KR101609542B1 - Metal-Body Antenna to Operating Wideband in a Multi-Band - Google Patents

Abstract

The present invention relates to a metal body antenna using a housing unit and a battery cover as an antenna. The metal body antenna includes: a radiation device receiving a signal from a power supply port; a ground unit generating an induced current by coupling connection with the radiation unit; and a frame bezel unit having an open end portion formed by being separated by the ground unit, a dielectrics and a gap. By connecting the frame bezel unit having the open end portion receiving the induced current of the ground unit, a dual antenna having an electric length of a half wavelength is formed, thereby operating as a wideband antenna in a multi-band. The present invention effectively uses the bezel unit, which is a frame unit, and has a wideband multi-antenna structure, thereby satisfying PENTA BAND (GSM850, EGSM, DCS, PCS, W2100), which is mainly used in a mobile phone.

Description

Technical Field [0001] The present invention relates to a metal body antenna that operates in a wide band in multiple bands,

The present invention relates to a metal body antenna for operating in a wide band in multiple bands, and more particularly, to a metal body antenna for operating a wide band in multiple bands. More particularly, the present invention relates to a metal body antenna, And a metal battery cover connected by the ground and the contact pin. The antenna includes a dual metal body antenna.

In recent years, along with the development of very fast communication technology, communication devices have been made smaller, lighter, and have higher performance.

In particular, a large number of smartphones are expected to be used in the second generation and third generation communication systems such as GSM (Global System for Mobile communication), CDMA (Code Division Multiple Access) and WCDMA (Wideband CDMA) , And various technologies such as Bluetooth, Global Positioning System (GPS), and WIFI are integrated.

However, it is difficult to mount a plurality of antennas in a limited size of a terminal, so that a wideband (broadband) antenna capable of implementing multiple antennas with a single antenna can be used, ) Antenna technology has been developed.

Although the wideband antenna technology has been proposed to support various communication bands through the design of a wide band antenna, it is impossible to implement multi-bands based on a wide bandwidth and to improve the efficiency of all bands at the same time. Moreover, since the antenna design requires a lot of space, there is a lack of space for mounting various components inside the terminal.

As a method for solving such a problem, a technique has been developed in which the housing part operates as an antenna after the housing part constituting the outer shape of the terminal is made of a metal material.

By utilizing the technique of operating the housing part as an antenna as described above, a space inside the terminal can be additionally secured, and more various parts can be mounted inside the terminal by utilizing the space, and a thin thin terminal can be designed.

More specifically, an antenna using a housing part as an antenna, that is, an antenna using a conductive bezel and a metal battery cover has a disadvantage of having a narrow bandwidth. To support various communication bands, Have been applied.

In addition, due to the application of the above-mentioned tunable antenna technologies, various problems such as an increase in manufacturing cost, an increase in design period due to additional parts, and an increase in power consumption are accompanied.

Therefore, the case of the housing part constituting the outer shape of the terminal is designed to operate as an antenna by being made of a metal material, thereby maximizing the space inside the terminal and having a smaller size, Design technology is in desperate need.

Reference Nos. &Lt; 20 > to Ninth Reference Numbers < 29 >

In order to overcome the disadvantages of the related art as described above, it is an object of the present invention to provide a metal body that operates with a wide band in multiple bands with a small radiation loss using a frame bezel.

According to another embodiment of the present invention, a radiating element, which receives a signal from a feed port, is not connected to a frame bezel portion and a coupling-coupling structure as a radiating element connected to a ground, The present invention also provides a metal body antenna that operates in a wide band in a multi-band coupling.

According to another embodiment of the present invention, when an electromagnetic signal is applied to the feed port, the radiating element couples to the ground to induce an induced current in the ground, and the radiating element connected to the ground by the current induced in the ground And a metal body antenna that exhibits broadband characteristics in multiple bands where magnetic energy is concentrated around a connection point connecting the side bezel portion and the ground. .

According to another embodiment of the present invention, there is provided a metal body antenna in which an L-C element is inserted into a feed port and a full impedance matching is performed in an operating frequency band with an antenna portion to exhibit broadband characteristics in multiple bands.

According to another embodiment of the present invention, a metal body antenna including a frame bezel is mounted in a space between a housing part and a metal battery cover, and a ground of the housing part is connected to the metal battery cover by a contact pin. The present invention has been made in view of the above problems.

In order to achieve the above object, a metal body antenna according to an embodiment of the present invention includes a frame bezel as a radiating element to which a radiating element receiving a signal from a feed port is connected to a ground, And the radiating element supplied with the signal is coupled to the ground so as to operate in a wide band in multiple bands.

According to another aspect of the present invention, there is provided a metal body antenna comprising: a terminal housing part; A metal frame bezel formed at an outer periphery of the terminal housing part; A gap formed by cutting a part of the frame bezel; A ground which is electrically connected to the frame bezel portion separated by the gap and is spaced apart from a part of the frame bezel portion including the gap; A first radiating element formed on the ground and electromagnetically coupled to the ground; And operates in a wide band.

According to another aspect of the present invention, there is provided a metal body antenna comprising: a terminal housing part; A metal frame bezel formed at an outer periphery of the terminal housing part; A gap formed by cutting a part of the frame bezel; A ground which is electrically connected to the frame bezel portion separated by the gap and is spaced apart from a part of the frame bezel portion including the gap; A first radiating element formed on the ground and electromagnetically coupled to the ground; A second radiating element formed on the ground and electromagnetically coupled to the ground; And operates in a wide band in multiple bands.

According to another aspect of the present invention, there is provided a metal body antenna comprising: a terminal housing part; A metal frame bezel formed outside the terminal housing part; A gap formed by cutting a part of the frame bezel; A ground formed at a predetermined distance from a part of the frame bezel separated by the gap; The ground is connected to a part of the other side of the frame bezel separated by the gap and the ground is connected to a part of the other side of the frame bezel separated by the gap, A first radiating element coupled to the first radiating element; And a second radiating element coupled electromagnetically coupled to the ground, wherein a signal coupled to the ground by electromagnetic coupling coupled from the first radiating element is transmitted to the ground through the gap, A signal transmitted to the ground is transmitted to another frame bezel separated by the gap connected to the ground and is radiated, Band and wideband.

