KR102383528B1 - Combo antenna module and portable device having the same - Google Patents

Abstract

Provided are a combo antenna module in which an extended magnetic sheet is extended and disposed under a connector cable of a portable terminal to prevent noise generation during wireless power transmission, and a portable terminal having the same. The presented mobile terminal includes a battery, a combo antenna module disposed under the battery, and a connector cable disposed adjacent to the combo antenna module, and the combo antenna module is disposed under the battery and connector cable to overlap the connector cable Includes sheet.

Description

Combo antenna module and mobile terminal having the same

The present invention relates to a combo antenna module and a portable terminal having the same, and more particularly, to a combo antenna module mounted on a portable terminal and a portable terminal having the same.

The mobile terminal provides various functions such as short-distance communication, wireless charging, and electronic payment. Various antennas such as an NFC antenna, a WPC antenna, and an MST antenna are mounted in a mobile terminal to provide various functions.

As various antennas are mounted in the portable terminal, the mounting space is always insufficient. As portable terminals become smaller and thinner, and the battery size increases due to an increase in battery capacity, the shortage of mounting space is further aggravating.

The antenna industry is conducting research to reduce the size of the antenna in order to solve the problem of insufficient mounting space for portable terminals. When the size of the antenna decreases, the area on which the radiation pattern is mounted decreases, and interference between radiation patterns of different frequency bands occurs. Area reduction and interference are the main causes of degradation of antenna performance.

A combo antenna module is an antenna in which a plurality of antennas (radiation patterns) having different frequency bands, such as an NFC antenna, a WPC antenna, and an MST antenna, are formed into one module (or board). is being used

Recently, as smaller and thinner portable terminals than conventional portable terminals such as wearable devices and foldable phones have been developed, the development of a combo antenna module having a smaller size and having an antenna performance equal to or greater than that of the conventional one is required.

Korean Patent Registration No. 10-0505847 (Name: Removable battery cover with loop antenna and contactless wireless payment mobile phone to which it is applied)

The present invention has been proposed in view of the above circumstances, and a metal sheet covering a separation area of magnetic sheets disposed on the upper and lower portions of the antenna sheet, respectively, is interposed in a combo to prevent the generation of fine noise in the connector cable during wireless power transmission. An object of the present invention is to provide an antenna module and a mobile terminal having the same.

In order to achieve the above object, a portable terminal according to an embodiment of the present invention includes a battery, a combo antenna module disposed under the battery, and a connector cable disposed adjacent to the combo antenna module, and the combo antenna module is located at the bottom of the battery. and a lower magnetic sheet disposed on the , an expanded magnetic sheet disposed under the battery, and a metal sheet disposed on the expanded magnetic sheet and disposed in a spaced area between the lower magnetic sheet and the expanded magnetic sheet.

In order to achieve the above object, a combo antenna module according to an embodiment of the present invention includes an antenna sheet having a plurality of radiation patterns formed thereon, an extended magnetic sheet disposed on the antenna sheet, a lower magnetic sheet disposed under the antenna sheet, and an extension and a metal sheet disposed on the magnetic sheet and disposed in a spaced region between the lower magnetic sheet and the expanded magnetic sheet.

According to the present invention, a combo antenna module and a mobile terminal having the same form a spacing between the lower magnetic sheet and the extended magnetic sheet, and by expanding the extended magnetic sheet, noise is generated in the connector cable by the TX magnetic field during wireless power transmission. There is a way to prevent that from happening.

In addition, the combo antenna module and the mobile terminal having the same interpose a metal sheet covering the separation area of the magnetic sheets disposed on the upper and lower portions of the antenna sheet, respectively, by shielding the TX magnetic field applied to the connector cable through the separation area. It has the effect of preventing the generation of fine noise in the connector cable.

In addition, the combo antenna module and the portable terminal having the same prevent the occurrence of noise in the connector cable due to the TX magnetic field, thereby preventing the occurrence of abnormal phenomena due to noise of the connector cable, such as the flicker phenomenon of the display module.

In addition, the combo antenna module and the mobile terminal having the same form a spacing between the lower magnetic sheet and the extended magnetic sheet and expand the extended magnetic sheet, thereby preventing noise in the connector cable and improving NFC and MST communication performance. can have an effect.

In addition, the combo antenna module and the mobile terminal having the same are arranged to have a spacing within a set range of magnetic sheets disposed on the upper and lower portions of the antenna sheet, respectively, so that the magnetic field flow of the second radiation pattern and the third radiation pattern is smooth. This has the effect of improving the antenna performance in the frequency band corresponding to the second radiation pattern and the third radiation pattern.

In addition, the combo antenna module and the mobile terminal having the same are arranged to have a spacing within a set range of magnetic sheets disposed on the upper and lower portions of the antenna sheet, respectively, so that noise is generated in surrounding parts by the magnetic field of the radiation patterns. It has a preventable effect.

In addition, the combo antenna module and the mobile terminal having the same are arranged to have a separation distance within a set range of magnetic sheets disposed on the upper and lower portions of the antenna sheet, respectively, to prevent the occurrence of noise in the surrounding parts, so that the display generated by noise There is an effect of preventing a flicker phenomenon and the like.

In addition, by forming the combo antenna module and the mobile terminal having the same to have opposite inclinations in the intersection area of the second radiation pattern and the third radiation pattern, interference between the second radiation pattern and the third radiation pattern is minimized even in a small size. This has the effect of improving the antenna performance.

In addition, the combo antenna module and the mobile terminal having the same can improve the recognition rate and recognition distance of the MST frequency band in the small mobile terminal by forming the second radiation pattern and the third radiation pattern to have opposite inclinations in the crossing area. It works.

In addition, the combo antenna module and the portable terminal having the same can secure reliability by minimizing the occurrence of cracks during the bending test by forming the second radiation pattern and the third radiation pattern to have opposite inclinations in the intersection area. .

