KR100473973B1 - Slim type antenna of a portable radio apparatus - Google Patents

Abstract

The present invention provides a slim antenna of a portable wireless device that is easy to carry and store by reducing the size of the antenna, in particular, the outer diameter of the helical antenna while maintaining the electrical characteristics thereof, and a metal rod having a feed point formed at the top thereof; A C ring which is formed by heat-treating the bellium copper and then heat-treated, and inserted into the metal rod; A spring whose cross section is rolled into a plate shape having a thickness of 0.2 mm and a width of 0.6 mm, the diameter of which is fixed to the top of the metal rod by turning the outer diameter of? A bobbin formed inside thereof in a hollow state and pressed in a vertical direction to the spring; A helical antenna having an outer diameter of φ7.5 and a length of 20ℓ, and having a built-in bobbin and a spring coupled to the top of the metal rod; A Ni-Ti wire coupled to the elevating inside the helical antenna through the bobbin; And the outer diameter is formed of ψ2.0 and includes a stopper coupled to the lower end of the Ni-Ti wire.

Description

Slim type antenna of a portable radio apparatus

The present invention relates to an antenna, and more particularly, to operate as a helical antenna during storage and to operate as a rod antenna when stretched, to reduce its size while maintaining its electrical characteristics so as to be easy to carry and store. A slim antenna of a portable radio device.

In general, a wireless device uses a conventional antenna to perform wireless communication. That is, the wireless devices apply the high frequency signal output from the modulator to the antenna and transmit it to the air, and also receive a predetermined radio wave transmitted through the air through the antenna.

In order to improve the electrical characteristics such as transmission and reception of the antenna, the impedance of the antenna and the impedance of the transceiver are matched with each other according to the frequency to be transmitted and received to increase the transmission and reception sensitivity, and to prevent unnecessary power radiation, so that the loss is small. You should.

In addition, such an antenna is structurally integrated as a whole, so that the antenna is normally operated as a helical antenna when stored and separated as a rod antenna when extended, and the antenna has a spring in the lower portion as a means for improving reception. Doing.

1 illustrates an antenna unit of a general wireless device, and the antenna unit 20 is coupled to a handle 21, an insulation unit 22, and a portable radio device main body 10 for use in extending or storing an antenna. It is composed of a helical antenna 23, which is operated when receiving the antenna and has a spring 25 built therein, and a Ni-Ti wire 24 which is combined with the helical antenna when the antenna is extended to serve as an antenna.

FIG. 2 shows a spring 25 embedded in the helical antenna 23 of FIG. 1, a metal rod 26 to which the spring 25 is coupled, and an inside of the spring 25 to support the spring. The rubber bobbin 27 is shown, and one end of the spring 25 is inserted into the metal rod 26 by about one turn, thereby fixing it by a cleavage operation. 3 shows a + cutting portion 28 and a C ring 29 inserted into a conventional metal rod 26.

In addition, the size of the helical antenna 23 generally has an outer diameter of ψ8.5 to ψ9.5 and a length of 20 to 23ℓ, and a stopper (not shown) coupled to the lower end of the Ni-Ti wire 24 may be used. Its outer diameter is formed by? 2.6. In addition, the characteristics of the antenna formed as described above are shown in FIGS. 4 and 5, where FIG. 4 is a SET FREE state. FIG. 5 is a representation of experimental data in a SET TALK state.

However, the antenna of the conventional portable wireless device configured as described above has a problem in that it is not convenient to carry and store because the size of the antenna exposed to the outside of the device is relatively large, and the electrical characteristics are not good compared to the size of the outer diameter. .

In addition, there is another problem that the electrical characteristics of the antenna is deteriorated if only the size of the antenna is unconditionally reduced for convenient portability and storage.

Accordingly, the present invention has been made to solve the above-mentioned problems, the purpose of which is to operate as a helical antenna at the time of storage and to operate as a rod antenna when stretched, the size of the antenna while maintaining the electrical characteristics are not degraded In order to reduce the outer diameter of the helical antenna, it is possible to provide a slim antenna of a portable wireless device that is easy to carry and store.