As described above, since the metal body antenna according to the present invention is a wide-band multi-antenna structure having a low radiation loss using a frame bezel, the PENTA BAND (GSM850, EGSM, DCS, PCS, W2100) There is an effect showing broadband characteristics.

The metal body antenna according to the present invention does not have a structure in which a radiating element supplied with a signal from the feed port is coupled to a frame bezel portion as a radiating element connected to the ground, To exhibit broadband characteristics in multiple bands.

In the metal body antenna according to the present invention, when an electromagnetic signal is applied to the feed port, the radiating element couples with the ground to generate an induced current in the ground, and the radiating element connected to the ground by the current induced in the ground There is an effect that the electric energy is concentrated in the open end portion of the upper bezel portion due to the surface current flowing through the frame bezel portion as the center bezel portion and the broad band characteristic is exhibited in the multi band where the magnetic energy is concentrated around the connection point connecting the side bezel portion and the ground .

In the metal body antenna according to the present invention, the L-C element is inserted into the feed port, and the impedance matching with the antenna part is performed in the operating frequency band, thereby exhibiting the broadband characteristic in the multiple bands.

Also, the metal body antenna according to the present invention includes a metal body antenna including a frame bezel in a space between the housing part and the metal battery cover, and the ground of the housing part and the metal battery cover are connected by the contact pins, .

1 is a plan view showing a typical structure of a metal body antenna formed in a housing part of a terminal according to an embodiment of the present invention.
FIG. 2A is a plan view showing a structure in which the radiating element connected to the feed port in FIG. 1 is linear and the metal body antenna is enlarged in detail.
FIG. 2B is a perspective view showing a structure in which the metal body antenna is enlarged in detail when the radiating element connected to the feed port in FIG. 1 is linear.
FIG. 2C is a diagram showing return loss of the metal body antenna when the radiating element connected to the feed port is linear in FIG.
FIG. 2D is a diagram showing the current distribution of the metal body antenna, the density of the electric energy, and the density of the magnetic energy when the radiating element connected to the feed port is linear in FIG.
FIG. 3A is a plan view showing a structure in which the radiating element connected to the feed port in FIG. 1 is linear, and the metal body antenna having the radiating element extended as the bezel portion of the second antenna portion is enlarged in detail.
FIG. 3B is a perspective view showing a structure in which the radiating element connected to the feed port in FIG. 1 is linear, and the metal body antenna having the radiating element extended as the bezel portion of the second antenna portion is enlarged in detail.
FIG. 3C is a diagram illustrating return loss of the metal body antenna in which the radiating element connected to the feed port is linear, which is a bezel portion of the second antenna portion. FIG.
FIG. 3D is a diagram showing the current distribution, the density of the electric energy, and the density of the magnetic energy of the metal body antenna in which the radiating element which is the bezel portion of the second antenna portion is extended when the radiating element connected to the feed port in FIG. to be.
4A is a plan view illustrating a structure of a metal body antenna formed in a housing part of a terminal according to an embodiment of the present invention.
FIG. 4B is a plan view showing a structure in which the radiating element connected to the feed port in FIG. 4A is linear and the metal body antenna is enlarged in detail.
FIG. 4C is a perspective view showing a structure in which the metal body antenna is enlarged in detail when the radiating element connected to the feed port in FIG. 4A is linear. FIG.
FIG. 4D is a diagram showing return loss of the metal body antenna when the radiating element connected to the feed port in FIG. 4A is linear. FIG.
FIG. 4E is a diagram showing a current distribution, a density of electric energy, and a density of magnetic energy of the metal body antenna when the radiating element connected to the feed port is linear in FIG. 4A. FIG.
FIG. 5A is a plan view showing the overall structure of a metal body antenna including a housing portion of a terminal in which a metal body antenna is formed as shown in FIG. 4A and a metal battery cover, and a metal battery cover according to another embodiment of the present invention.
FIG. 5B illustrates another embodiment of the present invention in which the radiating element connected to the feed port mounted on the housing part of the terminal in which the metal body antenna of FIG. 5A is formed is a vertical meander line, Fig.
FIG. 6A is a plan view showing a structure in which a radiating element connected to a feed port in FIG. 5A is a vertical meander line, and a metal body antenna including a metal battery cover is enlarged in detail.
FIG. 6B is a perspective view showing a structure in which the radiating element connected to the feed port in FIG. 5A is a vertical meander line and the metal body antenna including the metal battery cover is enlarged in detail.
FIG. 6C is a view showing the return loss of the metal body antenna including the metal battery cover, in which the radiating element connected to the feed port in FIG. 5A is a vertical meander line.
FIG. 6D is a diagram showing the current distribution, the density of the electric energy, and the density of the magnetic energy of the metal body antenna including the metal battery cover, in which the radiating element connected to the feed port is a vertical meander line.

The present invention will now be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same components, and repeated descriptions and known functions and configurations that may obscure the gist of the present invention will not be described in detail. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

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

1 is a plan view showing the overall structure of a metal body antenna formed in a housing part of a terminal according to an embodiment of the present invention.

Referring to FIG. 1, the metal body antenna of the present invention is mounted on a housing part 10 of a terminal, and the housing part 10 occupies most of the area of the housing part 10 with a rectangular metal material And a frame bezel portion 12 made of a metal and surrounding the rim of the outermost upper side of the rectangular ground.

The ground 11 of the housing part 10 may provide a ground voltage within the terminal and form a substrate on which circuit elements and components necessary for the terminal operation are mounted.

More specifically, referring to FIG. 1, a metal body antenna formed in a housing part 10 according to the present invention includes ground (110a, 110b) of an upper side ground region indicated by a dotted line, The first and second radiating elements 130a and 130b and the side bezel part 150 or the rim of the outermost upper side of the rectangular ground of the housing part, The first and second side bezel portions 150a and 150b formed on the side frame bezel portion 150 in the upper side frame bezel portion 12 of the upper side frame bezel portion 12, First and second bezel portions 160a and 160b formed on the first and second bezel portions 160a and 160b and a gap 180 and a dielectric 190 formed on the first and second bezel portions 160a and 160b.

The metal body antenna formed in the housing unit 10 according to the present invention includes a first antenna unit 100a operating in a low frequency band and a second antenna unit 100b operating in a high frequency band.

