KR102075780B1 - Portable device having rear cover and antenna module - Google Patents

Abstract

A portable terminal having a rear cover formed to have a horizontal length of a receiving groove accommodated in a camera module of a portable terminal longer than a vertical length to minimize magnetic field loss of the antenna module is provided. The presented mobile terminal includes a portable terminal body, a rear cover disposed on the rear side of the portable terminal body, and an antenna module interposed between the portable terminal body and the rear cover, and the rear cover is formed to be biased on one side and the first slit, one side And a camera hole formed closer to the first slit between the second slit and the first slit and the second slit formed on the other side opposite to the camera slit, wherein the camera hole has a horizontal length longer than the vertical length.

Description

PORTABLE DEVICE HAVING REAR COVER AND ANTENNA MODULE}

The present invention relates to a portable terminal having a rear cover and an antenna module, and more particularly, disposed between a rear cover and a portable terminal main body and a rear cover disposed at the rear of the portable terminal main body to perform electronic payment and short-range communication. The present invention relates to a portable terminal having an antenna module.

With the development of technology, mobile terminals such as mobile phones, PDAs, PMPs, navigation systems, laptops, etc., are not only basic functions such as calls, video / music playback, directions, etc. It provides additional functionality. Accordingly, the portable terminal includes a plurality of antennas for wireless communication, such as wireless internet and Bluetooth.

In addition, recently, there has been a trend to apply functions such as information exchange, payment, ticket reservation, search, etc. between terminals using short-range communication (ie, NFC) to the portable terminal. To this end, the portable terminal is equipped with an antenna module (that is, NFC antenna module) used in the short-range communication method. In this case, the NFC antenna module to be used is a non-contact short-range wireless communication module using a frequency band of about 13.56 MHz as one of electronic tags (RFID) to transmit data between terminals at a close distance of about 10 cm. NFC is widely used not only for payment, but also for sending goods information or travel information for visitors, traffic, and access control locks in supermarkets and general stores.

In addition, recently, as a function related to electronic payment using a mobile terminal such as Apple Pay, Samsung Pay, etc. is required, an electronic payment antenna is mounted on the mobile terminal. For example, since Samsung Pay performs electronic payment using a magnetic secure transmission method, a MST antenna is mounted in a mobile terminal that supports Samsung Pay.

On the other hand, as miniaturization and thinning required in the portable terminal market are required, the size and thickness of the portable terminal are reduced, and mounting space of internal components is decreasing.

To meet these market demands, various types of antenna modules have been developed to minimize area and thickness.

However, since the MST antenna module used for electronic payment is formed in the form of winding the coil, in case of miniaturization and thinning, short circuit occurs, irregular winding due to bending, and distortion due to thin material. Due to various causes, there is a problem in that a defective rate increases during manufacturing of the antenna module, and the performance of the antenna module is degraded.

In addition, as the portable terminal becomes smaller, there is a problem in that the mounting space is insufficient when simultaneously mounting a plurality of antennas. Accordingly, there is a demand for an integrated antenna in which a near field communication antenna and an MST antenna are integrally formed.

In addition, as the portable terminal is applied with a metal rear cover, a rear cover for minimizing a loss of a magnetic field (radiation field) generated in the antenna module is required.

Korea Patent No. 10-0505847 (Name: removable battery cover with a loop antenna and a contactless wireless payment mobile phone using the same)

The present invention has been proposed in view of the above circumstances, and has a portable terminal having a rear cover formed to have a horizontal length of a receiving groove accommodated in a camera module of the portable terminal longer than a vertical length to minimize magnetic field loss of the antenna module. It aims to provide.

In addition, the present invention is to form a radiation pattern for short-range communication and electronic payment radiation pattern on a flexible printed circuit board and then combined with a magnetic sheet to simplify the manufacturing process while performing an antenna module that is equal to or better than the conventional antenna module. It is an object to provide a portable terminal provided.

In order to achieve the above object, a portable terminal according to an embodiment of the present invention includes a portable terminal body, a rear cover disposed at the rear of the portable terminal body, and an antenna module interposed between the portable terminal body and the rear cover, and a rear cover. The camera hole includes a first slit formed by being biased on one side, a second slit formed by being biased by the other side opposite to one side, and a camera hole formed closer to the first slit between the first slit and the second slit. The horizontal length is formed longer than the vertical length.

The first slit may be formed in parallel with one side and the second slit may be formed in parallel with the other side. In this case, the first slit may be bent at both ends and connected to one side, and the second slit may be bent at both ends and connected to the other side.

