KR101347208B1 - Antenna of mobile terminal for dmb - Google Patents

Abstract

A DMB antenna for a terminal of the present invention includes: a connector including a connection part; a bobbin which is formed by being protruding from one side of the connection part; a helical antenna inserted into the bobbin; an insulation tube inserted into the outer circumference of the helical antenna; a connection member touching the helical antenna; and a multi-step antenna whose one end is controllably assembled to the insulation part. The bonding of the antenna is done solidly and productivity is improved by shortening assembly time, by forming the connector and the bobbin integrally by insert injection molding, by the DMB antenna for a terminal by the present invention. Also, the number of components is reduced and manufacturing process is simplified and production costs can be reduced remarkably, by simplifying adhesive material or process for electrical contact formation of the helical antenna, by forming the helical antenna with an elastic SUS material. Also, electrical stability is improved and constant radio wave reception rate can be maintained for a long time, by making insulation coating on the helical antenna and comprising the insulation tube inserted into the outer circumference of the helical antenna. Also, assembly structure can be maintained solidly even through the multi-step antenna is repetitively inserted or withdrawn or external impact is applied, by assembling the multi-step antenna in the outer circumference of the insulation part integrated with the connector.

Description

ANTENNA OF MOBILE TERMINAL FOR DMB}

The present invention relates to a DMB antenna, and more particularly, a connector and a bobbin are firmly coupled, an insulation layer is formed on a helical antenna, and an insulation tube is provided at an outer circumference thereof, so that a rigid coupling structure is obtained even if the antenna is repeatedly used. The present invention relates to a DM antenna for a terminal that can be maintained and can stably maintain electrical insulation.

In general, portable terminals such as mobile phones, navigation systems, PMPs, smart phones, and tablet PCs on the market are equipped with antennas for receiving terrestrial digital multimedia broadcasting (DMB) radio waves.

With the rapid development of various technologies that make up the hardware, portable terminals such as smartphones are becoming smaller, slimmer and lighter for easier portability.The performance of so-called multifunction intelligent multi-function terminals is steadily improving while the appearance is getting smaller. Research on the performance and miniaturization of the antenna installed for the reception of terrestrial DMB radio waves in a portable terminal has been continuously conducted.

Accordingly, the antenna installed in the portable terminal for receiving the conventional terrestrial DMB radio waves is generally provided with a multi-stage load antenna exposed to the outside and a helical provided to reduce the physical length while maintaining the electrical length of the antenna at one end thereof. It consists of an electrical coupling structure of the antenna (Helical Antenna).

1 is a perspective view illustrating a portable terminal equipped with a DMb antenna for a terminal according to the prior art, and FIG. 2 is a plan view and an exploded perspective view showing an assembled state of the DMb antenna for a terminal according to the prior art. As shown in Figs. 1 and 2, the conventional terrestrial DMB antenna 1 has a connector 2 having a hinge portion 2a formed at one end thereof, and a bobbin 3 coupled to the other end of the connector 2. And a helical antenna 4 fitted to an outer circumference of the bobbin 3, an upper cap 5 connected to one end of the helical antenna 5, and between the upper cap 5 and the connector 2. It includes an outer shell 6 fitted to the outer periphery of, and a multi-stage antenna 7 that is not shown but assembled on one side of the outer shell 6.

In the coupling structure of the conventional terrestrial DMB antenna as described above, the protrusion 3a of the bobbin 3 is first assembled to the groove 2b of the connector 2 by an adhesive or the like. At this time, there is a problem that productivity is reduced due to the process of coupling the connecting portion of the connector 2 and the bobbin 3 in the production process. In addition, the coupling between the connector 2 and the bobbin 3 is weakened due to excessive external force generated by the terminal user repeatedly drawing and drawing the antenna for DMB radio wave reception and external shock caused by the user's carelessness. there was.

In addition, the helical antenna 5 is fitted to the outer circumference of the bobbin (3), and forms contact points in contact with the connector (2) and the upper cap (5) at both ends. At this time, it is fixed by soldering, welding, or mechanical fastening to form a contact, and thus there is a problem in that the production time becomes long.

In addition, the helical antenna 5 has a problem in that chemical change such as oxidation occurs due to external foreign matter or moisture penetration, or contacts are formed between adjacent pitches or the multi-stage antenna 7 to make radio wave reception unstable.

