KR101471838B1 - Cap structure for Radome Assembling of Antenna - Google Patents

Abstract

A cap structure for assembling a radome of an antenna of the present invention includes a base plate for forming a wall surface for sealing the end of a radome and having a reflector coupled thereto; An outer side frame formed around the outer periphery of the base plate; An inner side edge offset from the outer side edge by a predetermined distance to form a groove into which the end of the radome is inserted; And a water drop hole formed at a predetermined interval along the bottom of the groove formed between the inner side edge and the outer side edge.
In the present invention, water drop holes are formed on a rainwater inflow path of a cap coupled with a radome to simplify the assembling process by omitting the silicone application work for preventing flooding, and it is possible to prevent semi-permanent flooding, It is possible to reduce the management cost of the system.

Description

Technical Field [0001] The present invention relates to a cap structure for radome assembly of an antenna,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cap structure for radome assembly of an antenna and a radome and a cap assembly method for an antenna, And more particularly, to a cap structure for radome assembly of an antenna and a method of assembling a radome and a cap of an antenna.

Various technologies have been applied to increase the capacity (bps / Hz), which is the transmission rate of the frequency band, in the Mobile WiMAX or LTE (Long Term Evolution) communication system, which is an international standard representing the 4G network. (Multiple Antenna Technology), which is called Multi-Input Multi-Output (MIMO).

Although the base of multi-antenna technology in base station antennas is based on baseband signal processing technology, the capacity improvement effect using multiple antennas is significantly different according to the antenna configuration.

The reason for this is that the multi-antenna technique is a technique for actively using a plurality of multi-path fading but eliminating an interference signal from other subscribers. Therefore, even in the same antenna installation configuration, (Wave Propagation) environment and subscriber distribution. Therefore, the international standard does not include the antenna installation shape in the standard, but the antenna can be freely installed according to the field conditions to maximize the capacity.

FIG. 1 is an assembled perspective view illustrating a radome assembly structure of a conventional antenna, and FIG. 2 is an exploded perspective view illustrating a radome assembly structure of a conventional antenna.

In the conventional radome assembly structure, a reflector 20 is installed in a rectangular tube or a streamlined tube-like radome 10, and a front plate (not shown) for assembling various types of connectors is attached to an end of the reflector 20, (30).

A cap 40 is coupled to the front surface of the front plate 30 using a screw or a hook method and the cap 40 is coupled to an end of the radome 10.

At this time, rainwater rushes between the radome 10 and the cap 40 to prevent the reflection plate 20 and the front plate 30 from being submerged in the radome 10 and the cap 40, Silicone is applied to make the waterproof treatment.

However, such a conventional art has a problem that the assembling process is cumbersome, the assembling process takes a long time, and leakage of water due to defective application of silicone or aging occurs and waterproofing is difficult.

Korean Patent Publication No. 10-2011-0071818 (Published on June 29, 2011)

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the drawbacks of the prior art by forming water drop holes in a rainwater inflow path of a cap coupled with a radome to simplify the assembly process by omitting the silicone application process for preventing flooding And a method of assembling the radome and the cap of the antenna.

According to an aspect of the present invention, there is provided a cap coupled with a radome of an antenna, the cap including a base plate defining a wall surface sealing the end of the radome and having a reflector coupled thereto; An outer side frame formed around the outer periphery of the base plate; An inner side edge offset from the outer side edge by a predetermined distance to form a groove into which the end of the radome is inserted; And a water vent hole formed at a predetermined distance along the bottom of the groove formed between the inner side edge and the outer side edge.

Further, a reflection plate fixing protrusion is protruded from the inner surface of the base plate.

At this time, a fastening hole for bolt-joining the reflection plate may be formed on the reflection plate fixing structure.

A connector hole and a knob hole for coupling the connector and the knob may be formed on the base plate.

According to another aspect of the present invention, there is provided a method of manufacturing a reflector, comprising: combining a reflector using a reflector plate formed on an inner surface of a cap; Coupling a connector and a knob using a connector hole and a knob hole formed on a base plate of the cap; And an end portion of the radome is inserted into a groove formed between the outer side edge and the inner side edge of the cap to form a drainage path for the rainwater so that the rainwater that has fallen on the outer surface of the radome is discharged through the water drop hole formed in the groove bottom portion A radome and a cap assembly method of an antenna including the steps of:

In the present invention, water drop holes are formed on a rainwater inflow path of a cap coupled with a radome to simplify the assembling process by omitting the silicone application work for preventing flooding, and it is possible to prevent semi-permanent flooding, It is possible to reduce the management cost of the system.

1 is an exploded perspective view showing a radome assembling structure of a conventional antenna.
BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to an antenna.
3 is an exploded perspective view showing the cap structure for assembling the radome of the antenna according to the present invention.
4 is a bottom assembled perspective view and a plan view showing a cap structure for assembling the radome of the antenna according to the present invention.
5 is a perspective view showing the internal structure of the cap according to the present invention.

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

FIG. 3 is an exploded perspective view showing a cap structure for assembling the radome of the antenna according to the present invention, and FIG. 4 is a bottom assembled perspective view and a plan view showing the cap structure for assembling the radome of the antenna according to the present invention.

In the radome assembly structure of the present invention as shown in the figure, a reflection plate 120 is installed in a rectangular tube or a streamlined tube-shaped radome 110. At this time, the reflection plate 120 may be fixed using a cap 140. [

At this time, the cap 140 is coupled to the end of the radome 110 to seal the inner space of the radome 110. The cap 140 may be coupled to the upper and lower ends of the radome 110, The structure of the cap 140 coupled to the lower end of the radome 110 will be described.