The camera hole may be formed to have a length longer than the length of the side disposed in parallel with one side.

The antenna module includes an antenna sheet having a first radiation pattern and a second radiation pattern formed thereon, a shielding sheet disposed on the front surface of the antenna sheet and overlapping the second radiation pattern, and having one end penetrating the antenna sheet at the front and rear surfaces of the antenna sheet. The other end may include a magnetic sheet disposed to extend outwardly of the antenna sheet and a first step compensating sheet disposed on the front surface of the magnetic sheet to compensate terminals of the antenna sheet and the magnetic sheet.

The magnetic sheet is formed to extend from the base region, the base region, a lower protruding region spaced apart from the first slit formed on the rear cover of the mobile terminal, extending from the base region to face the lower protruding region, the rear surface of the antenna sheet A first overlapping region disposed in and overlapping the first radiation pattern and extending from the first overlapping region to penetrate the insertion hole of the antenna sheet, and a second overlapping region disposed in front of the antenna sheet and overlapping the first radiation pattern It may include. In this case, the magnetic sheet extends from the second overlapping region to face the first overlapping region, and further includes an upper protrusion overlapping the shielding sheet, and the upper protrusion is spaced apart from the second slit formed on the rear cover of the mobile terminal. Can be arranged.

The antenna sheet is a flexible substrate formed by inserting one end of the magnetic sheet and a receiving hole spaced apart from each other, and a first radiation pattern wound along the outer circumference of the insertion hole and overlapping with the magnetic sheets disposed on the front and rear surfaces of the antenna sheet. And a second radiation pattern wound along an outer circumference of the accommodation hole. In this case, the second radiation pattern may overlap the first slit, and the accommodation hole may be disposed on an outer circumference of the camera hole formed in the rear cover.

According to the present invention, the rear cover of the portable terminal has a length longer than the vertical length of the camera hole accommodated in the camera module formed in the main body, there is an effect that can minimize the loss of the magnetic field of the radiation pattern for electronic payment. That is, as the rear cover of the portable terminal increases the amount of magnetic field emitted from the camera hole, the amount of magnetic field emitted by the back cover made of metal is increased, thereby minimizing the loss of the magnetic field of the radiation pattern for electronic payment.

In addition, the rear cover of the portable terminal increases the amount of magnetic field emission through the camera hole, thereby minimizing the length of the magnetic loop to minimize the magnetic field loss of the electronic payment radiation pattern.

In addition, the rear cover of the mobile terminal is formed by the length of the camera hole that accommodates the camera module formed in the main body longer than the vertical length, the magnetic field of the radiation pattern for the electronic payment compared to the conventional rear cover is formed shorter than the vertical length There is an effect that can improve the antenna performance by minimizing the loop.

In addition, the antenna module of the mobile terminal forms a short distance communication radiation pattern and an electronic payment radiation pattern on a flexible printed circuit board, and then combines it with a magnetic sheet, thereby increasing the short range communication and electronic payment recognition area as compared to the conventional antenna module. It has an effect.

In addition, the antenna module of the portable terminal has the effect of ensuring the mounting space, and simplify the manufacturing and mounting process, while achieving the antenna performance equivalent to or higher than the conventional antenna module.

In addition, the antenna module of the portable terminal is configured by using the flexible member to prevent the damage when mounting on the portable terminal, there is an effect that can be easily mounted in a curved position.

In addition, the antenna module of the mobile terminal forms a short-range communication radiation pattern and an electronic payment radiation pattern on the flexible printed circuit board and then combines with the magnetic sheet, thereby simplifying the manufacturing process compared to the conventional antenna module winding the coil on the magnetic material. It can be effective.

That is, the antenna module of the mobile terminal uses a coil winding process including coil winding, coil insertion, coil pressing, soldering, cutting, UV bonding, UV curing, and terminal connection of a coil in a conventional antenna module manufacturing process of winding a coil. Since it can be omitted, there is an effect that can simplify the manufacturing process.

In addition, the antenna module of the mobile terminal forms a radiation pattern for short-range communication and a radiation pattern for electronic payment on a flexible printed circuit board and then combines with a magnetic sheet, thereby preventing the attachment of an insulating material to prevent short between the magnetic material and the coil. This simplifies the manufacturing process and reduces costs.

In addition, the antenna module of the portable terminal forms a protruding region disposed in the magnetic sheet adjacent to the slit formed on the rear cover of the portable terminal, thereby increasing the amount of magnetic field emitted to the outside of the portable terminal to form a strong radiation field to increase the antenna performance. There is an effect to improve.