In addition, the multi-stage antenna (7) is assembled by a rolling (rolling) process is applied pressure along the groove formed in the shell 6, the coupling force of the shell 6 and the connector 2 is Because of the weakness, repeated rolling force is applied by the insertion and withdrawal of the multi-stage antenna 7, or due to inadvertent shock during use, the rolling part or the coupling part of the shell 6 and the connector 2 is shaken or spaced apart. There is a problem that occurs.

The present invention for solving the problems of the conventional DMB antenna, the connector and the bobbin is formed integrally and the insulation coating is made on the helical antenna with elasticity and to have an insulation tube on the outer periphery, repeated use of the antenna And it is possible to maintain a strong coupling structure from the external shock, and to maintain a stable electrical insulation is its purpose.

The present invention includes a connector including a hinge part connected to the receiving terminal part and a connection part formed on one side, and an insulating part formed between the hinge part and the connection part and protruding from one side of the connection part. A helical antenna inserted into the bobbin and forming a contact to be in contact with the connecting portion; and a connecting member fitted to the bobbin and in contact with the helical antenna; And a multi-stage antenna, which is in contact with the connection member and is assembled so that one end is intermittently intermittently formed, and is formed to form an insulation space with the helical antenna.

In addition, a connector including a hinge portion connected to the receiving terminal portion, and a connection portion formed on one side; and a bobbin including an insulation portion formed between the hinge portion and the connection portion and protruding from one side of the connection portion; A helical antenna fitted to the bobbin and forming a contact to be in contact with the connecting portion; an insulating tube fitted to an outer circumference of the helical antenna; and a connecting member fitted to the bobbin and in contact with the helical antenna; And a multistage antenna, which is in contact with the connection member and is assembled such that one end of the insulating part is intermittently intermittent.

In addition, the helical antenna is made of a SUS material, characterized in that made of a spring form having elasticity.

In addition, the helical antenna is an insulating coating is made on the remaining portion other than the portion in contact with the connecting member and the connecting portion.

In addition, the insulation coating is characterized in that the baking coating.

In addition, the bobbin is Insert Injection Molding together with the connector.

In addition, a first groove is formed in the outer circumference of the insulating portion, and the multi-stage antenna is assembled to the first groove.

In addition, a second groove portion is formed on the outer circumference of the connection member, and the multi-stage antenna is assembled to the second groove portion.

By the DMB antenna for the terminal according to the present invention, the connector and the bobbin are integrally formed by insert injection molding, so that the antenna is tightly coupled and the assembly time is shortened, thereby improving productivity.

In addition, by forming the helical antenna made of SUS material having elasticity, an additional adhesive material or process for forming electrical contact of the helical antenna is simplified, thereby reducing the number of parts, thereby simplifying the manufacturing process and reducing the production cost. .

In addition, the insulation coating is applied to the helical antenna and provided with an insulation tube fitted to the outer circumference of the helical antenna, thereby improving electrical stability and maintaining a constant radio wave reception rate.

In addition, the multi-stage antenna is assembled to the outer circumference of the insulation formed integrally with the connector, there is an effect that the assembly structure is firmly maintained even if the multi-stage antenna is repeatedly inserted or drawn out or an external impact is applied.

1 is a perspective view showing a portable terminal equipped with a DMMB antenna for a terminal according to the prior art.
2 is a plan view and an exploded perspective view showing an assembled state of a DM antenna for a terminal according to the prior art.
3 is an exploded view showing the overall configuration of a DMB antenna for a terminal according to an embodiment of the present invention.
4 is a partial cross-sectional view of a DMB antenna for a terminal according to an embodiment of the present invention.
5 is a plan view illustrating a partially assembled state of the DMB antenna for a terminal according to an embodiment of the present invention.
6 is an exploded view showing the overall configuration of a DMB antenna for a terminal according to another embodiment of the present invention.
7 is a partial cross-sectional view of a DM antenna for a terminal according to another embodiment of the present invention.

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

It will be understood by those of ordinary skill in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

In addition, the sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms defined specifically in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user, operator And the definitions of these terms should be based on the contents throughout this specification.

In the drawings illustrating the embodiments of the present invention, the same reference numerals are applied to the same parts.

3 is an exploded view showing the overall configuration of a DM antenna for a terminal according to an embodiment of the present invention, Figure 4 is a partial cross-sectional view of a DM antenna for a terminal according to an embodiment of the present invention.