1 is a view for explaining an example of a mobile terminal to which a combo antenna module according to an embodiment of the present invention is applied.
2 is a view for explaining a combo antenna module according to an embodiment of the present invention.
3 and 4 are views for explaining the antenna sheet of FIG.
5 is a view for explaining the upper magnetic sheet of FIG.
6 and 7 are views for explaining the lower magnetic sheet of FIG.
8 to 10 are views for explaining the expanded magnetic sheet of FIG.
11 is a view for explaining the overlapping of the upper magnetic sheet and the lower magnetic sheet of FIG.
FIG. 12 is a view for explaining the overlapping of the extended magnetic sheet and the lower magnetic sheet of FIG. 2 ;
13 is a view for explaining a radiation pattern exposed through a spaced region between the expanded magnetic sheet and the lower magnetic sheet.
14 and 15 are diagrams for explaining a portable terminal on which a general combo antenna module is mounted.
16 to 18 are diagrams for explaining a portable terminal having a combo antenna module according to an embodiment of the present invention.
19 to 21 are diagrams for explaining antenna performance of a portable terminal having a combo antenna module according to the first embodiment of the present invention.
22 and 23 are views for explaining a phenomenon in which a magnetic field is introduced into a connector cable through a separation area of the combo antenna module according to the first embodiment of the present invention.
24 to 28 are views for explaining a combo antenna module according to a second embodiment of the present invention.
29 to 31 are diagrams for explaining antenna performance of a portable terminal having a combo antenna module according to a second embodiment of the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described with reference to the accompanying drawings in order to describe in detail enough that a person of ordinary skill in the art to which the present invention pertains 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 components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings.

In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in the description of the embodiment of the present invention, when it is described that a certain structure is disposed or formed "on" or "on" of another structure, such a substrate is not only when these structures are in contact with each other, but also when these structures are It should be interpreted as including even the case where a third structure is interposed between them.

Referring to FIG. 1 , the combo antenna module 100 according to an embodiment of the present invention is mounted on a small portable terminal having a smaller mounting space than a general smart phone. As an example, the small portable terminal is a foldable phone 10 that is folded in a vertical direction, a wearable device, and the like.

For example, since a foldable phone is folded in the vertical direction, the mounting space is reduced in half compared to a general smartphone. The combo antenna module 100 becomes smaller in size as the mounting space is reduced, making it difficult to implement antenna performance.

Accordingly, the combo antenna module 100 according to the first embodiment of the present invention is based on the antenna characteristics required by the mobile terminal, the separation distance (GW) of the magnetic sheets disposed on the upper and lower portions of the antenna sheet 110, respectively. It provides antenna performance equal to or higher than that of the combo antenna module 100 applied to a general smartphone even in a state where the size is reduced by adjusting within the setting range.

In addition, the combo antenna module 100 according to the first embodiment of the present invention expands the magnetic sheet shielding the radiation pattern to shield the connector cable so that noise is generated in the connector cable by the magnetic field generated during wireless power transmission. to prevent Accordingly, the combo antenna module 100 according to the first embodiment of the present invention prevents flicker from occurring in the display due to the noise generation of the connector cable.

Referring to FIG. 2 , the combo antenna module 100 according to the first embodiment of the present invention includes an antenna sheet 110 having a plurality of radiation patterns formed thereon, and an upper magnetic sheet 120 disposed on the upper surface of the antenna sheet 110 . , is configured to include a lower magnetic sheet 130 disposed on the lower surface of the antenna sheet 110 , and an extended magnetic sheet 140 disposed on the upper surface of the upper magnetic sheet 120 .

The antenna sheet 110 includes a plurality of radiation patterns resonating in different frequency bands. The antenna sheet 110 is a first radiation pattern 112 that resonates in the WPC frequency band for wireless power transmission (or wireless charging), a second radiation pattern 113 that resonates in the NFC frequency band for short-range communication, and electronic payment For example, including the third radiation pattern 114 resonating in the MST frequency band will be described.

3 and 4 , the antenna sheet 110 includes a base sheet 111 , a first radiation pattern 112 , a second radiation pattern 113 , and a third radiation pattern 114 .

The base sheet 111 is formed of a thin flexible substrate such as a film, a sheet, or a thin film substrate. The base sheet 111 may be a flexible printed circuit board (FPCB). The base sheet 111 is an example of a polypropylene (PP; polypropylene) sheet. Here, the base sheet 111 is not limited thereto, and as long as it is a thin film substrate and capable of forming a radiation pattern constituting the antenna, it may be used in various ways.

The base sheet 111 includes a first side S11 , a second side S12 opposite to the first side S11 , and a third side connected to one end of the first side S11 and one end of the second side S12 . It has a side S13 and a fourth side S14 opposite to the third side S13 and connected to the other end of the first side S11 and the other end of the second side S12. Here, the first side (S11) to the fourth side (S14) are assumed to facilitate the description of the present invention, and in the actual product, as shown in the drawing, a terminal unit 115 for terminal connection of radiation patterns, The extension 116 or the like extending from one of the four sides may not be formed in a straight line. In this case, the first side S11 to the fourth side S14 may be defined based on a rectangular area in which the radiation pattern is formed in the base sheet 111 .

The first radiation pattern 112 is disposed on the upper surface of the base sheet 111 . The first radiation pattern 112 is formed in a loop shape in which the first winding shaft is wound a plurality of times. Here, the first winding axis is an imaginary axis orthogonal to the central portion of the base sheet 111 , and the first radiation pattern 112 resonates in the WPC frequency band as an example.

At this time, in the base sheet 111, the first radiation pattern 112 is divided into an inner peripheral area IZ, which is an area disposed on the inner periphery of the loop shape based on the loop shape, and an outer circumferential area OZ, which is disposed on the outer periphery of the loop shape. can be

The first radiation pattern 112 may also be disposed on the lower surface of the base sheet 111 . The first radiation pattern 112 disposed on the upper surface of the base sheet 111 and the first radiation pattern 112 disposed on the lower surface of the base sheet 111 are connected through a via hole. The first radiation pattern 112 is formed in the base sheet 111 in the intersecting areas (first intersecting area A1, second intersecting area A2, third intersecting area A3, fourth intersecting area A4). A loop is formed via the first radiation pattern 112 formed on the lower surface of the base sheet 111 rather than on the upper surface of the .