Features of the slim antenna of the portable wireless device according to the present invention for achieving the above object, a metal rod formed on the top feed point; A C ring which is formed by heat-treating the bellium copper and then heat-treated, and inserted into the metal rod; A spring whose cross section is rolled into a plate shape having a thickness of 0.2 mm and a width of 0.6 mm, the diameter of which is ψ0.4, the outer diameter of ψ5.5 and the inner diameter of φ5.1 turning to 6.5 turns and fixed to the top of the metal rod; A bobbin formed inside thereof in a hollow state and pressed in a vertical direction to the spring; A helical antenna having an outer diameter of φ7.5 and a length of 20ℓ, and having a built-in bobbin and a spring coupled to the top of the metal rod; A Ni-Ti wire coupled to the elevating inside the helical antenna through the bobbin; And the outer diameter is formed of ψ2.0 and includes a stopper coupled to the lower end of the Ni-Ti wire.

Hereinafter, a preferred embodiment of a slim antenna of a portable wireless device according to the present invention will be described in detail with reference to the accompanying drawings.

6 is a view showing a preferred embodiment of a slim antenna of a portable wireless device according to the present invention, the metal rod 100 has a feed point formed on the top as shown; C-ring (110) formed by heat-treating the bellium copper and then being heat-treated and inserted into the metal rod (100); Its cross section is formed by rolling into a plate shape having a thickness of 0.2 mm and a width of 0.6 mm, the diameter of which is ψ0.4, the outer diameter of ψ5.5 the inner diameter of ψ5.1 turns to 6.5 turns and fixed to the top of the metal rod 100. A spring 120; A bobbin 130 formed inside thereof in a hollow state and coupled to the spring 120 in a vertical direction; A helical antenna 140 having an outer diameter of φ7.5 and a length of 20ℓ, and having the bobbin 130 and the spring 120 incorporated therein and coupled to the top of the metal rod 100; Ni-Ti wire 150 coupled to the elevating inside the helical antenna 140 through the bobbin 130; And the outer diameter is formed of ψ2.0 and includes a stopper 160 coupled to the lower end of the Ni-Ti wire (150).

7 is a view showing the inner spring portion of the helical antenna of the present invention, one end of the spring 120 is inserted into the metal rod 100 and soldered to the bobbin 130 is inserted.

Figure 8 shows the structure of the C ring 110 of the present invention, as a whole consists of one circular body, four elastic pieces (110A) is formed integrally on the side thereof.

The assembling state and the action of the present invention configured as described above will be described in more detail with reference to FIG. 9.

In order to assemble the slim antenna of the present invention, first, the C ring 110 is inserted into the metal rod 100 (A), followed by a blemish (B), and the spring 120 is soldered to the metal rod 100. To be firmly fixed (C).

Here, the cross section of the spring 120 is rolled to form a plate of 0.2mm thickness 0.6mm thickness, the diameter is ψ0.4 and the outer diameter is ψ5.5 inner diameter ψ5.1 wound around 6.5 turns the size of smaller size Compared to this, the electrical characteristics of the antenna, such as transmission and reception efficiency, are improved, and the band width can be widened.

In addition, the C-ring 33 inserted into the metal rod 100 is formed by heat treatment after press-processing the beryl copper, the coupling structure of the conventional + cutting portion 28 and the C ring 29 (Fig. 3). Compared to the reference), the structure is very simple, which reduces the manufacturing cost and reduces the weight.

Therefore, the C ring 110 is inserted into the inner bottom of the spring 120 is formed in a circular shape having a plurality of elastic pieces (110A) on the side, when the antenna is pulled out Ni-Ti wire 150 of the antenna The elastic piece is supported by being firmly fixed while being received by the elastic piece (30A) and can also be elastically fixed by the elastic piece (110A) when inserting the antenna.

Next, as shown in (D), the bobbin 130 is inserted into the metal rod 100 assembled with the spring 120 from the top to the bottom, and then pressed. Conventionally, the bobbin is screwed into the spring, but according to the present invention, by easily pressing the bobbin 130 into the spring 120, workability is improved and the inner diameter of the spring 120 can be maximized.