That is, according to the present invention, the first and second antenna units 100a and 100b are antennas having a half-wavelength electrical length, and the metal body antenna according to the present invention includes a first antenna unit 100a, The first antenna unit 100a operates in a low frequency band and the second antenna unit 100b operates in a high frequency band to operate in a wide band in multiple bands . The first antenna unit 100a operates at a frequency of 880MHz to 960MHz which is a frequency of an EGSM at a low frequency band and the second antenna unit 100b operates at a frequency of 1710MHz to 2170MHz which is a frequency of DCS, PCS and W2100 which are high frequency bands.

The first antenna unit 100a includes a ground 110a and a first feed port 120a, a first radiating element 130a, the first side bezel 150a, And the first bezel 160a and the gap 180 and the dielectric 190 to open the end 165a of the first bezel 160a by the gap 180. [

The second antenna unit 100b includes a ground 110b and a second feed port 120b, a second radiating element 130b, and the second side bezel 150b The second bezel 160b and the gap 180 and the dielectric 190 to open the end 165b of the first bezel 160b by the gap 180. [

The two first and second feed ports 120a and 120b are formed so as not to be connected to the grounds 110a and 110b of the upper side ground region indicated by the dotted line adjacent to the dielectric 190, To the first and second antenna units 100a and 100b.

In addition, the first and second feed ports 120a and 120b may be connected to the first and second antenna units 100a and 100b so that the impedance matching is achieved by inserting the LC elements into the first and second feed ports 120a and 120b so as to be perfectly matched with the first and second antenna units 100a and 100b. do.

The first radiating element 130a is connected to the first feed port 120a and receives an electromagnetic signal. The first radiating element 130a has a structure in which the terminal end 135a is opened with the ground 110a, Respectively.

The second radiating element 130b is connected to the second feed port 120b and receives an electromagnetic signal. The second radiating element 130b has a structure in which the terminal end 135b is opened with a predetermined height and length, Respectively.

The first and second radiating elements 130a and 130b may be formed on the ground 11 or on the dielectric 190 to utilize the space of the housing part 10.

The first and second radiating elements 130a and 130b receiving the electromagnetic signals from the first and second feed ports 120a and 120b are coupled to the grounds 110a and 110b by coupling coupling, Signal.

The first and second side bezel portions 150a and 150b are formed on the left and right sides of the frame bezel portion 12 of the outermost rim portion of the housing portion and are coupled to the radiating elements 130a and 130b by electromagnetic coupling The first and second bezel units 160a and 160b of the first and second antenna units 100a and 100b are connected to the grounds 110a and 110b and the connection points P1 and P2, .

The upper bezel portion 160 is connected to the first and second side bezel portions 150a and 150b and is connected to the upper side frame bezel portion 12 of the uppermost outermost frame portion of the housing portion 10. [ The upper bezel unit 160 includes a first bezel unit 160a on the upper left side of the first antenna unit 100a and a second bezel unit 160b on the upper right side of the second antenna unit 100b.

In the case of the first antenna unit 100a, the first bezel 160a extends from the left end of the first bezel 150a of the frame bezel 12, And the second bezel 160b is horizontally formed on the upper edge of the second side bezel 150b on the right side in the case of the second antenna unit 100b, And the upper bezel portion 160 of the frame bezel portion 12 extending horizontally.

The gap 180 is formed at a predetermined position of the upper bezel 160 so as to separate the first and second bezels 160a and 160b from the first bezel 160a and the second bezel 160a, And 160b are formed with open end portions 165a and 165b.

A separate upper side frame bezel portion 12 including first and second side bezel portions 150a and 150b connected to the first and second bezel portions 160a and 160b by the gap 180, And a dielectric 190 formed with a predetermined width between the grounds 11.

The first and second side bezels 150a and 150b and the upper and lower bezels 160 and 160 that are the bezel 150 of the side portion are separated by the gap 180 and the dielectric 190, The upper frame bezel 12 including the bezel portions 160a and 160b and the ground 11 are separated from each other.

FIG. 2A is a plan view showing a structure in which the metal body antenna is enlarged in detail when the radiating element connected to the feed port is linear in FIG. 1, and FIG. 2B is a plan view showing the structure in which the radiating element connected to the feed port is linear Is a perspective view showing a structure in which a metal body antenna is enlarged in detail.

An embodiment of the metal body antenna of the present invention will be described in detail with reference to Figs. 1, 2A and 2B.

The metal body antenna formed in the housing part 20 according to the present invention includes grounds 210a and 210b of the upper side ground area indicated by a dotted line and first and second feed ports 220a and 220b of two ports, First and second side bezels 250a and 250b as a side frame bezel 250 of the housing part 20 and two first and second radiating elements 230a and 230b, First and second bezels 260a and 260b as the upper bezel 260 of the unit 20 and first and second bezels 260a and 260b formed on the first and second bezels 260a and 260b, , 280b, and a dielectric 290. [

According to the present invention, as shown in FIG. 2A, the first and second radiating elements 230a and 230b are connected to a feed port in FIG. 1, and a metal body antenna having a linear structure as a radiating element. Therefore, in the structure of FIGS. 2A and 2B, the first and second radiating elements 230a and 230b are represented by the first and second linear radiating elements 230a and 230b in parallel.

The metal body antenna formed in the housing unit 20 according to the embodiment of the present invention is composed of a first antenna unit 200a operating in a low frequency band and a second antenna unit 200b operating in a high frequency band.

That is, according to the present invention, the first and second antenna units 200a and 200b are antennas having an electrical length of a half wavelength, and the metal body antenna according to the present invention includes a first antenna unit 200a and a second antenna The first antenna unit 200a operates in a low frequency band and the second antenna unit 200b operates in a high frequency band to operate in a wide band in multiple bands. The first antenna unit 200a operates at a frequency of 880MHz to 960MHz which is a frequency of an EGSM at a low frequency band and the second antenna unit 200b operates at a frequency of 1710MHz to 2170MHz which is a frequency of DCS, PCS, and W2100 which are high frequency bands.

The metal body antenna according to the present invention shown in FIGS. 2A and 2B is characterized in that the first and second radiating elements 230a and 230b have a linear structure and the first bezel 260a and the second bezel 260b Are positioned adjacent to each other with the gap 280 therebetween.

