dish antenna according to FIG. 3 in a stacked state;

5 is a perspective view of a first embodiment of the present invention.

Figure 6 is a cut surface of the frame structure of the first embodiment of the present invention.

7 is a schematic view showing the satellite dish antenna according to FIG. 6 in a stacked state;

Fig. 8 is a cut section of the frame structure of the second embodiment of the present invention.

9 is a schematic diagram illustrating the satellite dish antenna according to FIG. 8 in a stacked state;

10 is a schematic diagram showing a third embodiment of a satellite dish antenna according to the present invention in a stacked state;

11 is a side view of the present invention in a stacked state.

The present invention relates to an edge structure of a satellite dish antenna, and more particularly, to a structure that is arranged around the periphery of the dish body and provides a stable stacking behavior by providing a concave border toward the inside.

In the past, terrestrial radio communications were often influenced by factors such as topography and buildings, the atmosphere, the curvature of the earth, and the electromagnetic fields of the universe, reflecting, refracting, and diffracting normal communications radio waves, thus worsening communications results and quality.

Accordingly, a communication satellite is introduced to overcome the drawbacks of conventional wireless communications, and earth stations, including dish antennas, feedhorns, low noise amplifiers (LNAs), down converters and satellites, Since the main electronic means for receiving the radio wave signal transmitted from the satellite in space orbit can be efficiently received.

The dish antenna is a window to the entire earth station and its shape looks like a dish, but its structure is actually parabolic for easy focusing of weak signals scattered on the antenna surface, resulting in a single focal point in front of the antenna . Such focus is usually used as a location for installing the feed horn, so the quality and structural techniques of the antenna significantly affect the signal reception.

Satellite antennas are used to capture signals from satellites in outer space and reflect them to intrinsic focus, but the ability to capture signals largely depends on the precision of the disk curvature. Whether the satellite dish antenna is elliptical or rectangular, the common satellite dish antenna includes curvature with focus.

As shown in FIGS. 1 and 2, the flange 20 is disposed around the periphery of the bottom rim 11 of the arc dish-shaped body 10. Folded support ring 30 is formed in the upper portion of the flange (20). As shown in Figures 1 and 2, the support ring 30a is formed by bending the upper portion of the flange 20 toward the outside. 3 and 4, the other support ring 30b is formed by bending the upper portion of the flange 20 toward the inside. Whichever support ring 30 is used, the satellite dish antenna should be placed in a flat position when loaded into the container for transport out of the factory. As shown in FIGS. 2 and 4, the bottom rim 11 and the flange 20 of the dish-shaped body 10 are designed at a wide angle. When the upper dish body 10 is placed on the lower dish body 10, the support ring 30 of the lower dish body 10 is the support ring 30 of the lower dish body 10 is the outer (30a) Abutting toward the end 12 of the bottom rim 11 of the upper dish-shaped body 10, whether bent toward the side or bent toward the interior 30b.

Since the support ring 30 of the dish-shaped body 10 is arcuate, the upper dish-shaped body 10 tends to fall to the floor and be damaged when it is affected by vibration or in an inappropriate position. In addition, since the conventional dish-shaped body 10 occupies a large amount of vertical space H1 that is stacked integrally, a large container is required to increase the transportation cost. All of the above problems need to be urgently solved in the relevant manufacturing field.

Accordingly, a main object of the present invention is to provide an edge structure of a satellite dish antenna including a flange having a receiving groove recessed inside. In this way, the upper dish body fits snugly into the lower dish body, thus ensuring a stable stacking structure and reducing the stacking space. In addition, the satellite dish antenna is prevented from being damaged by slipping to the floor. On the other hand, improper stacking, which occupies limited container space, can be avoided, thus saving a lot of transportation costs.