The second radiation pattern 113 is disposed on the upper surface of the base sheet 111 . The second radiation pattern 113 is disposed adjacent to the first side S11 of the base sheet 111 . The second radiation pattern 113 is formed in a loop shape in which a second winding shaft spaced apart from the first winding shaft is wound a plurality of times. Here, the second winding side is a virtual axis orthogonal to a position spaced apart from the first winding axis by a predetermined distance in the direction of the first side S11 of the base sheet 111 from the first winding axis, and the second radiation pattern 113 is the NFC frequency band. For example, resonance in

The second radiation pattern 113 intersects the first radiation pattern 112 . That is, the second radiation pattern 113 alternately passes through the inner circumferential area IZ and the outer circumferential area OZ of the base sheet 111 and passes through the first intersecting area A1 and the second intersecting area A2 . It intersects the loops of the radiation pattern 112 .

The second radiation pattern 113 has an inclination that approaches the first side S11 of the base sheet 111 from the inner periphery to the outer periphery of the first radiation pattern 112 . In other words, the second radiation pattern 113 flows in the outer circumferential direction of the first radiation pattern 112 in the first intersection area A1 and the second intersection area A2, and the first side ( S11) and has an inclination away from the third radiation pattern 114 .

The third radiation pattern 114 is disposed on the upper surface of the base sheet 111 . The third radiation pattern 114 is disposed adjacent to the second side S12 of the base sheet 111 . The third radiation pattern 114 is formed in a loop shape in which a third winding shaft spaced apart from the first winding shaft and the second winding shaft is wound a plurality of times. Here, the third winding side is a virtual axis orthogonal to a position spaced apart from the first winding axis by a predetermined distance in the direction of the second side S12 of the base sheet 111, and the third radiation pattern 114 is the MST frequency band. For example, resonance in

The third radiation pattern 114 intersects the first radiation pattern 112 . That is, the third radiation pattern 114 alternately passes through the inner circumferential area IZ and the outer circumferential area OZ of the base sheet 111 and passes through the first intersecting area A3 and the fourth intersecting area A4 . It intersects the loops of the radiation pattern 112 .

The third radiation pattern 114 has an inclination that approaches the second side S12 of the base sheet 111 from the inner periphery to the outer periphery of the first radiation pattern 112 . In other words, the third radiation pattern 114 flows in the outer circumferential direction of the first radiation pattern 112 in the third intersection area A3 and the fourth intersection area A4, and the second side ( S12) and has an inclination away from the second radiation pattern 113.

The third radiation pattern 114 may be formed to have a plurality of refraction portions. The third radiation pattern 114 may be formed as a quadrangular loop having the first refraction portions R1 to the fourth refraction portions R4 . In this case, among the plurality of refraction portions, a refraction portion of an area facing the second radiation pattern 113 may be exposed through a spaced apart area GA between the upper magnetic sheet 120 and the lower magnetic sheet 130 , which will be described later.

The second radiation pattern 113 and the third radiation pattern 114 maintain the same spacing G1 in the inner peripheral region IZ of the first radiation pattern 112 . The spacing between the second radiation pattern 113 and the third radiation pattern 114 increases toward the outer periphery of the first radiation pattern 112 between the inner and outer periphery of the first radiation pattern 112 . The second radiation pattern 113 and the third radiation pattern 114 maintain the same spacing G2 after passing through the outer periphery of the first radiation pattern 112 . In this case, the spacing G2 in the outer peripheral region OZ of the first radiation pattern 112 is greater than the spacing G1 in the inner peripheral region IZ of the first radiation pattern 112 .

The combo antenna module 100 according to the first embodiment of the present invention is formed such that the spacing between the second radiation pattern 113 and the third radiation pattern 114 in the crossing areas A1-A4 is widened. Accordingly, the combo antenna module 100 minimizes the interference between the second radiation pattern 113 and the third radiation pattern 114 to improve the antenna performance of the second radiation pattern 113 and the third radiation pattern 114 . can be improved

Of course, since the combo antenna module 100 has an inclination in the first crossing region A1 to the fourth crossing region A4, it is possible to minimize the occurrence of cracks during the bending test.

The upper magnetic sheet 120 is disposed on the upper surface of the antenna sheet 110 . The upper magnetic sheet 120 is disposed adjacent to the first side S11 of the base sheet 111 . The upper magnetic sheet 120 is disposed in a region overlapping the first radiation pattern 112 and the second radiation pattern 113 . Referring to FIG. 5 , the upper magnetic sheet 120 may be divided into a first base area 121 and a first protrusion area 122 .

The first base area 121 is disposed adjacent to the first side S11 of the base sheet 111 . The first base region 121 is disposed adjacent to the first side S11 of the base sheet 111 by facing the first side S21 and the first side S21 facing the lower magnetic sheet 130 . A third side S23 connected to the second side S22, one end of the first side S21, and one end of the second side S22, the other end of the first side S21, and the other end of the second side S22 It includes a fourth side (S24) connected to.

The first protruding area 122 extends from the first side S21 of the first base area 121 . The first protruding area 122 extends from the first side S21 of the first base area 121 in the direction of the second side S12 of the base sheet 111 .

Among the first protruding regions 122 , a partial region disposed in a direction opposite to the first base region 121 overlaps the lower magnetic sheet 130 . In this case, the first protruding region 122 overlaps the lower magnetic sheet 130 with the antenna sheet 110 interposed therebetween in a partial region extending in the direction of the second side S12 of the base sheet 111 .

The width of the first protruding area 122 is narrower than the width of the first base area 121 (ie, the shortest distance between the third side S23 and the fourth side S24 of the first base area 121 ). is formed Accordingly, a portion of the first side S21 ′ of the first base region 121 faces the lower magnetic sheet 130 at both sides of the first protruding region 122 and is spaced apart from the lower magnetic sheet 130 by a predetermined distance or more. do.