The first antenna unit 200a operates in a low frequency band and includes a first linear radiating element 230a and a ground 210a of the upper side ground region indicated by the dotted line. A first side bezel 250a and a first bezel 260a and a gap 280 and a dielectric 290. The first bezel 250a and the first side bezel 250a have a first bezel 250a and a first bezel 260a.

The first feed port 220a connected to the first linear radiating element 230a is located near the end 265a of the first bezel 260a and is connected to the dielectric body 290 by a dotted line And is not connected to the ground 210a at a predetermined portion of the ground 21 in the displayed upper side ground area to feed a signal of an electromagnetic low frequency band from the RF module of the terminal to the first antenna unit 200a.

In some cases, an L-C element is inserted into the first feed port 220a so as to be perfectly matched with the first antenna portion 200a in a low frequency band, thereby performing impedance matching.

The first linear radiating element 230a is connected to the first feed port 220a and receives an electromagnetic signal. The first linear radiating element 230a is connected to the linear ground terminal 210a having a predetermined height, 235b. Therefore, when the first linear radiating element 230a receiving the electromagnetic signal from the first feed port 220a transmits an electromagnetic signal to the ground 210a by coupling coupling, An electric current is generated. The end portion 235a of the opened first linear radiating element 230a is located at a point near the first connection point P1.

The first radiating element 230a may be formed on the ground 210a or on the dielectric 290 to utilize the space of the housing 20.

The first connection point P1 is connected to the ground 210a of the upper side ground region indicated by the dotted line and the first side bezel portion 250a which is the left side frame bezel portion 250 of the upper side frame bezel portion 22 The first connection point P1 connects the ground 210a and the first side bezel 250a.

Therefore, an electromagnetic signal is transmitted from the ground 210a to the first side bezel 250a of the first antenna unit 200a by the first connection point P1, and the first connection point P1 And is a starting point of the first side bezel 250a.

The first side bezel 250a of the first antenna unit 200a includes a first bezel portion 250a of the upper side frame bezel portion 22 surrounding the outermost upper side edge portion of the rectangular ground 21 260a to the first connection point P1.

The first bezel 260a is connected to an end edge of the first side bezel 250a and is perpendicular to the first side bezel 250a, The first bezel 260 is horizontally formed as an upper portion, and the first bezel 260a forms an open end 265a.

The gap 280 maintains a gap at a predetermined position of the upper bezel 260 to form an open end 265a of the first bezel 260a.

And a dielectric 290 formed between the upper side frame bezel 22 separated by the gap 280 and the rectangular ground 21 to have a predetermined width.

The first side bezel 250a and the first bezel 260a are formed by the gap 280 and the dielectric 290. The first side bezel 250a and the first bezel 260a, And a frame bezel portion 22 is formed separately from the ground 21.

 Accordingly, the first antenna unit 200a includes a first feed port 220a, which is a first port formed not to be connected to the ground 210a, which is an upper side ground region indicated by a dotted line adjacent to the dielectric body 290, ; A first linear radiating element 230a connected to the first feed port 220a and receiving an electromagnetic signal and having a linearly opened end portion 235a having a predetermined height from the ground 210a, ; The ground 210a formed below the first linear radiating element 230a coupled to the first linear radiating element 230a and receiving an electromagnetic signal to generate an induced current; A first side bezel portion 250a which is a bezel portion 250 of a side surface of the frame bezel portion 22 connected to the ground 210a by a first connection point P1; And an open end 265a of the first bezel 260a which is a left frame of the upper vane 260 connected to the first side bezel 250a.

The operation principle according to the configuration of the first antenna unit 200a is as follows.

When an electromagnetic signal is applied to the first feed port 220a, the first linear radiating element 230a couples with the ground 210a to generate an induced current in the ground 210a. The current induced in the ground 210a flows to the first bezel 260a through the first side bezel 250a by the first connection point P1. Electrical energy is concentrated on the opened end portion 265a of the first bezel 260a by the flow of the surface current and a first connection point P1 connecting the first side bezel 250a and the ground 210a, Magnetic energy is concentrated in the periphery. The first antenna unit 200a has a half wavelength electrical length at the operating frequency of the low frequency band and exhibits the broadband characteristic as the return loss 201 indicated by the solid line 201 in FIG.

The second antenna unit 200b operates in a high frequency band and includes a second linear radiating element 230b and a ground 210b, a second connection point P2, And includes a second side bezel 250b, a second bezel 260b, a gap 280, and a dielectric 290.

The second feed port 220b connected to the second linear radiating element 230b is located near the open end 265b of the second bezel 260b and is positioned adjacent to the dielectric 290 And is not connected to the ground 210b of the upper side ground area indicated by a dotted line, so that a signal of an electromagnetic high frequency band from the RF module of the terminal is fed to the second antenna unit 200b.

In some cases, the L-C element is inserted into the second feed port 220b so as to be perfectly matched with the second antenna portion 200b in the high frequency band, so that the impedance matching is performed.

The second linear radiating element 230b is connected to the second feed port 220b and receives an electromagnetic signal. The second linear radiating element 230b is connected to the linear ground terminal 210b having a predetermined height, 235b. Therefore, when the second linear radiating element 230b receives an electromagnetic signal from the second feed port 220b and transmits an electromagnetic signal to the ground 210b by coupling coupling, the second linear radiating element 230b is guided to the ground 210b An electric current is generated. The open end 235b of the second linear radiating element 230b is located at a point near the second connection point P2.

The second radiating element 230b may be formed on the ground 210b or on the dielectric 290 to utilize the space of the housing 20.

The second connection point P2 is a connection point for connecting the ground 210b and the side bezel 250 of the side frame of the upper side frame bezel 22, And the right side second side bezel part 250b of the frame bezel part 22 are connected to each other.

An electromagnetic signal is transmitted from the ground 210b to the second side bezel 250b of the second antenna unit 200b by the second connection point P2, Is the starting point of the second side bezel portion 250b.

The second side bezel part 250b of the second antenna part 200b includes a second bezel part 260b which is an upper bezel part 260 surrounding a rim of the uppermost outermost part of the rectangular ground 21, And transmits the electromagnetic signal transmitted from the second connection point P2.

The second bezel portion 260b is connected to an end edge portion of the second side bezel portion 250b and is perpendicular to the second side bezel portion 250b, And the second bezel portion 260b is formed with an open end portion 265b.

The gap 280 maintains a gap at a predetermined position of the upper bezel 260 to form an open end 265b of the second bezel 260b.