In addition, the antenna module of the portable terminal forms a protruding region disposed in the magnetic sheet adjacent to the slit formed on the rear cover of the portable terminal, thereby forming a radiation field on the front and the rear of the portable terminal, so that short-range communication is performed in front and rear of the portable terminal. There is a possible effect.

In addition, the antenna module of the portable terminal can arrange the step compensation sheet on the magnetic sheet, thereby compensating the step between the magnetic sheet and the antenna sheet to form an antenna module having a constant thickness, and thus can be easily mounted on the portable terminal. have.

In addition, the antenna module of the portable terminal has an effect of improving the flatness of the surface of the antenna module by forming a hole in the step compensation sheet, thereby minimizing the generation of bubbles when the protective sheet is bonded.

In addition, the antenna module of the portable terminal removes a partial region of the magnetic sheet overlapping with the geomagnetic sensor of the portable terminal, and then arranges a step compensation sheet, thereby preventing the occurrence of interference of the geomagnetic sensor by the antenna module, thereby reducing the sensing performance of the geomagnetic sensor. There is an effect that can be prevented.

In addition, the antenna module of the portable terminal supports the circuit board of the portable terminal by arranging the supporting member on the front surface, thereby having an effect of firmly supporting the circuit board while preventing the degradation of the antenna performance.

1 and 2 are views for explaining a rear cover according to an embodiment of the present invention.
3 and 4 are views for explaining the antenna module of FIG.
5 and 6 are views for explaining the antenna sheet of FIG.
FIG. 7 is a view for explaining the shielding sheet of FIG. 3. FIG.
FIG. 8 is a view for explaining the magnetic sheet of FIG. 3. FIG.
9 is a view for explaining a modification of the antenna module of FIG.

Hereinafter, the most preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily implement the technical idea of the present invention. . First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are designated as much as possible even if displayed on different drawings. In addition, in describing the present invention, if it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 and 2, a portable terminal according to an exemplary embodiment of the present invention includes an antenna module interposed between a rear cover 100, a main body 10, and a rear cover 100 disposed on a rear side of a main body 10. And 200.

The back cover 100 includes a first slit 122, a second slit 124, and a camera hole 130 that pass through a magnetic field (ie, a magnetic field) of a radiation pattern to form a radiation field for electronic payment and near field communication. ) Is formed.

The first slit 122 is formed to be biased toward one side of the portable terminal. The first slit 122 is formed to be spaced apart from one side and disposed parallel to one side. At this time, both ends of the first slit 122 may be connected to one side.

The second slit 124 is formed to be biased toward the other side of the portable terminal, the second slit 124 is formed to be spaced apart from the other side and disposed in parallel with the other side. At this time, both ends of the second slit 124 may be bent and connected to the other side.

The camera hole 130 is formed between the first slit 122 and the second slit 124, and is formed by being biased by the first slit 122. In this case, the camera hole 130 is a groove in which the camera module, the lighting module, and the like of the portable terminal are accommodated.

The camera hole 130 has a horizontal length X longer than the vertical length Y. That is, the length X of the horizontal side of the camera hole 130 disposed in parallel with one side is formed longer than the length Y of the vertical side disposed vertically with the one side. Here, as an example, the camera hole 130 has a rectangular shape. The camera hole 130 may have a rectangular vertex in a round shape.

The camera hole 130 increases the width of the area in which the magnetic field generated in the electronic payment radiation pattern of the antenna module 200 is emitted. That is, the camera hole 130 accommodates the camera module of the mobile terminal main body 10, and the width (ie, the horizontal length) of the emission area of the camera module is increased so that the magnetic field of the radiation pattern for electronic payment is emitted. Increase the width

Accordingly, the rear cover 100 increases the emission amount of the magnetic field generated in the electronic payment radiation pattern through the camera hole 130 having an increased horizontal length, thereby improving antenna characteristics of the electronic payment radiation pattern. This will be described below with reference to the attached back cover 100 with reference to the accompanying drawings.

In the case of the conventional rear cover 100 to which the length (Y) of the vertical side is longer than the length (X) of the horizontal side, a small number of magnetic fields emitted by the radiation pattern for electronic payment are generated by the camera hole ( 130, and most of the remaining magnetic field is discharged through the first slit 122. In this case, the magnetic field emitted from the electronic payment radiation pattern is emitted through the first slit 122 and the camera hole 130 and forms a magnetic field in which the second slit 124 is introduced.