3 to 4, the DM antenna 100 for a terminal according to an embodiment of the present invention is configured as follows. The connector 10 having the connection part 12 formed thereon is connected to the receiving terminal part 80 inside the terminal, and a bobbin 20 is formed at one side of the connection part 12, and the connection part 12 is formed on the bobbin 20. The helical antenna 30 is inserted into contact with the helical antenna, and the connecting member 50 is fitted into the bobbin 20 to be in contact with the helical antenna 30, and one end of the helical antenna 30 is assembled to be intermittently intermittent to the insulating portion 21. An antenna 60 is included.

First, the connector 10 is made of a conductive metal material, and is connected to the receiving terminal 80 of the portable terminal so that the DMB antenna 100 and the portable terminal are electrically connected to each other. The configuration includes a hinge portion 11 connected to the receiving terminal portion 80 of the portable terminal, and a connection portion 12 formed on one side and in contact with the helical antenna 30. The hinge portion 11 is hinged to the receiving terminal portion 80 of the portable terminal so that the DM antenna 100 is rotated at an angle of about 180 degrees. In addition, the connection part 12 has a first stepped groove part 13 formed so that the helical antenna 30 is inserted at a predetermined interval to form a contact, and the hinge part 11 has a predetermined distance toward the multi-stage antenna 60. It is formed to be spaced apart.

The bobbin 20 is formed of a bobbin LCP (Bobbin LCP), which is a dielectric material, is formed of insert injection molding, and is integrally formed with the connector 10. That is, a hole corresponding to the outer circumference of the bobbin 20 is formed at the center of the connecting portion 12 so that the inside thereof penetrates to reach one end of the hinge portion 11, and the hinge portion 11 When holes are formed at both sides along a circumference of a pipe connected between the connection parts 12, the connector 10 is provided in the insert injection mold manufactured in the form of the bobbin 20, and the bobbin LCP is injected. The bobbin 20 protrudes toward the multi-stage antenna 60 in the center of the connecting portion 12, and the insulating portion 21 is formed between the connecting portion 12 and the hinge portion 11. As such, the connector 10 and the bobbin 20, which are formed by insert injection molding and are integrally formed, have a structure that is connected by a firm coupling force.

In addition, the insulation portion 21 includes a first groove portion 22 assembled with the multi-stage antenna 60 and a stepped portion 23 in contact with an end of the multi-stage antenna 60.

5 is a plan view illustrating a partially assembled state of the DMB antenna for a terminal according to an embodiment of the present invention. Referring to FIG. 5, the helical antenna 30 is made of SUS material, is formed in a spring shape having elasticity, and is insulated at the remaining portions except for the portions in contact with the connecting member 50 and the connecting portion 12. The coating is made. Electrical connection with the multi-stage antenna 60 is made by forming an insulating coating part 31 having a coating layer formed on the surface of the helical antenna 30 except for both ends of the connecting part 12 and the connecting member 50. And electrical contact between adjacent pitches of the helical antenna 30 is prevented by foreign matter or moisture. At this time, as the insulating coating, it is preferable that the baking coating is performed to form an excellent anti-rusting ability and a solid and uniform coating film by applying heat after coating using a thermosetting resin, and drying it. Spray coating or the like may be carried out.

The connecting member 50 is made of brass, which is a conductive metal, and is gold plated on its surface to improve electrical conductivity. The configuration, the through-hole 51 is formed therein, the second groove 52 is formed so that the multi-stage antenna 60 is assembled along the outer circumference, the helical antenna 30 is inserted at a predetermined interval and seated It includes a second stepped groove 53 formed along the edge of the through hole 51 to be.

The helical antenna 30 and the connection member 50 are fitted to the outer circumference of the bobbin 20. First, the helical antenna 30 is inserted into the bobbin 20 so that one end of the helical antenna 30 is inserted into the first stepped groove 13, and then the connecting member 50 is inserted to the helical antenna 30. The other end is inserted into the second stepped groove 53 of the connecting member 50 so that both ends of the helical antenna 30 is electrically connected to the connecting portion 12 and the connecting member 50 to make an electrical connection. ). At this time, the end surface of the connection member 50 and the end surface of the bobbin 20 are assembled to form the same plane, the connection member 50 and the bobbin 20 is bonded (bonding).

In this case, when the connection member 50 is fitted, the helical antenna 30 having a spring shape has a predetermined interval compression in a longitudinal direction, and at this time, by using an elastic restoring force generated inside the helical antenna 30. It is possible to maintain an electrical connection with the connecting portion 12 and the connecting member 50 without using a separate fastening method.

The insulating space 70 is formed in the form of an empty space on the outer periphery of the helical antenna 30. In this case, the helical antenna 30 has an electrically stable coupling structure by being fixed at a predetermined interval from the multi-stage antenna 60 which is an electrical conductor due to the insulating space 70.