And a dielectric 290 formed between the upper side frame bezel 22 and the rectangular ground 21 separated to the upper side by the gap 280 and having a predetermined width.

That is, the second side bezel 250b and the right side second bezel 260b of the upper bezel 260 are formed by the gap 280 and the dielectric 290, Side frame bezel portion 22 is formed separately from the ground 21. The upper frame-

The second antenna unit 200b includes a second feed port 210b that is a second port that is not connected to the ground 210b at a predetermined portion of the ground 210b adjacent to the dielectric body 290, Wow; A second linear radiating element 230b connected to the second feed port 210b and receiving an electromagnetic signal and having an end portion 235b linearly opened with the ground 210b at a predetermined height, ; The ground 210b formed below the second linear radiating element 230b coupled to the second linear radiating element 230b and receiving an electromagnetic signal to generate an induced current; A second side bezel part 250b which is a bezel part 250 of a side part of the frame 22 connected to the ground 210b by a second connection point P2; And an opened end portion 265b of the second bezel portion 260a which is the upper bezel portion 260 connected to the right side frame second side bezel portion 250b connected to the second connection point P2.

The operation principle according to the configuration of the second antenna unit 200b is as follows.

When an electromagnetic signal is applied to the second feed port 220b, the second linear radiating element 230b couples with the ground 210b to generate an induced current in the ground 210b. The current induced in the ground 210b flows to the second bezel portion 260b through the second side bezel portion 250b by the second connection point P2. Electrical energy is concentrated on the opened end portion 265b of the second bezel portion 260b by the flow of the surface current and the second connection point P2 connecting the second side bezel portion 250b and the ground 210b, The magnetic energy is concentrated around. The second antenna unit 200b has a half wavelength electrical length at an operating frequency of a high frequency band and exhibits a broadband characteristic such as a return loss indicated by a dotted line 202 in FIG.

FIG. 2C is a diagram illustrating reflection loss of the metal body antenna shown in FIGS. 2A and 2B. FIG.

Referring to FIG. 2C, the range of the operating frequency in the low frequency band is between 857 MHz and 963 MHz on the basis of the return loss of the solid line 201, -6 dB, and includes the frequency range of 880 MHz to 960 MHz of the EGSM. Also, the operating frequency range in the high frequency band is between about 1658 MHz and about 2180 MHz based on the dotted line 202 return loss -6 dB, and includes frequencies ranging from 1710 MHz to 2170 MHz of the DCS, PCS, and W2100.

FIG. 2D is a diagram showing surface current, electric and magnetic energy density of the metal body antenna shown in FIGS. 2A and 2B. Each operating frequency is 910 MHz included in the low frequency band and 1900 MHz included in the high frequency band.

3A and 3B are views showing the structure of an antenna according to another embodiment of the present invention.

FIG. 3A is a plan view showing a structure in which a radiating element connected to the feed port is linear and the radiating element, which is a bezel of the second antenna, is extended; FIG. FIG. 2 is a perspective view showing a structure in which a radiating element connected to a feed port is linear, and a metal body antenna in which a radiating element, which is a bezel part of a second antenna, is extended; FIG.

As shown in Figs. 3A and 3B, an extension line 370 is inserted into the open end portion 365b of the second bezel portion 360b. The extension line 370 serves to extend the length of the second bezel portion 360b in a vertical meander shape. 2A and 2B, when the distance between the end portions 265a of the first bezel 260a and the end 265b of the second bezel 260b is small, The bandwidth of the GSM 850 and the EGSM band can not be both included, as in the case of the return loss 202 of FIG. 2C. In order to overcome this, the gap 380 formed in the upper frame bezel 360 is expanded as shown in FIGS. 3A and 3B of the present invention, and an extension line 370 is inserted to compensate for the shortened resonance length. At this time, the end portion 375 of the extension line 370 is configured to maintain a maximum distance from the end portion 365a of the first bezel portion 360a and to minimize the gap with the ground 11.

The extension line 370 may be implemented as a linear or horizontal meander. In addition, the first and second radiating elements of FIGS. 2A and 3B can be modified into various shapes such as a linear meander, a vertical meander and the like as well as a linear shape.

FIG. 3C is a diagram illustrating return loss of the metal body antenna in which the radiating element connected to the feed port is linear, which is a bezel portion of the second antenna portion. FIG.

3C, the range of the operating frequency in the low frequency band is between about 822 MHz and about 964 MHz on the basis of the return loss -6 dB shown by the solid line 301, and includes the GSM 850 and the EGSM frequency range from 824 MHz to 960 MHz. The range of the operating frequency in the high frequency band is between about 1704 MHz and about 2177 MHz on the basis of the return loss -6dB represented by the point loss 302, and includes frequencies ranging from 1710 MHz to 2170 MHz of the DCS, PCS, and W2100.

FIG. 3D is a diagram showing the surface current, electric and magnetic energy density of the metal body antenna shown in FIGS. 3A and 3B. Each operating frequency is 910 MHz included in the low frequency band and 1900 MHz included in the high frequency band.

4A to 4E are views showing another embodiment of the present invention.

Referring to FIG. 4A, the metal body antenna of the present invention is mounted on a housing part 40 of a terminal, and the housing part 40 occupies most of the area of the housing part 40 by a rectangular metal material And a metal frame bezel portion 42 surrounding the upper end of the outermost rim portion of the rectangular ground.

The ground 41 of the housing part 40 may provide a ground voltage within the terminal and form a substrate on which circuit elements and components necessary for terminal operation are marketed.

More specifically, the metal body antenna formed in the housing part 40 according to the present invention includes grounds 410a and 410b, first and second feed ports 420a and 420b formed of two ports, The first and second radiating elements 430a and 430b and the common connection line 450 and the upper bezel portion 460 of the upper side frame bezel portion 42, that is, the first and second bezel portions 460a 480b formed on the first and second side bezel portions 470a and 470b and the first and second side bezel portions 470a and 470b and the dielectric body 460a and 460b formed on the first and second side bezel portions 470a and 470b, 490a, 490b.

In addition, the metal body antenna formed in the housing unit 40 according to the present invention includes a first antenna unit 400a operating in a low frequency band and a second antenna unit 400b operating in a high frequency band.