In the mobile terminal to which the conventional rear cover 100 is applied, a loss occurs due to the metal rear cover 100 while the magnetic field generated by the electronic payment radiation pattern moves to the first slit 122. Antenna performance is degraded. That is, in the portable terminal to which the conventional rear cover 100 is applied, the rear cover 100 of the metal material is less than the magnetic field (that is, the magnetic field emitted through the camera hole 130) with less loss due to the metal back cover 100. ) Due to the high loss of the magnetic field (that is, the magnetic field emitted through the first slit 122), the performance of the electronic payment antenna is degraded.

In addition, since most of the magnetic field emitted from the electronic payment radiation pattern is emitted through the first slit 122, the distance to the second slit 124 to be input to the second slit 124 is long, so that an additional loss occurs. Antenna performance is further degraded.

Accordingly, the rear cover 100 according to the embodiment of the present invention applies the camera hole 130 formed with the length X of the horizontal side longer than the length Y of the vertical side.

Accordingly, the emission amount of the magnetic field emitted to the camera hole 130 of the magnetic field emitted from the electronic payment radiation pattern is increased compared to the conventional rear cover 100, the emission amount of the magnetic field emitted to the first slit 122 is It is reduced compared to the conventional rear cover (100).

At this time, the magnetic field emitted to the camera hole 130 is less than the magnetic field emitted to the first slit 122 because the loss caused by the metal back cover 100 can be minimized.

Therefore, the rear cover 100 according to the embodiment of the present invention can improve the antenna performance by reducing the loss of the magnetic field emitted from the radiation pattern for electronic payment compared to the conventional rear cover 100.

In addition, since the rear cover 100 according to the embodiment of the present invention increases the amount of emission of the magnetic field emitted through the camera hole 130, the distance to the second cover 124 (ie, the magnetic loop) is increased. Decreases relatively.

Thus, the rear cover 100 according to the embodiment of the present invention can improve the antenna performance compared to the conventional rear cover 100.

The antenna module 200 is interposed between the main body 10 and the rear cover 100 of the portable terminal. In this case, one end of the antenna module 200 is spaced apart from the second slit 124 by a predetermined interval, and the other end of the antenna module 200 is disposed to partially overlap the first slit 122.

3 and 4, the antenna module 200 includes an antenna sheet 210, a shielding sheet 220, a magnetic sheet 230, a first step compensation sheet 240, and a second step compensation sheet 250. , A protective sheet 260, a third step compensation sheet 270, and an adhesive sheet 280. Hereinafter, the front surface refers to one surface of the direction facing the inside of the mobile terminal (ie, the main body 10 direction), and the rear surface refers to the other surface of the direction facing the outside of the portable terminal (ie, the rear cover 100 direction). I can understand it.

5 and 6, the antenna sheet 210 includes a flexible substrate 211 on which a first radiation pattern 212 and a second radiation pattern 213 are formed. In this case, the first radiation pattern 212 is a radiation pattern for electronic payment (eg, MST (Magnetic Secure Transmission)), the second radiation pattern 213 is radiation for short-range communication (eg, NFC) As an example, it is a pattern.

The flexible substrate 211 may be formed of a flexible material, such as polyimide (PI), polyethylene phthalate (PET), and thermoplastic polyurethane (TPU).

In the flexible substrate 211, insertion holes 214 and accommodation holes 215 are formed to be spaced apart from each other. In this case, the insertion hole 214 is a hole through which the magnetic sheet 230 is inserted, and may be formed in a slit shape having a long side and a short side. The accommodation hole 215 is a hole in which a camera module (not shown) of the portable terminal is accommodated, and may be formed in various shapes according to the portable terminal in which the antenna module 200 is mounted.

The first radiation pattern 212 is formed in a loop shape in which the outer circumference of the insertion hole 214 of the flexible substrate 211 is wound a plurality of times. In this case, the first radiation pattern 212 may be formed on at least one surface of the front and rear surfaces of the flexible substrate 211.

In this case, the region in which the first radiation pattern 212 is formed in the flexible substrate 211 may be formed in the first region A1 and the second region according to the relative position with the insertion hole 214 and the overlap with the magnetic sheet 230. It may be divided into (A2), the third region A3, and the fourth region A4.

The first area A1 is disposed above the insertion hole 214 and is an area where the magnetic sheet 230 overlaps at the rear surface. In this case, the first radiation pattern 212 is formed only on the front surface of the first region A1 that does not overlap the magnetic sheet 230.

The second area A2 is disposed under the insertion hole 214 and is an area where the magnetic sheet 230 overlaps the front surface. In this case, the first radiation pattern 212 is formed only on the rear surface of the second region A2 that does not overlap the magnetic sheet 230.