The cap 140 according to the present invention provides a flood prevention structure that prevents rainwater from flowing into the radome 110 through the coupling portion between the radome 110 and the cap 140 and flooding the interior.

5 is a perspective view showing the internal structure of the cap according to the present invention.

The cap 140 of the present invention as shown in the same figure forms a wall surface for sealing the end of the radome 110 and a base plate 141 to which the reflection plate 120 is coupled.

Such a base plate 141 provides an integral structure capable of performing a role of a front plate to which the reflection plate 120 of the prior art is coupled.

At this time, a plurality of reflecting plate fixing strips 145 protrude from the inner surface of the base plate 141. The fixing plate 145 is a fixing structure for fixing the reflection plate 120 to the base plate 141. The fixing plate 145 includes a horizontal plate having a fixing hole 145a for bolt- And a support lip which is padded in a perpendicular direction to support the lip.

A connector hole 141a and a knob hole 141b for coupling the connector 150 and the knob 160 may be formed on the base plate 141. [ A plurality of the connector 150 and the knob 160 may be formed and a screw 150 for fixing the connector 150 and the knob 160 may be formed around the connector hole 141a and the knob hole 141b. Fastening holes can be formed.

In addition, a closed loop outer peripheral edge 142 is formed along the outer circumference of the base plate 141. At this time, the outer side frame 142 is protruded at a predetermined height so as to surround the outer circumference of the end portion of the radome 110.

An inner side edge 143 is formed to be offset from the outer side edge 142 by a predetermined distance. At this time, the inner side frame 143 protrudes to a certain height so as to surround the inner surface of the end portion of the radome 110. The height of the outer side frame 142 and the inner side frame 143 may be the same or the height of the inner side frame 143 may be higher.

A groove having a predetermined gap is formed between the outer side rim 142 and the inner side rim 143. The end of the radome is fitted into the groove.

The distance between the outer side rim 142 and the inner side rim 143 is preferably equal to the thickness of the radome 110.

At this time, the water drop holes 144 may be formed at regular intervals along the bottom of the groove formed between the inner side edge 143 and the outer side edge.

The water drop hole 144 is formed on the rainwater inflow path of the cap 140 coupled with the radome 110 so that the rainwater can be drained without flowing into the radome 110, Thereby simplifying the assembly process by omitting the silicon application operation.

Hereinafter, a method of assembling a radome and a cap of an antenna according to the present invention will be described.

First, the cap 140 and the reflection plate 120 are combined. At this time, the reflection plate 120 is coupled using the reflection plate fixing rib 145 formed on the inner surface of the cap 140. A plurality of fastening holes 145a are formed in the reflector fixing part 145 so that the reflector 120 can be bolted.

The connector 150 and the knob 160 may be coupled using a connector hole 141a and a knob hole 141b formed on the base plate 141 of the cap 140. [

At this time, the end of the radome 110 is fitted into the groove formed between the outer side edge 142 of the cap 140 and the inner side edge 143. The cap 140 and the radome 110 are screwed together to prevent the cap 140 from being separated.

At this time, the end face of the radome 110 is positioned above the water drop hole 144 in the groove, and the rainwater that has fallen on the outer surface of the radome 110 is discharged through the water drop hole 144 formed in the bottom of the groove Thereby forming a drainage path.

As described above, according to the present invention, water drop holes are formed on a rainwater inflow path of a cap coupled with a radome to perform natural drainage, so that it is possible to omit the operation of applying silicone for preventing flooding around the cap do.

This makes it possible to simplify the assembling process and prevent the semi-permanent inundation prevention, thereby reducing the maintenance cost due to the maintenance.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, it is to be understood that the described embodiments are to be considered in all respects as illustrative and not restrictive, .

110: Radome 120: Reflector
140: cap 141: base plate
141a: Connector hole 141b: Knob hole
142: Outer side rim 143: Inner side rim
144: water-drop hole 145: reflector fixing
150: connector 160: knob

Claims (5)

A cap 140 coupled to the radome of the antenna, wherein the cap 140 forms a wall surface for sealing the end of the radome 110 and has a base plate 141 to which the reflection plate 120 is coupled;
An outer frame 142 formed around the outer periphery of the base plate 141 and having a structure protruding at a predetermined height so as to surround the outer periphery of the end of the radome;
An inner side frame 143 having a structure in which a groove for receiving the end portion of the radome is formed at a predetermined interval offset from the outer side frame 142 and protrudes at a predetermined height so as to surround the inner circumference of the end portion of the radome; And
A water drop hole 144 formed at a predetermined interval along the bottom of the groove formed by the radome end portion formed in the groove with a predetermined interval between the inner side rim 143 and the outer side rim;
/ RTI >
The base plate may provide an integral structure capable of performing a function of a front plate to which the reflection plate is coupled,
Wherein the water drop hole is formed on the rainwater inflow path of the cap coupled with the radome so that the rainwater is drained into the radome without flowing into the radome.
delete delete delete Coupling the reflector plate 120 using a reflector plate fixture 145 formed on the inner surface of the cap 140; And
Coupling the connector 150 and the knob 160 using the connector hole 141a and the knob hole 141b formed on the base plate 141 of the cap 140; And
A groove having a predetermined gap is formed between the outer side rim 142 and the inner side rim 143 of the cap 140 and the end of the radome 110 is inserted in the formed groove, Forming a drainage path for rainwater which is located above the water drop hole and allows rainwater that has been taken on the outer surface of the radome 110 to be discharged through the water drop hole 144 formed in the groove bottom;
Lt; / RTI >
The base plate may provide an integral structure capable of performing a function of a front plate to which the reflection plate is coupled,
Wherein the water drop hole is formed on the rainwater inflow path of the cap coupled with the radome so that the rainwater is drained without flowing into the radome.

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