The metal body antenna according to the present invention shown in Figs. 4B and 4C is characterized in that the first and second radiating elements 430a and 430b are linear structures and the first and second bezel portions 460a and 460b Receives electromagnetic signals from the connection line 450 from a common position having the same start point.

The first antenna unit 400a operates in a low frequency band and includes a first linear radiating element 430a, a ground 410a, a connection line 450, 1 bezel portion 460a, a first side bezel portion 470a, a first gap 480a, and a dielectric body 490a.

The first feed port 420a connected to the first linear radiating element 430a is located near the end portion 475a of the first side bezel portion 470a and is connected to the dashed line 490a adjacent to the dielectric 490a, And is not connected to the ground 410a in the upper side ground 41 shown in FIG. 5A, so that the electromagnetic low frequency band signal from the RF module of the terminal is fed to the first antenna unit 400a.

The first linear radiating element 430a is connected to the first feed port 420a and receives an electromagnetic signal. The first linear radiating element 430a is connected to the linear ground terminal 410a having a predetermined height, 435b. Accordingly, the first linear radiating element 430a receiving the electromagnetic signal from the first feed port 420a transmits an electromagnetic signal to the ground 410a by coupling coupling. The end portion 435a of the opened first linear radiating element 430a is located at a point close to the connection line 450.

The first linear radiating element 430a may be formed on the ground 410a or on the dielectric body 490a to utilize the space of the housing part 20. [

The connection line 450 is a common connection line connecting the ground 410a and the upper bezel portion 460 of the upper side frame bezel portion 42. The connection line 450 connects the ground 410a, And the second connection point 452 of the upper bezel unit 460. The first connection point 451 of the upper bezel unit 460 is connected to the second connection point 452 of the upper bezel unit 460. [

Accordingly, the electromagnetic signal is transmitted from the ground 410a to the first bezel 460a of the first antenna unit 400a by the connection line 450, and the second connection point 452 is connected to the first 1 Bezel portion 460a.

The first bezel portion 460a of the first antenna portion 400a is connected to the upper portion of the frame bezel portion 42 surrounding the outermost upper side edge portion of the rectangular ground 41 connected to the connection line 450 And the electromagnetic signal transmitted by the connection line 450 is branched by the second connection point 452 and transmitted.

The first side bezel 470a is formed on the left side of the frame bezel 42 and extends to the first bezel 460a perpendicularly to the end edge of the first bezel 460a And an opened end portion 475a is formed in the first side bezel portion 470a.

The first gap 480a is formed at a position spaced apart from the upper portion of the first side bezel 470a by a predetermined distance from the lower end of the first side bezel 470a, 475a.

And dielectric bodies 490a and 490b formed to have a predetermined width between the upper side frame bezel part 42 separated by the first and second gaps 480a and 480b and the rectangular ground 41 .

That is, by the first and second gaps 480a and 480b and the dielectrics 490a and 490b, the first and second bezel parts 460a and 460b, which are the upper bezel part 460, The upper side frame bezel part 42 including the first side bezel part 470a and the second side bezel part 470b is formed separately from the ground 41. [

The first antenna unit 400a includes a first feed port 410a which is a first port that is not connected to the ground 410a at a predetermined upper portion of the ground 410a adjacent to the dielectric body 490a, Wow; A first linear radiating element 430a connected to the first feed port 410a and receiving an electromagnetic signal and having an end portion 435a linearly opened with the ground 410a at a predetermined height, ; A ground 410a formed below the first linear radiating element 430a coupled to the first linear radiating element 430a and receiving an electromagnetic signal; A connection portion connected to the ground 410a and connected to the upper bezel portion 460 of the upper side frame bezel portion 42 separated by the dielectric body 490a and the gap 480a is formed in the dielectric body 490a A connection line 450; Is separated by the first gap 480a from the upper bezel portion 460 that is connected to the connection line 450 to the first gap 480a of the left side frame of the upper side frame frame portion 42 And a first side bezel 470a.

The operation principle according to the configuration of the first antenna unit 400a is as follows.

When an electromagnetic signal is applied to the first feed port 420a, the first linear radiating element 430a couples with the ground 410a to generate an induction current in the ground 410a. The current induced in the ground 410a flows through the connection line 450 to the first bezel 460a. Electric energy is concentrated on the opened end portion 475a of the first side bezel portion 470a by the flow of the surface current and the electric energy is concentrated on the connection line 450 connecting the first bezel portion 460a and the ground 410a Magnetic energy is concentrated. The first antenna unit 400a has an electrical length of a half wavelength at an operating frequency in a low frequency band and exhibits a broadband characteristic such as a return loss indicated by a solid line 401 in FIG.

The configuration and operation principle of the second antenna unit 400b are the same as those of the first antenna unit 400a. However, only the operating frequency is different.

The second antenna unit 400b is an antenna element operating in a high frequency band and includes a second linear radiating element 430b, a ground 420b, a connection line 450, a second bezel 460b, And includes a bezel portion 470b and a dielectric 490b.

The second feed port 420b connected to the second linear radiating element 460b is located near the open end portion 475b of the second side bezel 470b and is adjacent to the dielectric 490b And is not connected to the ground 410b in the ground area 41 indicated by a dotted line to feed a signal of an electromagnetic high frequency band from the RF module of the terminal to the second antenna unit 400b.

The second linear radiating element 430b is connected to the second feed port 420b and receives an electromagnetic signal. The second linear radiating element 430b is connected to the linear ground terminal 410b having a predetermined height, 435b. Accordingly, the second linear radiating element 430b, which receives the electromagnetic signal from the second feed port 420b, transmits an electromagnetic signal to the ground 410b by coupling coupling. The open end 435b of the open second linear radiating element 430b is located at a point close to the connection line 450.

The second radiating element 430b may be formed on the ground 410b or on the dielectric body 490b to utilize the space of the housing part 40. [

The connection line 450 is a common connecting line connecting the second ground 420b and the upper bezel portion 460 of the upper side frame bezel portion 42. The connection line 450 connects the ground 410b and the second connection point 452 of the second bezel portion 460. The second connection point 452 of the second bezel portion 460 is connected to the first connection point 451 of the second bezel portion 410b.

Therefore, the electromagnetic signal is transmitted from the ground 410b to the second bezel 460b of the second antenna unit 400b by the connection line 450, and the second connection point 452 is connected to the 2 Bezel portion 460b.