The third area A3 and the fourth area A4 are areas that are disposed opposite to each other on the side of the insertion hole 214 and do not overlap with the magnetic sheet 230. In this case, since the width (ie, D) of the insertion hole 214 is formed to be as wide as possible in order to increase the performance of the first radiation pattern 212 (that is, the performance for electronic payment), the third region A3 and the third region are formed. 4 area | region A4 becomes relatively narrow. That is, the area capable of forming the first radiation pattern 212 is narrowed.

When the first radiation pattern 212 is formed in the third region A3 and the fourth region A4 with the same number of turns as the first region A1 and the second region A2, the first radiation pattern 212 may be Narrower line widths increase resistance and degrade antenna performance.

Accordingly, first radiation patterns 212 are formed on the front and rear surfaces of the third region A3 and the fourth region A4. At this time, the first radiation pattern 212 formed in the third area A3 and the fourth area A4 has a turn count compared to the first radiation pattern 212 formed in the first area A1 and the second area A2. Reduces to half and increases line width to minimize resistance increase.

The first radiation patterns 212 disposed on the front and rear surfaces of the flexible substrate 211 form a loop type electronic payment antenna connected through the via holes to wind the insertion hole 214.

When only one surface of the flexible substrate 211 is formed, the first radiation pattern 212 may be formed on the other surface opposite to one surface on which the second radiation pattern 213 is formed. For example, when the first radiation pattern 212 is formed on the front surface of the flexible substrate 211, the second radiation pattern 213 is formed on the rear surface of the flexible substrate 211.

When formed on both sides (ie, front and rear) of the flexible substrate 211, the first radiation pattern 212 is composed of a plurality of patterns respectively disposed on the front and rear of the flexible substrate 211, each pattern is For example, the first radiation pattern 212 may be connected to another pattern formed on the opposite surface through the via hole.

The second radiation pattern 213 is formed in a loop shape in which the outer circumference of the accommodating hole 215 of the flexible substrate 211 is wound a plurality of times. In this case, the second radiation pattern 213 may be formed in a loop shape to wind the outer circumference of the accommodation hole 215 on the front or rear surface of the flexible substrate 211.

The second radiation pattern 213 may be formed of a plurality of patterns, and may be formed in a loop shape in which the outer circumference of the accommodation hole 215 is wound a plurality of times on the front and rear surfaces of the flexible substrate 211. In this case, the plurality of patterns are spaced apart on the front and rear of the flexible substrate 211, each pattern is connected to the other pattern formed on the opposite surface through the via hole to form a second radiation pattern 213 as an example. do.

The antenna sheet 210 may further include a terminal portion 216 connecting the first radiation pattern 212 and the second radiation pattern 213 to the main circuit board of the portable terminal. In this case, the terminal unit 216 includes a plurality of terminals 217 connected to both ends of the first radiation pattern 212 and both ends of the second radiation pattern 213, respectively, and extend from one side of the flexible substrate 211. Is formed.

Referring to FIG. 7, the shielding sheet 220 is adhered to the front surface of the antenna sheet 210. At this time, the shielding sheet 220 is bonded to the front of the antenna sheet 210, so that the radiation pattern of the antenna sheet 210 forms a magnetic field in the rear direction of the portable terminal. The shielding sheet 220 is formed to cover an area in which the second radiation pattern 213 is formed in the antenna sheet 210, and a hole corresponding to the accommodation hole 215 of the antenna sheet 210 is formed therein.

The magnetic sheet 230 is an auxiliary radiation of the first radiation pattern 212 formed on the antenna sheet 210 and may be formed of a thin film metal. In this case, the magnetic sheet 230 may be formed of one metal material selected from nanocrystalline alloy, iron-based amorphous alloy, and ferrite. Here, the nano-grain alloy is an Fe-based magnetic alloy as an example, the Fe-based magnetic alloy can be used Fe-Si-B-Cu-Nb alloy. In this case, it is preferable that Fe is 73-80 at%, the sum of Si and B is 15-26 at%, and the sum of Cu and Nb is 1-5 at%.

The magnetic sheet 230 is formed of a metal material in a soft state that is not subjected to heat treatment. That is, when the magnetic sheet 230 is formed in a rigid state by heat-treating a metal material, the magnetic sheet 230 is damaged in the process of mounting the antenna module 200 on the portable terminal, and thus the antenna sheet is deteriorated or mounted at a position where bending occurs. Because of this difficulty, the magnetic sheet 230 is preferably in a soft state without performing heat treatment.

Referring to FIG. 8, the magnetic sheet 230 is formed in a quadrangular shape and includes a base region 231, which is a region of the magnetic sheet 230.