In order to achieve the above object, the present invention

a) dish-shaped body; And

b) a flange disposed around the periphery of the dish-shaped body and having a foldable support ring formed thereon;

Including,

The flange between the bottom rim of the dish-shaped body and the support ring includes an inwardly recessed receiving groove, and the receiving groove of the upper dish-shaped body fits against each other when a plurality of dish antennas are stacked on each other. Is disposed on the inner edge of the support ring of the lower dish body.

5 to 7, the dish antenna 40 according to the first embodiment of the present invention includes a dish body 10 and a flange 20.

To form the body of the dish antenna, the dish body 10 is made of metal or plasticizing material in one piece.

The flange 20 is disposed around the periphery of the dish-shaped body 10. The foldable support ring 30 is formed on the flange 20.

The present invention is characterized in that the flange (20) between the bottom edge of the dish-shaped body (10) and the support ring (30) comprises an accommodating groove (21). In this way, when a plurality of dish-shaped antennas 40 are stacked up, the receiving groove 21 of the upper dish-shaped body 10 is placed on the inner edge of the support ring 30 of the lower dish-shaped body 10. Is placed. That is, when the dish antennas 40 are stacked up, these dish antennas 40 fit together.

In an embodiment, the support ring 30a is formed by bending the top of the flange 20 outward. As shown in FIG. 7, the receiving groove 21 of the dish-shaped body 10 of the upper dish antenna 40 is placed on the inner edge of the support ring 30a of the lower dish antenna 40. In this way, the upper support ring 30a and the lower support ring 30a are stacked on each other and smoothly aligned. Thus, there is no need to worry about the antennas slipping or falling to the floor during transportation.

8 and 9, the second embodiment is basically the same as the first embodiment. Like elements in the first and second embodiments are denoted by the same reference numerals. Another difference is that the support ring 30b is formed by bending the upper portion of the flange 20 inward. In this way, when the dish antenna 40 is placed on the other antenna, the receiving groove 21 of the upper dish antenna 40 is the inner edge of the upper surface of the support ring 30b of the lower dish antenna 40. Is placed on. Thus, the effect of the first embodiment for avoiding the risk of slipping can be similarly achieved by the second embodiment.

As shown in Fig. 10, the third embodiment is basically the same as the second embodiment. The same reference numerals are given to the same components in the second and third embodiments. The difference is that the flange 20 is formed at a slightly inclined position 22. This embodiment also ensures practical fitting and positioning effects.

As shown in Fig. 11, the structure according to the present invention ensures a stable positioning effect and prevents damage due to slipping to the floor when a plurality of dish antennas 40 are placed on another antenna. On the other hand, by fitting the dish-shaped bodies 10 together, the height H2 is considerably reduced, thereby reducing the transportation space of the container and thus saving the transportation cost.

Of course, various modifications and variations to the above-described embodiments of the invention can be made without departing from the scope of the invention. Accordingly, in order to advance science and useful technology, the present invention has been disclosed and is intended to be limited only by the claims.

The edge structure of the satellite dish antenna including a flange having a concave receiving groove in the interior according to the present invention is stable stacking because the upper dish body fits the lower dish body when the antennas are stacked and transported. The raised structure can be guaranteed and the stacking space can be reduced. In addition, the satellite dish antenna is prevented from being damaged by slipping to the floor. On the other hand, improper stacking, which occupies limited container space, can be avoided, thus saving a lot of transportation costs.

Claims (3)

As the edge structure of satellite dish antenna, a) dish-shaped body; And b) a flange disposed around the periphery of the dish-shaped body and having a foldable support ring formed thereon Including, The flange between the bottom rim of the dish-shaped body and the support ring includes a receiving groove recessed inwardly, The support ring is formed by bending an upper portion of the flange inwardly, The receiving groove of the upper dish type body is disposed on the inner edge of the support ring of the lower dish type body so that a plurality of dish antennas fit against each other when they are stacked on each other. The upper inner edge is to support the receiving groove of the upper dish-shaped body Border structure of satellite dish antenna. delete delete

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