The second bezel portion 460b of the second antenna unit 400b includes an upper side frame bezel portion 42 that surrounds the outermost upper side edge portion of the rectangular ground 41 connected to the connection line 450, And an electromagnetic signal transmitted by the connection line 450 is branched by the second connection point 452 and transmitted.

The second side bezel portion 470b is a right side frame of the upper side frame bezel portion 42 and extends perpendicularly to the end edge portion of the second bezel portion 460b and the second bezel portion 460b, And the second side bezel portion 470b is formed with an open end portion 475b.

The second gap 480b is formed at a position spaced a predetermined distance from the upper portion of the second side bezel 470b by a predetermined distance so that the open end of the second side bezel 470b 475b.

And dielectric bodies 490a and 490b formed to have a predetermined width between the upper side frame bezel portion 42 separated by the first and second gaps 480a and 480b and the rectangular ground 41 .

The first and second bezel portions 460a and 460b and the first and second bezel portions 460a and 460b that are the upper and lower bezel portions 460 and 460b and the side bezel portions 470a and 460b are formed by the gaps 480a and 480b and the dielectrics 490a and 490b. The upper side frame bezel portion 42 including the second side bezel portions 470a and 470b is formed separately from the ground 41. [

The second antenna port 400b is connected to a second feed port (not shown) connected to the ground 410b at a predetermined position in a region of the ground 41 indicated by a dotted line adjacent to the dielectric 490b. 420b; A second linear radiating element 430b connected to the second feed port 420b and receiving an electromagnetic signal and having a terminal portion 435b linearly opened with the ground 410b and a predetermined height, ; The ground 410b formed below the second radiating element 430b coupled to the second radiating element 430b and receiving an electromagnetic signal to generate an induced current; The dielectric body 490b is connected to the upper bezel portion 460 of the upper side frame bezel portion 41 connected to the ground 410b and separated by the dielectric body 490b and the second gap 480b. A connection line 450 formed; An upper bezel portion 460 of the upper side frame bezel portion 41 connected to the connection line 450; And a second side bezel 470b separated by the second gap 480b from the upper bezel 460 to the second gap 480b of the right frame of the frame bezel 42 Antenna.

The operation principle according to the configuration of the second antenna is as follows.

When an electromagnetic signal is applied to the second feed port 420b, the second linear radiating element 430b couples with the ground 410b to generate an induction current in the ground 410b. The current induced in the ground 410b flows to the second bezel portion 460b through the connection line 450. [ Electric energy is concentrated on the opened end portion 475b of the second side bezel portion 470b by the flow of the surface current and the electric energy is concentrated on the connection line 450 connecting the second bezel portion 460b and the ground 410b Magnetic energy is concentrated. The second antenna portion 400b has an electrical length of a half wavelength at an operating frequency in a high frequency band and exhibits a broadband characteristic as a return loss indicated by a dotted line 402 in FIG. 4D.

FIG. 4D is a diagram illustrating return loss of the metal body antenna shown in FIGS. 4B and 4C. FIG.

Referring to FIG. 4D, the range of the operating frequency in the low frequency band is between about 808 MHz and about 1073 MHz on the basis of the return loss of the solid line 201, -6dB, and between 824 MHz and 960 MHz in the frequency range of GSM850 and EGSM. Also, the range of the operating frequency in the high frequency band is between about 1705 MHz and about 2198 MHz based on the dotted line 202 return loss -6 dB, and includes frequencies ranging from 1710 MHz to 2170 MHz of DCS, PCS, and W2100.

FIG. 4E is a diagram showing the surface current, electric and magnetic energy density of the metal body antenna shown in FIGS. 4B and 4C. FIG. Each operating frequency is 910 MHz included in the low frequency band and 1900 MHz included in the high frequency band.

5A and 5B are views of a terminal including a structure of an antenna according to another embodiment of the present invention.

5A is a plan view illustrating a metal body cover and a metal body cover including a housing portion of a terminal in which a metal body antenna is formed as shown in FIG. 4A and a metal battery cover, and FIG. 5B Is a plan view showing a structure in which a metal body antenna including a vertical meander line is enlarged in detail, as a radiating element connected to a feed port mounted on a housing part of a terminal in which the metal body antenna of FIG. 5A is formed.

That is, in the metal body antenna structure shown in FIG. 4B, the metal body antenna is further formed by further including the right battery cover 55 in FIG. 5A. The battery cover 55 is composed of a metal battery cover 555a and a plastic battery cover 555b.

More specifically, as shown in FIG. 5B, a metal body antenna having a battery cover 55 on the right side of FIG. 5A is disposed on an upper portion of a housing portion of a terminal having a metal body antenna including the vertical meander line of FIG. 5a.

5A and 5B is characterized in that the first and second radiating elements 530a and 530b are vertical meander lines and the first and second radiating elements 530a and 530b are vertical meander lines, The bezel unit 560b receives electromagnetic signals from the connection line 550 from a common position having the same start point.

As in the left drawing of FIG. 5A. The transparent plastic battery cover 555b located at the upper portion of the battery cover 55 on the right side is located at the upper portion of FIG. 5B, and only the dielectric 590 and the upper bezel portions 560a and 560b are seen through, The upper surface is covered by the metal battery cover 555a of the battery cover 55 and the metal battery cover 555a and the lower ground 51 covered by the upper part are connected by the contact pin 555 to be.

Will be described in detail with reference to Figs. 6A and 6B. FIG. 6A is a plan view showing a structure in which a radiating element connected to a feed port in FIG. 5A is a vertical meander line, and a metal body antenna including a battery cover is enlarged in detail, FIG. 6B is a cross- Is a vertical meander line, and is a perspective view showing a structure in which a metal body antenna including a battery cover is enlarged in detail.

6A. The transparent plastic battery cover 555b located on the upper portion of the battery cover 55 shown on the right side of FIG. 5A is positioned at the upper portion of FIG. 6A and the dielectric 690 and the upper frame first and second bezel portions 660a and 660b And the upper surface of the ground 61 is covered by the metal battery cover 555a of the battery cover 55. At this time, the metal battery cover 555a covered at the upper portion is covered with the lower ground 61, And the connection line 650 as a connection line of the contact hole 655 and the contact pin 655 are shown in detail in FIG. 6B. 6A and 6B, the first and second radiating elements 630a and 630b are used in parallel with the first and second vertical meander lines 630a and 630b.