In the base region 231, a concave region 232 is formed to prevent interference of the geomagnetic sensor. That is, when the magnetic sheet 230 overlaps with the geomagnetic sensor mounted on the portable terminal, the magnetic permeability of the magnetic sheet 230 causes interference with the geomagnetic sensor, thereby reducing the sensing accuracy of the geomagnetic sensor.

Thus, in the exemplary embodiment of the present invention, the concave region 232 is formed in the base region 231 so as not to overlap the magnetic sheet 230 and the geomagnetic sensor. In this case, the concave region 232 is a region in which metal is removed by cutting a portion of the base region 231.

Since the rear cover 100 of the mobile terminal is formed of a metal material, the magnetic field emitted from the radiation patterns (that is, the first radiation pattern 212 and the second radiation pattern 213) is shielded.

The antenna module 200 requires a radiation pattern (ie, a first radiation pattern 212 and a second radiation pattern 213) or a magnetic sheet 230 to be disposed adjacent to the slit 120 and the camera hole 130. The magnetic field can be strongly formed by increasing the amount of magnetic field emitted outside of.

However, since various substrates are disposed in the portable terminal such as a main circuit board, a battery, a coupling or support structure, it is difficult to arrange the magnetic sheet 230 adjacent to the slit 120.

Accordingly, in the exemplary embodiment of the present invention, the lower protruding region 233 is formed to protrude outwardly (ie, in the direction of the second slit 124) from one side of the base region 231. The lower protruding region 233 protrudes from one side of the four sides of the base region 231 in the direction of the second slit 124. The lower protruding region 233 is spaced apart from the second slit 124 by a predetermined interval. In this case, the lower protruding region 233 is disposed as close as possible to the second slit 124.

The width of the lower protruding region 233 is formed to be narrower than the width of one side of the base region 231, and the protruding position may be changed within one side according to the substrate arrangement structure of the portable terminal.

In the base region 231, an overlapping region 234 is formed through the insertion hole 214 of the antenna sheet 210 to overlap with the first radiation pattern 212. In this case, the overlap region 234 extends from the other surface of the base region 231 and is disposed to face the lower protruding region 233.

The overlap region 234 extends from the other side of the base region 231 and extends from the first overlap region 235 and the first overlap region 235 disposed on the rear surface of the antenna sheet 210 to extend the antenna sheet 210. It may be divided into a second overlapping area 236 disposed on the front surface.

The first overlapping region 235 is disposed on the rear surface of the antenna sheet 210 and overlaps the first radiation pattern 212 formed under the insertion hole 214. The second overlapping region 236 is disposed on the front surface of the antenna sheet 210 through the insertion hole 214 and overlaps the first radiation pattern 212 formed on the insertion hole 214.

In this case, the width of the second overlapping region 236 is formed to be equal to or less than the width of the insertion hole 214, and the first overlapping region 235 is formed to decrease in width as it approaches the second overlapping region 236.

For example, the first overlapping region 235 has a trapezoidal shape having a lower side longer than the upper side, and the lower side is connected to the other surface of the base region 231, and the upper side is connected to the second overlapping region 236. In this case, the upper side of the first overlapping region 235 is formed to have a length less than or equal to the width of the insertion hole 214.

The second overlapped region 236 extends from an upper side of the first overlapped region 235. The second overlapping region 236 passes through the insertion hole 214 in the front direction from the rear surface of the antenna sheet 210 and is disposed on the front surface of the antenna sheet 210.

Meanwhile, bonding the antenna sheet 210 and the magnetic sheet 230 between the first overlap region 235 and the rear surface of the antenna sheet 210 and between the second overlap region 236 and the front surface of the antenna sheet 210. An adhesive substrate (not shown) may be interposed.

An upper protruding region 237 may be formed in the second overlapping region 236 to improve antenna performance of the first radiation pattern 212.

The upper protruding region 237 extends from the second overlapping region 236. In this case, the upper protruding region 237 extends in a direction opposite to the first overlapping region 235. In this case, the upper protruding region 237 is disposed as close as possible to the second slit 124. The width of the upper protruding region 237 is smaller than the width of one side of the connected second overlapping region 236.

The upper protruding region 237 overlaps the second radiation pattern 213 and a part of the shielding sheet 220 and is spaced apart from the first slit 122 of the portable terminal by a predetermined distance. In this case, the antenna module 200 according to the embodiment of the present invention arranges the upper protruding region 237 of the magnetic sheet 230 to overlap with the shielding sheet 220, so that the shielding overlapping the upper protruding region 237 is disposed. The sheet 220 may partially act as an auxiliary radiator of the first radiation pattern 212 to improve antenna performance of the first radiation pattern 212.

