KR20080033593A - Built-in antenna for wireless terminal - Google Patents

Abstract

A built-in antenna for a wireless terminal is provided to improve productivity by manufacturing a base frame and coupling the base frame with a radiator at the same time. A built-in antenna(200) for a wireless terminal includes a conductive radiator(204) and an insulating base frame(202). The radiator is electrically connected to a feeding unit to radiate electromagnetic waves. The base frame is coupled with the radiator. The base frame is made of an elastic member to transmit elastic force to a feeding pin(208) in case of electrical connection between the radiator and the feeding unit. The base frame is integrally formed with the radiator by insert-molding. The base frame is made of rubber. The base frame and the radiator are coupled with each other by injecting the liquid elastic member into a mold after placing the radiator inside the mold.

Description

Built-in antenna for wireless terminal {Built-in antenna for wireless terminal}

1 is a perspective view illustrating a connection of a conventional built-in antenna and a PCB.

2 is an exploded perspective view showing a conventional built-in antenna.

3 is a cross-sectional view taken along line AA ′ of FIG. 1.

4 is a perspective view showing an embodiment of a built-in antenna for a wireless terminal according to the present invention.

5 is an exploded perspective view of the embodiment shown in FIG. 4.

FIG. 6 is a cross-sectional view taken along line BB ′ of FIG. 4.

<Description of Symbols for Major Parts of Drawings>

202: base frame 204: radiator

206: slit 208: feed pin

The present invention relates to a built-in antenna (antenna) for a wireless terminal, and more particularly, even if the built-in antenna is built in a thin, small wireless terminal, while improving the contact force of the feed pin and the resilience of the feed pin at the same time It is to increase the production efficiency of the built-in antenna by unifying the manufacturing of the base frame and the radiator and the coupling step thereof.

Recently, as portable wireless terminals using various bands, such as CDMA, PCS, DCS, GSM, etc., separately or in common, have become more and more popular, terminals having various functions and designs have emerged. In addition, as the terminal becomes smaller and lighter and smaller, the diversity of its functions becomes more and more important. As the wireless terminal becomes smaller and thinner and smaller, the built-in antenna built into the wireless terminal is also increased. It is required to be miniaturized and light and short.

Hereinafter, with reference to the drawings will be described in detail the problems of the prior art that obstructs the miniaturization of the built-in antenna.

1 is a perspective view illustrating a connection between a conventional internal antenna and a PCB, FIG. 2 is an exploded perspective view illustrating a conventional internal antenna, and FIG. 3 is a cross-sectional view of AA ′ of FIG. 1.

Referring to FIGS. 1 to 3, the conventional internal antenna 110 is described. The conventional internal antenna 110 includes a base frame 112 and a radiator 120. The base frame 112 is a member made of plastic material to which the radiator 120 is fixed, and includes a top surface 117 and a side surface 118, and a power supply formed on the radiator 120 is provided on the top surface 117. Two through holes 116 through which the pin 124 penetrates are formed, and a protrusion 114 inserted into the insertion hole 122 formed in the radiator is formed at a side of the through hole 116.

 In addition, the radiator is a member for generating an electromagnetic wave by receiving a current from a power supply unit 102 formed on a printed circuit board (PCB) 100. The radiator is formed of a predetermined metallic plate and inserted into the insertion hole 122 formed in the radiator. After the protrusion 114 is inserted, the upper surface 117 and the side surface 118 of the base frame 112 is contacted by a heat fusion method, one side of the through the through hole 116 through the rapid Feed pins 124 in contact with the entire body 102 are formed.

When the embedded antenna 110 is attached to the PCB, the feed pin 124 protruding out of the base frame 112 is pressed by the PCB and bent into the through hole 116 (126). Thus, the contact force and the restoring force is generated in the feed pin 124. Here, the contact force of the feed pin 124 means a force acting between the feed pin 124 and the PCB, the restoring force of the feed pin 124 is when the feed pin 124 is separated from the PCB, It means the power to return to its original state.

As described above, in recent years, since the wireless terminal gradually decreases and becomes thinner, the space occupied by the built-in antenna in the wireless terminal becomes smaller, and thus the length of the feed pin 124 becomes shorter.

However, the shorter the length of the feed pin 124, the less the contact force of the feed pin and the restoring force of the feed pin, there is a problem that the built-in antenna does not work well.

In addition, according to the prior art, the base frame 112 and the radiator 120 are in contact with each other by thermal fusion, in this case, after separately manufacturing the base frame 112 and the radiator 120, Again, since the base frame 112 and the radiator 120 should be coupled to each other by applying a predetermined heat to the base frame 112, the manufacturing process of the built-in antenna is performed in the manufacturing process of the base frame 112 and the radiator 120. And, there is a problem in that the production efficiency of the wireless terminal is lowered by dualizing the step of combining them.

The present invention is to solve the above problems, even if the built-in antenna is built in a thin, small wireless terminal, while improving the contact force of the feed pin and the resilience of the feed pin and at the same time manufacturing the base frame and radiator It is a technical problem to provide a built-in antenna for a wireless terminal to increase the production efficiency by unifying the combination step and these.