6A and 6B is characterized in that the first and second radiating elements 630a and 630b are vertical meander lines and the first bezel portion 660a and the second bezel portion 660b The bezel unit 660b receives electromagnetic signals from the connection line 650 from a common position having the same start point.

The first vertical meander line 630a and the second vertical meander line 630b are located in a space between the ground 11 and the battery cover 55. [ In order to prevent the occurrence of spurious resonance, the contact pin 655 connects the ground 11 and the metal battery cover 555a.

The first and second radiating elements 630a and 630b fed from the feed ports 620a and 620b in the structure using the battery cover 55 as shown in FIG. 6A are not limited to the linear radiating elements in FIG. And a radiating element of a diffuse structure.

The upper surface of the ground 51 formed in the housing part shown in FIG. 5A is covered by the metal battery cover 555a of the battery cover 55. At this time, the metal battery cover 555a and the lower The first and second radiating elements 230a and 230b shown in FIGS. 2A and 2B are linear in structure and the first bezel 260a And the open end portions 265a and 265b of the second bezel portion 260b are positioned adjacent to each other with the gap 280 therebetween, so that the metal body antenna is mounted, and the ground of the housing portion And the metal battery cover are connected to each other by the contact pins, thereby preventing the occurrence of unnecessary resonance.

5A is covered by the metal battery cover 555a of the battery cover 55. At this time, the metal battery cover 555a covered with the upper portion The lower ground 51 is connected by the contact pin 555. The gap 380 formed in the upper bezel 360 shown in Figs. 3A and 3B is also expanded, and the shorter resonance length is compensated The distance between the end portion 375 of the extension line 370 and the end portion 365a of the first bezel portion 360a is maximized by inserting the extension line 370 so that the distance between the extension portion 370 and the ground 11 is minimized So that it is possible to prevent the occurrence of unnecessary resonance by connecting the metal body antenna with the ground of the housing portion and the metal battery cover by the contact pin.

As described above, since the metal body antenna according to the present invention is a multi-antenna structure of a wide band with low radiation loss using a frame bezel, the PENTA BAND (GSM850, EGSM, DCS, PCS, W2100) Is satisfied.

In addition, the metal body antenna according to the present invention includes a metal body antenna including a frame bezel in a space between the housing part and the metal battery cover, and the ground of the housing part and the metal battery cover are connected by the contact pins, . &Lt; / RTI &gt;

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, It is within the scope of the present invention that component changes to such an extent that they can be coped evenly within a range that does not deviate from the scope of the present invention.

10, 20, 30, 40, 50, 60:
11, 21, 31, 41, 51, 61: ground
12, 22, 32, 42, 52, 62: upper side frame bezel portion
55: Battery cover: 150, 250, 350: Side bezel
370: extension line
160, 260, 360, 460, 560, 660:
180, 280, 380: Gap 190: Dielectric
555a: Metal battery cover 555b: Plastic battery cover
555, 655: contact pin
100a, 200a, 300a, 400a, 500a, 600a:
100b, 200b, 300b, 400b, 500b, 600b:
110a, 210a, 310a, 410a, 510a, 610a:
110b, 210b, 310b, 410b, 510b, 610b:
120a, 220a, 320a, 420a, 520a, and 620a:
120b, 220b, 320b, 420b, 520b, 620b:
130a, 230a, 330a, 430a, 530a, 630a:
130b, 230b, 330b, 430b, 530b, 630b:
135, 135a, 235a, 335a, 435a, 535a, 635a:
135b, 235b, 335b, 435b, 535b, 635b: the end of the second radiating element
450, 550, 650: connection line
451, 551, 651: First connection point 452, 552, 652: Second connection point
160a, 260a, 360a, 460a, 560a, 660a:
160b, 260b, 360b, 460b, 560b, 660b:
165a, 265a, and 365a: a terminal portion of the first bezel
165b, 265b, and 365b: the ends of the second bezel
470a, 570a, 670a: First side bezel part 470b, 570b, 670b: Second side bezel part
475a, 575a, 675a: a terminal end of the first side bezel
475b, 575b, 675b: the end of the second side bezel
480a, 580a, 680a: first gap 480b, 580b, 680b: second gap
190a, 290a, 390a, 490a, 590a, 690a: dielectric
190b, 290b, 390b, 490b, 590b, 690b: dielectric
P1: first connection point P2: second connection point

Claims (8)

delete delete A terminal housing part;
A metal frame bezel formed outside the terminal housing part;
A gap formed by cutting a part of the frame bezel;
A ground formed at a predetermined distance from a part of the frame bezel separated by the gap;
The ground is connected to a part of the other side of the frame bezel separated by the gap, the ground is connected to a part of the other side of the frame bezel separated by the gap,
A first radiating element coupled electromagnetically coupled to the ground;
A second radiating element coupled electromagnetically coupled to the ground; And
A first feed port formed in the terminal housing part for applying a low frequency signal to the first radiating element and a second feed port formed in the terminal housing part for applying a high frequency band signal to the second radiating element, ; &Lt; / RTI &gt;
A signal fed to the ground by electromagnetic coupling coupling from the first radiating element is transmitted to the frame bezel separated by the gap connected to the ground to be radiated and coupled to the electromagnetic coupling from the second radiating element, And the signal fed to the ground is transmitted to another frame bezel part separated by the gap connected to the ground, so that the broadband operation is performed in multiple bands. [4] The apparatus of claim 3, wherein the first radiating element and the second radiating element comprise:
Wherein the antenna is formed on both sides of the ground with the gap as a center, and operates in a wide band in multiple bands. The method of claim 3,
Wherein an impedance is matched by inserting an LC element between the first and second feed ports and the first and second radiating elements to operate in a wide band in multiple bands. The method of claim 3,
Further comprising an extension line of a metal material extending from one end of the frame bezel portion formed by the gap, so that the metal body antenna operates in a wide band in multiple bands. 7. The device of claim 6, wherein the end of the extension line is an open end,
Wherein a terminal end of the extension line operates in a wide band in multiple bands so as to maximize the distance from the one end of the frame bezel separated by the gap and to minimize the gap with the ground. . The method of claim 3,
Further comprising a metal battery cover at an upper portion of the housing portion to connect the ground of the housing portion to the battery cover.

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