Here, the base region 231, the lower protruding region 233, the overlapping region 234 (that is, the first overlapping region 235 and the second overlapping region 236) and Although separated into the upper protruding area 237, the present invention is not limited thereto, and in the actual product, the base area 231, the lower protruding area 233, the overlapping area 234 (that is, the first overlapping area 235 and the second overlapping area) are described. Region 236 and top protruding region 237 may be integrally formed.

The first step compensation sheet 240 compensates for the step between the antenna sheet 210 and the magnetic sheet 230. That is, the first step compensation sheet 240 may include a magnetic sheet (or magnetic sheet) to compensate for the step difference generated between the antenna sheet 210 and the magnetic sheet 230 as the magnetic sheet 230 is inserted through the antenna sheet 210. 230 is placed in front of.

The first step compensation sheet 240 is formed to have a thickness corresponding to the thickness of the antenna sheet 210. In this case, the thickness of the first step compensation sheet 240 may be the same as the thickness of the flexible substrate 211 and the radiation pattern of the antenna sheet 210.

The first step compensation sheet 240 is disposed in the base area 231 of the magnetic sheet 230. In this case, the first step compensation sheet 240 may be disposed in a portion of the base area 231 and may be disposed to face the overlap area 234.

This is to compensate for the step by the sticker (for example, a battery specification sheet sticker) attached to the battery of the mobile terminal. That is, for example, the first step compensation sheet 240 is disposed in the base area 231 of the magnetic sheet 230 and is formed in an area except for an area overlapping the sticker attached to the battery.

The first step compensation sheet 240 is provided with a plurality of air receiving holes 242 spaced apart from each other. The air accommodating hole 242 accommodates air introduced between the magnetic sheet 230 and the protective sheet 260 during the attaching process of the protective sheet 260 which will be described later to prevent bubble generation of the protective sheet 260. That is, the air accommodating hole 242 serves to planarize the surface of the protective sheet 260 by preventing bubble generation of the protective sheet 260.

As an example, the first step compensation sheet 240 is one selected from a polyethylene naphthalate (PEN) film, a polyethylene terephthalate (PET) film, a polyimide (PI) film, a polycarbonate (PC) film, and a polystyrene sulfonate (PSS) film. .

The second step compensation sheet 250 is disposed in the concave region 232 of the magnetic sheet 230. The second step compensating sheet 250 is formed in the same shape as the region cut from the magnetic sheet 230 to form the recessed region 232 for preventing the interference between the geomagnetic sensor and the magnetic sheet 230. 232). In this case, the second step compensation sheet 250 may be formed in various shapes such as a quadrangle, a fan, and the like corresponding to the shape of the concave region 232.

For example, the second step compensation sheet 250 may be one selected from a polyethylene naphthalate (PEN) film, a polyethylene terephthalate (PET) film, a polyimide (PI) film, a polycarbonate (PC) film, and a polystyrene sulfonate (PSS) film. .

The protective sheet 260 is adhered to the front surface of the antenna sheet 210 and the magnetic sheet 230 to prevent breakage of the radiation pattern formed on the antenna sheet 210 and the magnetic sheet 230.

When an impact is applied to the portable terminal, the antenna module 200 may generate a collision with an internal structure (for example, a battery) of the portable terminal. When the antenna module 200 collides with the internal structure, the magnetic sheet 230 is damaged or the characteristics of the magnetic sheet 230 are changed to affect antenna performance.

Thus, in the exemplary embodiment of the present invention, a dummy region is formed at one side of the antenna sheet 210 and one side of the magnetic sheet 230. In this case, the dummy region may include a first dummy region 218 formed in the antenna sheet 210 and a second dummy region 238 formed in the magnetic sheet 230. Here, the first dummy region 218 is an area formed on one side of the antenna sheet 210 and means an area in which the radiation pattern is not formed among the entire areas of the flexible substrate 211. The second dummy region 238 is a region formed on one side of the magnetic sheet 230 and refers to a region formed by removing a portion of one side of the magnetic substrate.

The third step compensation sheet 270 is disposed on one side of the magnetic sheet 230, and is disposed in the second dummy area 238. That is, the shock is absorbed during the collision between the magnetic sheet 230 and the internal structure of the portable terminal to prevent breakage and change of characteristics of the magnetic sheet 230.