And inserts the helical antenna 140 is coupled to the upper end of the metal rod 100 by inserting the combined bobbin 130 and the spring 120 as shown in (E).

Thereafter, the Ni-Ti wire 150 having the handle 170 and the insulation portion 180 formed therein is inserted into the helical antenna 140 injected as shown in (F), and the stopper 160 is punched and coupled to the lower end thereof.

Here, the outer diameter of the stopper 160 in the prior art in ψ2.6 can be reduced to ψ2.0 to reduce the space occupied by the main body when receiving the antenna, and also not shown in the figure of the metal rod 100 By moving the feed point to the upper end, the electrical characteristics are improved, and the length of the Ni-Ti wire 150 can be reduced in the range exhibiting the same characteristics.

In addition, the characteristics of the antenna of the present invention as shown in Figs. 10 and 11, where Fig. 10 is a SET FREE state Fig. 11 shows the experimental data of the SET TALK state. In addition, as shown in FIGS. 12 and 13, the effect of the present invention can be clearly understood through the experimental data of comparison of antenna characteristics according to the prior arts A1 and A2 and B1 and B2.

As described above, according to the slim antenna of the portable radio apparatus according to the present invention, the cross section of the spring is rolled into a plate shape having a thickness of 0.2 mm and a width of 0.6 mm, and the diameter is ψ 0.4 and the outer diameter is ψ 5.5. Compared to the smaller size, the inner diameter is wound around 6.5 turns at ψ5.1, which improves the electrical characteristics of the antenna such as transmission and reception efficiency and widens the bandwidth. In addition, the C-ring of the present invention inserted into the metal rod is formed by heat treatment after press-processing the beryl copper, the structure is very simple compared to the conventional structure of the + cutting portion and the C ring (see Fig. 3). The manufacturing cost is reduced and the weight is lighter, and by simply pressing the bobbin inside the spring, the workability is improved and the inner diameter of the spring is maximized. In addition, the outer diameter of the stopper is conventionally reduced from ψ2.6 to ψ2.0, which reduces the space occupied by the main body when storing the antenna, and also moves the feed point of the metal rod to the upper end, although not shown in the drawing. As a result, the electrical characteristics are improved, and there are various effects of reducing the length of the Ni-Ti wire in the range of exhibiting the same characteristics.

1 is a view showing an antenna of a conventional wireless device,

2 is a view showing a spring portion of a conventional antenna,

3 is a view illustrating a + cutting portion and a C ring portion of a conventional antenna;

4 and 5 are the antenna characteristic experiment data according to the prior art,

6 is a view showing a preferred embodiment of a slim antenna of a portable wireless device according to the present invention;

7 is a view showing a spring portion of the present invention,

8 is a view showing a C ring portion of the present invention,

9 is an antenna assembly process diagram of the present invention,

10 and 11 are antenna characteristic experiment data according to the present invention,

12 and 13 are diagrams comparing antenna characteristics according to the present invention and the prior art.

<Explanation of symbols for main parts of drawing>

100: metal rod 110: C ring

120: spring 130: bobbin

140: helical antenna 150: Ni-Ti wire

160: stopper

Claims (1)

A metal rod on which a feed point is formed; A C ring which is formed by heat-treating the bellium copper and then heat-treated, and inserted into the metal rod; A spring whose cross section is rolled into a plate shape having a thickness of 0.2 mm and a width of 0.6 mm, the diameter of which is fixed to the top of the metal rod by turning the outer diameter of? A bobbin formed inside thereof in a hollow state and pressed in a vertical direction to the spring; A helical antenna having an outer diameter of φ7.5 and a length of 20ℓ, and having a built-in bobbin and a spring coupled to the top of the metal rod; A Ni-Ti wire coupled to the elevating inside the helical antenna through the bobbin; And an outer diameter of ψ2.0 and a stopper coupled to the lower end of the Ni-Ti wire.