Looking at another embodiment of the present invention as follows.

6 is an exploded view showing the overall configuration of a DMb antenna for a terminal according to another embodiment of the present invention, Figure 7 is a partial cross-sectional view of a DMb antenna for a terminal according to another embodiment of the present invention. 6 and 7, the DMB antenna 100 of the present invention is assembled by adding an insulating tube 40 to the insulating space 70. The insulating tube 40 is made of a synthetic resin-based non-conductive material, is formed in the form of a tube is assembled in the form of being fitted to the outer circumference of the helical antenna (30). At this time, both ends of the insulating tube 40 is in close contact with the ends of the connecting portion 12 and the connecting member 50, the helical antenna 30 is located in an electrically stable sealed space, the helical antenna (30) gives a rigidity to the site to form a strong structure against external forces.

The multi-stage antenna 60 forms the physical length of the DM antenna 100, and its end is assembled to be in close contact with the step 23 of the insulating portion 21. Thereafter, the first rolling part 61 is applied by a rolling process in which pressure is applied along the positions of the first groove part 22 of the insulating part 21 and the second groove part 52 of the connection member 50. ) And the second rolling part 62 are formed, and the first and second rolling parts 61 and 62 and the first and second groove parts 22 and 52 are coupled to each other so as to be engaged with each other. 60) is fixed so as not to deviate. In particular, since the insulating portion 21 is formed by the hinge portion 11 and the insert injection molding is made integrally, the multi-stage antenna 60 has a rigid fastening structure without shaking with the first groove (22). At this time, since the two or four points are punched along the outer circumferential surfaces of the first and second rolling parts 61 and 62, the multi-stage antenna 60 is fixed to the connector 10 without rotating.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

Accordingly, the above-described embodiments are to be considered illustrative and not restrictive, and the scope of the present invention should be construed in accordance with the invention as set forth in the appended claims, And may further include various modifications, alternatives, and equivalents by those skilled in the art.

100: DMB antenna 10: connector
20: bobbin 11: hinge part
21 Insulation part 12 Connection part
22: first groove 13: first stepped groove
23: step 30: helical antenna
50 connection member 31 insulation coating
51: through hole 32: energizing part
52: second groove 40: insulated tube
53: second step groove 60: multi-stage antenna
70: insulating space 61: first rolling part
80: receiving terminal portion 62: second rolling portion

Claims (7)

In the antenna connected to the receiving terminal in the terminal,
A connector including a hinge part connected to the receiving terminal part and a connection part formed at one side;
A bobbin including an insulation portion formed between the hinge portion and the connection portion and protruding from one side of the connection portion;
A helical antenna inserted into the bobbin and forming a contact to be in contact with the connection part;
A connection member fitted to the bobbin and in contact with the helical antenna; And
And a multi-stage antenna, which is in contact with the connection member and is intermittently assembled with the insulating part, and is assembled to form an insulating space with the helical antenna.
In the antenna connected to the receiving terminal in the terminal,
A connector including a hinge part connected to the receiving terminal part and a connection part formed at one side;
A bobbin including an insulation portion formed between the hinge portion and the connection portion and protruding from one side of the connection portion;
A helical antenna inserted into the bobbin and forming a contact to be in contact with the connection part;
An insulating tube fitted to an outer circumference of the helical antenna;
A connection member fitted to the bobbin and in contact with the helical antenna; And
And a multi-stage antenna, which is in contact with the connection member and is assembled with one end intermittently in the insulating part.
The method according to claim 1 or 2,
The helical antenna is a terminal antenna, characterized in that made of SUS material and made of a spring shape having elasticity.
The method of claim 1 or 2
The connection portion is formed with a first stepped groove portion in which the helical antenna is inserted to form a contact point,
A second stepped groove is formed in the connection member so that the helical antenna is inserted and seated therein.
The helical antenna is an antenna for a terminal, characterized in that the insulating layer is formed on the remaining portions other than the portion that is inserted into the first stepped groove portion and the second stepped groove portion.
5. The method of claim 4,
The insulating layer is a terminal antenna, characterized in that formed by baking coating.
The method according to claim 1 or 2,
The bobbin is an insert injection molding (Insert Injection Molding) to be integrally formed with the connector.
The method according to claim 1 or 2,
And a first groove portion and a second groove portion are formed at outer circumferences of the insulation portion and the connection member, and the multi-stage antenna is rolled and assembled to the first groove portion and the second groove portion.

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