In order to solve the above technical problem, the present invention is electrically connected to the power supply and the conductive radiator for emitting electromagnetic waves; And an insulating base frame coupled to the radiator, wherein the base frame is formed of an elastic member to transmit an elastic force to the feed pin during electrical connection of the radiator and the feeder, and to insert molding. Thereby provides a built-in antenna for a wireless terminal that is integrally coupled with the radiator.

The base frame is formed of an elastic member, and the elastic force of the elastic member is By being transmitted to the feed pin, even if the built-in antenna is embedded in a thin, small wireless terminal, the contact force of the feed pin and the resilience of the feed pin can be improved. In addition, the production efficiency of the built-in antenna can be improved by integrally manufacturing the base frame and the radiator.

Preferably, the base frame may be formed of rubber.

Preferably, after placing the radiator inside the mold, the liquefied elastic member may be injected into the mold to couple the base frame and the radiator.

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

Figure 4 is a perspective view showing an embodiment of a built-in antenna for a wireless terminal according to the present invention, Figure 5 is an exploded perspective view of the embodiment shown in Figure 4, Figure 6 is a cross-sectional view of BB 'of FIG.

This embodiment 200 includes a base frame 202 and a radiator 204 having a predetermined shape. The base frame 202 is formed of an elastic member, and consists of a horizontal surface 210 and a vertical surface 212, two slits into which the feed pins 208 formed on the radiator 204 are inserted. 206 is formed.

The radiator 204 is formed of a metallic plate, integrally coupled to the horizontal plane 210 and the vertical plane 212 of the base frame 202 by insert molding, and passes through the slit 206 to feed the PCB. And a feed pin 208 in contact with the.

In this case, the integrated antenna is not manufactured by separately manufacturing the base frame 202 and the radiator 204 and combining the antennas with each other. The fabrication of the base frame and the combination of the base frame and the radiator may include inserts. It is meant to be done simultaneously by molding.

To describe one of the embodiments in which the base frame 202 and the radiator 204 are integrally coupled, first, to produce a radiator 204 having a predetermined shape, and then to the manufactured radiator 204 Is placed inside the molding mold having the shape of the base frame 202, and finally, the liquefied elastic member is injected into the molding mold, and stored at room temperature for a predetermined time, and then the base frame (from the molding mold) 202).

In such a case, the built-in antenna is not dually manufactured by manufacturing the base frame 202 and the radiator 204 and combining them as in the related art, but manufacturing the base frame 202 and the base frame. Since the combination of the 202 and the radiator 204 is performed at the same time, the production efficiency of the built-in antenna may be higher than in the related art.

As described above, the base frame 202 is formed of an elastic member, and transmits an elastic force to the feed pin 208. Preferably rubber may be used as the elastic member.

As such, when the base frame 202 is formed of an elastic member, and the elastic force is transmitted to the feed pin 208, the length of the feed pin 208 is due to the narrow space occupied by the built-in antenna in the wireless terminal. Even if it becomes short, since the contact force and the restoring force of the feed pin 208 are improved, a built-in antenna can be manufactured favorably.

Hereinafter, this will be described in more detail with reference to FIG. 6.

When the built-in antenna is manufactured, a part of the feed pin 208 is exposed to the outside of the base frame 202 through the slit 206 of the base frame 202, in which case, by pressing the built-in antenna to the horizontal plane of the base frame When the bottom surface 211 of the 210 is in contact with the PCB, the lower surface 211 is raised in a state in which the feed pin 208 is in contact with the bottom surface 211 of the horizontal surface 210 (214) (213) ).

In this case, the contact force and the restoring force of the feed pin applied to the feed pin are the value of the contact force and the restoring force generated by the feed pin 208 plus the contact force and the restoring force generated by the elastic force of the base frame 202. Therefore, the contact force and the restoring force as a whole may be improved as compared to the conventional built-in antenna in which the contact force and the restoring force are generated only by the feed pin.

According to the present invention, even if the built-in antenna is embedded in a wireless terminal having a small thickness and a small size, the contact force of the feed pin and the resilience of the feed pin are improved, so that a good built-in antenna can be manufactured, and the base frame is manufactured and the base frame. And since the coupling of the radiator is performed at the same time the production efficiency of the built-in antenna can be improved compared to the conventional.

Claims (3)

A conductive radiator electrically connected to the feeding part to radiate electromagnetic waves; And Including an insulating base frame (couple) coupled to the radiator, The base frame is formed of an elastic member, when the electrical connection between the radiator and the feeder, and transmits an elastic force to the feed pin, the integrated antenna for a wireless terminal is integrally coupled to the radiator by insert molding. The method of claim 1, The base frame is a built-in antenna for a wireless terminal is formed of rubber. The method of claim 1, And positioning the radiator inside a mold, and injecting the liquefied elastic member into the mold to couple the base frame and the radiator.

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