The lower magnetic sheet 130 is disposed on the lower surface of the antenna sheet 110 . In this case, the lower magnetic sheet 130 is disposed adjacent to the second side S12 of the base sheet 111 opposite to the first side S11 of the base sheet 111 . The lower magnetic sheet 130 is disposed in an area overlapping the third radiation pattern 114 .

Referring to FIG. 6 , a recess 132 is formed in one side of the lower magnetic sheet 130 facing the upper magnetic sheet 120 . The recess 132 is formed to have a shape corresponding to the first radiation pattern 112 so that the lower magnetic sheet 130 does not overlap the first radiation pattern 112 .

The groove 132 is formed to have a width smaller than that of one side of the lower magnetic sheet 130 facing the upper magnetic sheet 120 . Accordingly, the lower magnetic sheet 130 faces the upper magnetic sheet 120 at both sides of the recess 132 . In this case, the lower magnetic sheet 130 is spaced apart from the first side part S21 ′ of the first base region 121 of the upper magnetic sheet 120 by more than a set range.

Referring to FIG. 7 , the lower magnetic sheet 130 may be divided into a first main area 134 , a first expansion area 136 , and a second expansion area 138 .

The first main area 134 is an area overlapping the antenna sheet 110 among the entire area of the lower magnetic sheet 130 . The above-described recess 132 is formed in the first main region 134 .

The first extended area 136 refers to an area from one side of the first main area 134 to the first side S31 among the entire area of the lower magnetic sheet 130 . In other words, the first extension area 136 is an area arranged to extend outwardly on a line overlapping the fourth side S14 of the antenna sheet.

The second extended area 138 refers to an area from the other side of the first main area 134 to the second side S32 among the entire area of the lower magnetic sheet 130 . In other words, the second extended area 136 is an area arranged to extend outwardly on a line overlapping the third side S13 of the antenna sheet.

When the first extension region 136 and the second extension region 138 are mounted on the portable terminal, at least a portion overlaps with the connector cable. The first extension region 136 and the second extension region 138 block the magnetic field generated by the radiation patterns to prevent noise from being generated in the connector cable due to the magnetic field.

For example, the first extension region 136 and the second extension region 138 overlap a connector cable such as an FRC cable and a C2C cable connecting the main board and the display. The first extension area 136 and the second extension area 138 block a magnetic field generated in the first radiation pattern during wireless power transmission to prevent noise in the connector cable. Accordingly, the combo antenna module 100 may prevent the flickering phenomenon of the display due to the noise generation of the connector cable.

The expanded magnetic sheet 140 is disposed adjacent to the first side S11 of the base sheet 111 . The expanded magnetic sheet 140 is disposed in a region overlapping the first radiation pattern 112 and the second radiation pattern 113 .

The expanded magnetic sheet 140 is disposed on the upper magnetic sheet 120 . An upper magnetic sheet 120 is interposed between the expanded magnetic sheet 140 and the antenna sheet 110 . That is, the upper magnetic sheet 120 is disposed on the upper surface of the antenna sheet 110 , and the extended magnetic sheet 140 is disposed on the upper surface of the upper magnetic sheet 140 . Accordingly, the upper magnetic sheet 120 is interposed between the antenna sheet 110 and the extended magnetic sheet 140 .

Referring to FIG. 8 , the expanded magnetic sheet 140 may be disposed on the antenna sheet 110 . The second upper magnetic sheet 140 is interposed between the antenna sheet 110 and the upper magnetic sheet 120 . That is, the expanded magnetic sheet 140 is disposed on the upper surface of the antenna sheet 110 , and the upper magnetic sheet 120 is disposed on the upper surface of the expanded magnetic sheet 140 . Accordingly, the expanded magnetic sheet 140 is interposed between the antenna sheet 110 and the upper magnetic sheet 120 .

Referring to FIG. 9 , the expanded magnetic sheet 140 may be divided into a second base area 141 and a second protrusion area 142 .

The second base area 141 is disposed adjacent to the second side S11 of the base sheet 111 . The second base region 141 is disposed adjacent to a first side S31 facing the lower magnetic sheet 130 , facing the first side S31 and adjacent to the second side S11 of the base sheet 111 . A third side S33 connected to the second side S32, one end of the second side S31, and one end of the second side S32, the other end of the second side S31, and the other end of the second side S32 It includes a fourth side (S34) connected to.

The second protruding area 142 extends from the first side S31 of the second base area 141 . The second protruding area 142 extends from the first side S31 of the second base area 141 in the direction of the second side S12 of the base sheet 111 .

Among the second protruding regions 142 , a partial region disposed in a direction opposite to the second base region 141 overlaps the lower magnetic sheet 130 . In this case, the second protruding region 142 overlaps the lower magnetic sheet 130 with the antenna sheet 110 interposed therebetween in a partial region extending in the direction of the second side S12 of the base sheet 111 .

The width of the second protruding area 142 is narrower than the width of the second base area 141 (ie, the shortest distance between the third side S33 and the fourth side S34 of the second base area 141 ). is formed Accordingly, a portion of the first side S31 ′ of the second base region 141 faces the lower magnetic sheet 130 at both sides of the second protruding region 142 and is spaced apart from the lower magnetic sheet 130 by a predetermined distance or more. do.

The second protruding area 142 overlaps the first protruding area 121 of the upper magnetic sheet 120 . That is, when the expanded magnetic sheet 140 is disposed on the upper surface of the upper magnetic sheet 120 , the second protruding area 142 is disposed on the upper surface of the first protruding area 121 to overlap the first protruding area 121 . do. When the expanded magnetic sheet 140 is disposed on the lower surface of the upper magnetic sheet 120 , the second protruding area 142 is disposed on the lower surface of the first protruding area 121 to overlap the first protruding area 121 .

Meanwhile, referring to FIG. 10 , the second base region 141 may be divided into a second main region 143 , a third extension region 144 , and a fourth extension region 145 .

The second main area 143 is an area overlapping the antenna sheet 110 and the upper magnetic sheet 120 among the second base areas 141 .

The third extended area 144 is an area from the outer periphery of the second main area 143 to a portion of the second side S42 and the third side S43 of the second base area 141 . The third extended area 144 does not overlap the antenna sheet 110 and is an area disposed outside the first side S11 and the fourth side S14 of the antenna sheet 110 .