In this case, the third step compensation sheet 270 is one selected from a polyethylene naphthalate (PEN) film, a polyethylene terephthalate (PET) film, a polyimide (PI) film, a polycarbonate (PC) film, and a polystyrene sulfonate (PSS) film. Shall be.

The adhesive sheet 280 is a component for attaching the antenna module 200 to the main body 10 or the rear cover 100 of the portable terminal, and is bonded to the rear surface of the antenna sheet 210 and the magnetic sheet 230. In this case, the front surface of the adhesive sheet 280 is bonded to the rear surface of the antenna sheet 210 and the magnetic sheet 230. The release film, which is removed before the process of attaching the antenna module 200 to the mobile terminal, is attached to the rear surface of the adhesive sheet 280. Here, the adhesive sheet 280 may include a first adhesive sheet 280 attached to the antenna sheet 210 and a second adhesive sheet 280 attached to the magnetic sheet 230.

The portable terminal has a structure for supporting the circuit board (for example, a support protrusion connecting the battery and the main circuit board) is formed, and as the size (area) of the antenna module 200 increases, the portable terminal is formed in an area where the structure is formed. The antenna module 200 may be disposed.

In this case, the antenna module 200 may have a hole through which the structure penetrates. However, when the hole is formed, the area for forming the radiation pattern may be narrowed, or the antenna module 200 may not implement a loop-shaped radiation pattern. The performance of the antenna becomes impossible.

Thus, as shown in FIG. 9, the antenna module 200 according to the embodiment of the present invention may further include a support member 290 for supporting the circuit board. That is, the support module 290 protruding toward the front surface (ie, the circuit board direction) is disposed in the antenna module 200 instead of forming a hole.

Through this, the antenna module 200 may firmly support the circuit board while maintaining the antenna performance.

Although a preferred embodiment according to the present invention has been described above, it can be modified in various forms, and those skilled in the art can make various modifications and modifications without departing from the claims of the present invention. It is understood that it may be practiced.

100: rear cover 120: slit
124: first slit 126: second slit
130: camera hole 200: antenna module
210: antenna sheet 220: shielding sheet
230: magnetic sheet 240: first step compensation sheet
250: second step compensation sheet 260: protective sheet
270: third step compensation sheet 280: adhesive sheet
290: support member

Claims (10)

A portable terminal body;
A rear cover disposed at the rear of the portable terminal main body; And
An antenna module interposed between the portable terminal body and the rear cover;
The rear cover,
A first slit formed by being biased at one side;
A second slit formed to be biased to the other side opposite to the one side; And
A camera hole formed closer to the first slit between the first slit and the second slit,
The camera hole has a horizontal length longer than the vertical length,
The antenna module,
An antenna sheet having a first radiation pattern and a second radiation pattern;
A shielding sheet disposed on a front surface of the antenna sheet and overlapping the second radiation pattern;
A magnetic sheet having one end penetrating the antenna sheet and disposed at the front and rear surfaces of the antenna sheet, and the other end extending in an outer direction of the antenna sheet; And
And a first step compensating sheet disposed on a front surface of the magnetic sheet to compensate the terminals of the antenna sheet and the magnetic sheet. The method of claim 1,
The first slit is formed in parallel with the one side, the second slit is formed in parallel with the other side. The method of claim 2,
The first slit is bent at both ends and connected to the one side, and the second slit is bent at both ends and connected to the other side. delete delete The method of claim 1,
The magnetic sheet,
Base area;
A lower protruding region extending from the base region and spaced apart from a first slit formed on a rear cover of the portable terminal;
A first overlapping region extending from the base region to face the lower protruding region and disposed on a rear surface of the antenna sheet and overlapping the first radiation pattern; And
And a second overlapping region extending from the first overlapping region and penetrating through the insertion hole of the antenna sheet and disposed in front of the antenna sheet and overlapping the first radiation pattern. The method of claim 6,
The magnetic sheet is
An upper protrusion extending from the second overlapping region to face the first overlapping region and overlapping with the shielding sheet;
The upper protrusion is a portable terminal spaced apart from the second slit formed on the rear cover of the portable terminal. The method of claim 1,
The antenna sheet,
A flexible substrate formed by spaced apart from each other an insertion hole and a receiving hole through which one end of the magnetic sheet is inserted;
A first radiation pattern wound along an outer circumference of the insertion hole and overlapping with a magnetic sheet disposed on front and rear surfaces of the antenna sheet; And
And a second radiation pattern wound along an outer circumference of the accommodation hole. The method of claim 8,
The second radiation pattern overlaps the first slit. The method of claim 8,
The accommodation hole is a portable terminal disposed on the outer circumference of the camera hole formed in the rear cover.

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