The fourth extended area 145 is an area from the outer periphery of the second main area 143 to a portion of the second side S42 and the fourth side S44 of the second base area 141 . The fourth extended area 145 is an area that does not overlap the antenna sheet 110 and is disposed outside the first side S11 and the third side S13 of the antenna sheet 110 .

At least a portion of the third extension region 144 and the fourth extension region 145 overlaps with the connector cable when mounted on the mobile terminal. The third extended region 144 and the fourth extended region 145 block the magnetic field generated by the radiation patterns to prevent noise from being generated in the connector cable due to the magnetic field.

For example, the third extension area 144 and the fourth extension area 145 overlap a connector cable such as an FRC cable and a C2C cable connecting the main board and the display. The third extended region 144 and the fourth extended region 145 block a magnetic field generated in the first radiation pattern during wireless power transmission to prevent noise in the connector cable. Accordingly, the combo antenna module 100 may prevent the flickering phenomenon of the display due to the noise generation of the connector cable.

Referring to FIG. 11 , the upper magnetic sheet 120 and the lower magnetic sheet 130 overlap each other in a portion of the third radiation pattern 114 , and a first separation interval GW1 within a set range at both sides of the overlapped region ) to form a first separation area GA1 .

The first separation distance GW1 of the upper magnetic sheet 120 and the lower magnetic sheet 130 may be adjusted within a set range according to antenna characteristics required by the mobile terminal.

When a current is applied to the radiation patterns in a state where the first separation distance GW1 of the upper magnetic sheet 120 and the lower magnetic sheet 130 exceeds the maximum value of the set range, the magnetic field formed in the radiation patterns becomes strong. It affects the components in the mobile terminal.

For example, noise is generated in the connector cable connecting the display of the mobile terminal and the main board due to the magnetic field generated in the first radiation pattern 112 during wireless power transmission, and the flicker phenomenon in the display due to the noise of the connector cable This can happen.

As another example, the magnetic field generated in the second radiation pattern 113 must pass through the upper magnetic sheet 120 and move to the upper portion of the combo antenna module 100, and the upper magnetic sheet 120 and the lower magnetic sheet ( When the first separation interval GW1 of 130) exceeds the maximum value of the set range, the magnetic field does not flow well to the upper part of the combo antenna module 100, and a loss occurs, which causes the antenna of the second radiation pattern 113 Performance (eg, MST communication performance) is degraded.

On the other hand, when a current is applied to the radiation patterns in a state where the first separation distance GW1 of the upper magnetic sheet 120 and the lower magnetic sheet 130 is less than the minimum value of the set range, the upper magnetic sheet 120 and the lower magnetic sheet Since the first separation interval GW1 of 130 is narrow, the magnetic field formed in the radiation patterns does not pass through the first separation interval GW1 and is stagnant, thereby deteriorating the antenna performance.

For example, the magnetic field generated from the second radiation pattern 113 and the third radiation pattern 114 does not smoothly pass through the first separation distance GW1 between the upper magnetic sheet 120 and the lower magnetic sheet 130 . and congestion, and short-distance communication performance deteriorates.

In other words, the magnetic field generated from the second radiation pattern 113 must pass through the upper magnetic sheet 120 and move to the upper portion of the combo antenna module 100 , and the upper magnetic sheet 120 and the lower magnetic sheet 130 . ) is less than the minimum value of the set range, and the magnetic field of the second radiation pattern 113 is not sufficiently formed in the lower part of the combo antenna module 100 due to the stagnation of the magnetic field, so the second radiation pattern The antenna performance of (113) (eg, MST communication performance) is deteriorated.

Accordingly, the first separation interval GW1 of the upper magnetic sheet 120 and the lower magnetic sheet 130 is formed to have an interval within a set range according to the antenna characteristics required by the mobile terminal.

At this time, as an example, the setting range is 2 mm or more and 8 mm or less. The setting range may be set as a relative length with the antenna sheet 110 , and in this case, it may be set to 5% or more and 20% or less of the length of the antenna sheet 110 . Here, the length of the antenna sheet 110 is the length of the region where the radiation pattern is formed in the antenna sheet 110 , which is the shortest distance between the first side S11 and the second side S12 of the base sheet 111 . As an example, when the antenna sheet length is about 38mm, the setting range may be about 1.9mm or more and 7.6mm or less.

The setting range may be set as a relative length with the base sheet 111 , and in this case, it may be set to 5% or more and 20% or less of the length of the base sheet 111 . Here, the length of the base sheet 111 may be a length in a direction orthogonal to the first side S11 and the second side S12, and when the length of the base sheet is approximately 38 mm, the setting range is approximately 1.9 mm or more and 7.6 mm may be below.

The upper magnetic sheet 120 and the lower magnetic sheet 130 may be formed to have the same first spacing GW1 at both sides of the first protruding region 122 or the recess 132 . That is, in the upper magnetic sheet 120 and the lower magnetic sheet 130 , the first separation interval GW1 in the direction of the third side S13 of the base sheet 111 is the first separation interval in the direction of the fourth side S14 of the base sheet 111 . It may be arranged to be the same as (GW1).

Referring to FIG. 12 , the lower magnetic sheet 130 and the extended magnetic sheet 140 overlap each other in a portion of the third radiation pattern 114 , and a second separation interval GW2 within a set range at both sides of the overlapping area. ) to form a second spaced area GA2 . In this case, the first extended region 136 of the lower magnetic sheet 130 faces the third extended region 144 of the extended magnetic sheet 140 while being spaced apart by the second separation distance GW2 . The second extended area 138 of the lower magnetic sheet 130 faces the fourth extended area 145 of the expanded magnetic sheet 140 while being spaced apart by the second separation distance GW2 .

The second separation distance GW2 of the lower magnetic sheet 130 and the extended magnetic sheet 140 may be adjusted within a set range according to antenna characteristics required by the mobile terminal.

When a current is applied to the radiation patterns in a state where the second separation distance GW2 of the lower magnetic sheet 130 and the extended magnetic sheet 140 exceeds the maximum value of the set range, the magnetic field formed in the radiation patterns becomes strong. It affects the components in the mobile terminal.

For example, noise is generated in the connector cable connecting the display of the mobile terminal and the main board due to the magnetic field generated in the first radiation pattern 112 during wireless power transmission, and the flicker phenomenon in the display due to the noise of the connector cable This can happen.

As another example, the magnetic field generated in the second radiation pattern 113 must pass through the expanded magnetic sheet 140 and move to the upper portion of the combo antenna module 100, and the lower magnetic sheet 130 and the expanded magnetic sheet ( When the second separation interval GW2 of 140 exceeds the maximum value of the set range, the magnetic field does not flow well to the upper part of the combo antenna module 100 and a loss occurs, which causes the antenna of the second radiation pattern 113 Performance (eg, MST communication performance) is degraded.

On the other hand, when a current is applied to the radiation patterns in a state where the second separation distance GW2 of the lower magnetic sheet 130 and the extended magnetic sheet 140 is less than the minimum value of the set range, the lower magnetic sheet 130 and the extended magnetic sheet Because the second separation interval GW2 of 140 is narrow, the magnetic field formed in the radiation patterns does not pass through the second separation interval GW2 and stagnates, thereby deteriorating the antenna performance.

For example, the magnetic field generated from the second radiation pattern 113 and the third radiation pattern 114 does not smoothly pass through the second separation interval GW2 of the lower magnetic sheet 130 and the extended magnetic sheet 140 . and congestion, and short-distance communication performance deteriorates.

In other words, the magnetic field generated in the second radiation pattern 113 must pass through the expanded magnetic sheet 140 and move to the upper portion of the combo antenna module 100 , but the lower magnetic sheet 130 and the expanded magnetic sheet 140 . ) is less than the minimum value of the set range, and the magnetic field of the second radiation pattern 113 is not sufficiently formed in the lower part of the combo antenna module 100 due to the stagnation of the magnetic field, so the second radiation pattern The antenna performance of (113) (eg, MST communication performance) is deteriorated.

Accordingly, the second separation interval GW2 of the lower magnetic sheet 130 and the extended magnetic sheet 140 is formed to have an interval within a set range according to the antenna characteristics required by the mobile terminal.

At this time, as an example, the setting range is 2 mm or more and 8 mm or less. The setting range may be set as a relative length with the antenna sheet 110 , and in this case, it may be set to 5% or more and 20% or less of the length of the antenna sheet 110 . Here, the length of the antenna sheet 110 is the length of the region where the radiation pattern is formed in the antenna sheet 110 , which is the shortest distance between the first side S11 and the second side S12 of the base sheet 111 . take as an example

The setting range may be set as a relative length with the base sheet 111 , and in this case, it may be set to 5% or more and 20% or less of the length of the base sheet 111 . Here, the length of the antenna sheet 110 (or the length of the base sheet 111 ) may be a length in a direction perpendicular to the first side S11 and the second side S12 .

The lower magnetic sheet 130 and the extended magnetic sheet 140 may be formed to have the same second spacing GW2 at both sides of the first protruding region 122 or the concave groove 132 . That is, in the lower magnetic sheet 130 and the extended magnetic sheet 140 , the second separation interval GW2 in the direction of the third side S13 of the base sheet 111 is the second separation interval in the direction of the fourth side S14 of the base sheet 111 . It may be arranged to be the same as (GW2).

On the other hand, it is assumed that the second separation interval GW2 is the same interval as the first separation interval GW1 that is the interval between the upper magnetic sheet 120 and the lower magnetic sheet 130 . The first separation interval GW1 and the second separation interval GW2 may be within a set range and may be different from each other.

Referring to FIG. 13 , one of the plurality of radiation patterns included in the antenna sheet 110 is a first separation area GA1 between the upper magnetic sheet 120 and the lower magnetic sheet 130 and/or the lower magnetic sheet. It is exposed through the first separation area GA1 between the 130 and the expanded magnetic sheet 140 .

That is, among the first refraction portions R1 to fourth refraction portions R4 of the third radiation pattern 114 , the first refraction portion R1 and the second refraction portion R1 and the second refraction portion R1 positioned in the region facing the second radiation pattern 113 . The refractive portion R2 is exposed through the first separation area GA1 and/or the second separation area GA2 .

Through this, the combo antenna module 100 may increase the intensity of the magnetic field generated in the third radiation pattern 114 to improve antenna performance (ie, MST performance) of the third radiation pattern 114 .

On the other hand, when the third radiation pattern 114 is not exposed through the first spaced area GA1 and/or the second spaced area GA2 , the combo antenna module 100 is generated from the third radiation pattern 114 . The intensity of the magnetic field is decreased, so that the antenna performance (ie, MST performance) of the third radiation pattern 114 is deteriorated.

Accordingly, the combo antenna module 100 is configured such that a portion of the third radiation pattern 114 is exposed through the first spaced area GA1 and/or the second spaced area GA2 .

14 and 15 , in the conventional portable terminal, the connector cable 12 and the display module 13 are disposed on the battery 11 . At this time, since the magnetic sheet 16 and the battery 11 of the combo antenna module shield the magnetic field (magnetic field), the connector cable 12 is the TX magnetic field generated in the wireless power transmission module 20 during wireless power transmission. not affected

Recently, as the thickness of the portable terminal becomes thinner, the capacity of the battery 11 increases and thus the size becomes larger, and the connector cable 12 is mainly disposed under the battery 11 . The magnetic sheet 16 of the Gombo antenna module overlaps only the antenna sheet 17 , and the battery 11 is disposed at the lower end of the connector cable 12 .

Accordingly, the connector cable 12 is exposed in the direction of the wireless power transmission module 20 as it is, and noise is generated under the influence of the TX magnetic field generated in the wireless power transmission module 20 during wireless power transmission. Various problems occur in the display module 13 due to noise of the connector cable 12 . For example, when the connector cable 12 is a cable for connecting the display module 13 such as FRC or C2C and the main circuit, flicker occurs on the display module 13 due to noise generated in the connector cable 12 . phenomenon occurs.

Accordingly, referring to FIGS. 16 and 17 , the portable terminal according to the first embodiment of the present invention expands the upper magnetic sheets 120 and 140 of the combo antenna module 100 to extend the upper portion of the connector cable 220 ( That is, in the direction of the wireless power transmission module 20).

The mobile terminal includes a battery 210 , a display module 230 disposed above the battery 210 , a connector cable 220 disposed under the battery 210 , and a combo antenna module disposed under the battery 210 . (100).

The combo antenna module 100 is disposed under the battery 210 and includes an upper magnetic sheet 120 having an extended area, a lower magnetic sheet 130 and an extended magnetic sheet 140 .

At this time, as the extended magnetic sheet 140 is disposed on the upper surface of the upper magnetic sheet 120 , it is bent in the extended areas during the mounting process of the combo antenna module 100 and is disposed under the connector cable 220 .

As the combo antenna module 100 is mounted, the first extended area 136 and the second extended area 138 and the expanded magnetic sheet 140 of the lower magnetic sheet 130 among the magnetic sheets of the combo antenna module 100 . ) of the third extended area 144 and the fourth extended area 145 are disposed on the top of the connector cable 220 .

The upper magnetic sheet 120 of the combo antenna module 100 is disposed on the upper surface of the antenna sheet 110 to shield only the antenna sheet 110 area, and the extended magnetic sheet 140 is on the upper surface of the upper magnetic sheet 120 . It is disposed to shield the area of the antenna sheet 110 and the connector cable 220 .

Accordingly, the extended areas disposed under the connector cable 220 shield the TX magnetic field generated during wireless power transmission, and the connector cable 220 does not generate noise due to the TX magnetic field.

Meanwhile, referring to FIG. 18 , the extended magnetic sheet 140 may be interposed between the upper magnetic sheet 120 and the antenna sheet 110 . That is, the upper magnetic sheet 120 is mounted on the lower surface of the battery 210 , and is interposed between the two connector cables 220 . The extended magnetic sheet 140 is interposed between the upper magnetic sheet 120 and the antenna sheet 110 and is disposed under the connector cables 220 without being bent during the mounting process.

As such, the mobile terminal according to the first embodiment of the present invention extends the magnetic sheet of the combo antenna module 100 and arranges it under the connector cable 220, so that the connector cable ( 220) can be prevented from generating noise.

In addition, the portable terminal according to the first embodiment of the present invention extends the magnetic sheet of the combo antenna module 100 and arranges it under the connector cable 220 by the TX magnetic field generated during wireless power transmission to the connector cable 220 ), it is possible to prevent a flicker phenomenon occurring due to noise of the connector cable 220, and the like.

19 shows the results of testing the MST antenna performance of the portable terminal having the combo antenna module according to the first embodiment of the present invention.

First, the MST antenna performance test environment is described. The mobile terminal and the reader on which the combo antenna module 100 is mounted are center-aligned, and the mobile terminal is arranged to be spaced apart from the upper part of the reader by about 2 cm. While the mobile terminal is moved by 1 cm along the X and Y axes, it is tested whether the MST communication between the mobile terminal and the reader is successful. In this case, the MST antenna performance test is performed on the entire area of the mobile terminal, and the ratio of the MST communication success area compared to the total area is defined as the recognition rate.

When the combo antenna module is disposed to have a separation distance GW within a set range between the upper magnetic sheet 120 and the lower magnetic sheet 130 without including the expanded magnetic sheet 140 having an extended area, MST According to the antenna performance test result, the mobile terminal has a recognition rate of about 50.33%.

According to the MST antenna performance test result, when the extended magnetic sheet 140 having an extended area is included and the extended magnetic sheet 140 and the lower magnetic sheet 130 are disposed to have a separation distance GW within a set range. The mobile terminal has a recognition rate of about 54.90%.

As such, the combo antenna module 100 arranges the extended magnetic sheet 140 having an extended area on the upper surface or the lower surface of the upper magnetic sheet 120, so that the mobile terminal prevents noise generation of the connector cable while preventing the MST of the mobile terminal. Communication performance is improved.

20 shows a performance test result of an NFC antenna operating in a card mode. Here, FIG. 20 is a test result for ACM1252, which is a type of NFC reader, and in the case of load modulation, the height of the mobile terminal (that is, the distance between the mobile terminal and the reader) is 0cm, 1cm, 2cm, 3cm. This is the test result in

When including a combo antenna module disposed to have a separation distance GW within a set range between the upper magnetic sheet 120 and the lower magnetic sheet 130 without including the extended magnetic sheet 140 having an extended area, NFC According to the card mode test result, the mobile terminal has a recognition distance of about 68 mm.

According to the NFC card mode test result, when the extended magnetic sheet 140 is included and the extended magnetic sheet 140 and the lower magnetic sheet 130 are disposed to have a separation distance GW within a set range. The mobile terminal has a recognition distance of about 70 mm.

As described above, in the portable terminal having the combo antenna module according to the first embodiment of the present invention, as the extended magnetic sheet 140 having an extended area is disposed on the upper surface or the lower surface of the upper magnetic sheet 120, the portable terminal is connected to the connector It is possible to prevent the generation of noise in the cable and satisfy the recognition distance characteristic of the MST frequency band required by the mobile terminal even though the size is small.

The mobile terminal does not include an extended magnetic sheet 140 having an extended area, but a combo antenna module disposed to have a separation distance GW within a set range between the upper magnetic sheet 120 and the lower magnetic sheet 130. do. When the mobile terminal is disposed on the top of the reader without a gap, the mobile terminal has a load modulation characteristic of about 37.55 mV, which exceeds the reference value of 8.8 mV. When the mobile terminal is spaced apart from the upper part of the reader by about 1 cm, the mobile terminal has a load modulation characteristic of about 20.59 mV, which exceeds the reference value of 7.2 mV. When the mobile terminal is separated by about 2 cm from the upper part of the reader, the mobile terminal has a load modulation characteristic of about 24.11 mV, which exceeds the reference value of 5.6 mV. When the mobile terminal is spaced apart by about 3 cm from the top of the reader, the mobile terminal has a load modulation characteristic of about 23.62 mV, which exceeds the reference value of 4.0 mV. Next, it includes an extended magnetic sheet 140 having an extended area, and a combo antenna module arranged to have a separation distance GW within a set range between the extended magnetic sheet 140 and the lower magnetic sheet 130. .

When the mobile terminal is disposed on the top of the reader without a gap, the mobile terminal has a load modulation characteristic of about 38.69 mV, which exceeds the reference value of 8.8 mV. When the mobile terminal is spaced apart by about 1 cm from the top of the reader, the mobile terminal has a load modulation characteristic of about 20.83 mV, which exceeds the reference value of 7.2 mV. When the mobile terminal is separated by about 2 cm from the upper part of the reader, the mobile terminal has a load modulation characteristic of about 25.19 mV, which exceeds the reference value of 5.6 mV. When the mobile terminal is spaced apart from the upper part of the reader by about 3 cm, the mobile terminal has a load modulation characteristic of about 23.86 mV, which exceeds the reference value of 4.0 mV.

In this way, the portable terminal having the combo antenna module according to the first embodiment of the present invention forms a spacing between the lower magnetic sheet and the extended magnetic sheet, and by expanding the expanded magnetic sheet, the portable terminal generates noise of the connector cable and can satisfy the recognition distance and load modulation characteristics of the NFC frequency band required by the mobile terminal even though the size is small.

21 shows the results of testing the recognition distance of the NFC antenna operating in the reader mode. Here, in FIG. 21, Type1, Type2, Type4, Type4 small. TypeB and TypeF are standard names defined in the NFC forum, and Topaz, Ultra light, NTAG203, ULC, Desfire EV1, TecTiles, NETS Flash, Process_16.0, and OCTOPUS at the bottom are commercial tags that operate with the corresponding Type, respectively.

When the combo antenna module is disposed to have a separation distance GW within a set range between the upper magnetic sheet 120 and the lower magnetic sheet 130 without including the expanded magnetic sheet 140 having an extended area, According to the NFC reader mode test results, the mobile terminal is approximately 33mm in Type1, approximately 41mm, 32mm, and 18mm depending on the product in Type2, approximately 19mm in Type4, and approximately 19mm in Type4 small. Type B has a recognition distance of about 15 mm or 16 mm depending on the product, and Type F has a recognition distance of about 30 mm.

When the combo antenna module is disposed to have a separation distance GW within a set range between the upper magnetic sheet 120 and the lower magnetic sheet 130 without including the expanded magnetic sheet 140 having an extended area, According to the NFC reader mode test result, the mobile terminal is about 34mm in Type1, about 42mm, 35mm, and 20mm depending on the product in Type2, about 21mm in Type4, and about 21mm in Type4 small. Type B has a recognition distance of about 15 mm or 17 mm depending on the product, and Type F has a recognition distance of about 31 mm.

In this way, the portable terminal having the combo antenna module according to the first embodiment of the present invention forms a spacing between the lower magnetic sheet and the extended magnetic sheet, and by expanding the expanded magnetic sheet, the portable terminal generates noise of the connector cable and can satisfy the recognition distance characteristic of the NFC reader mode required in the mobile terminal even though the size is small.

Meanwhile, referring to FIGS. 22 and 23 , the wireless power transmission module 20 forms a TX magnetic field in the process of performing wireless power for wireless charging of the mobile terminal.

The TX magnetic field is mostly shielded by the magnetic sheets of the combo antenna module 100 . In the combo antenna module 100 according to the first embodiment of the present invention, the connector cable 220 is connected to the wireless power transmission module 20 through the separation area GA2 between the extended magnetic sheet 140 and the lower magnetic sheet 130 . ) is exposed in the direction Here, exposure means that the magnetic field (electromagnetic waves) is not shielded.

Accordingly, a portion of the TX magnetic field is introduced into the connector cable 220 through the separation area GA2. The connector cable 220 generates fine noise due to the introduced TX magnetic field, and in the display module, the flicker phenomenon occurs finely due to the fine noise generated from the connector cable 220 .

Accordingly, the combo antenna module and the mobile terminal having the same according to the second embodiment of the present invention block the inflow of the TX magnetic field through the separation area GA2 by disposing the metal sheet 150, and through this, the fine display module Prevents flickering.

24, the combo antenna module 100 according to the second embodiment of the present invention includes an antenna sheet 110 on which a plurality of radiation patterns are formed, an upper magnetic sheet 120 disposed on the upper surface of the antenna sheet 110, The lower magnetic sheet 130 disposed on the lower surface of the antenna sheet 110 , the expanded magnetic sheet 140 disposed on the upper surface of the upper magnetic sheet 120 , and the metal sheet 150 disposed on the upper surface of the expanded magnetic sheet 140 . ) is included. Here, the antenna sheet 110 , the upper magnetic sheet 120 , the lower magnetic sheet 130 , and the extended magnetic sheet 140 are the same as those of the above-described first embodiment, so the same reference numerals are assigned to them, and overlapping descriptions are omitted. do it with

As an example, the metal sheet 150 is a conductive sheet, and is a thin metal sheet 150 made of copper (Cu). The metal sheet 150 may be made of any conductive material capable of blocking (shielding) electromagnetic waves (magnetic field) in addition to copper.

However, since the magnetic material may affect the antenna performance of the radiation patterns because electromagnetic waves (magnetic field) flow, the metal sheet 150 is preferably made of a non-magnetic material.

The metal sheet 150 is disposed on the upper surface of the extended magnetic sheet 140 to block the inflow of electromagnetic waves. That is, the metal sheet 150 is the TX magnetic field generated by the wireless power transmission module 20 during wireless power transmission. block the inflow.

Here, referring to FIGS. 25 and 26 , the area of the metal sheet 150 is formed wider than the area of the expanded magnetic sheet 140 to overlap the entire area of the expanded magnetic sheet 140 , and the lower magnetic sheet 130 . may overlap with a part of The metal sheet 150 may overlap a portion of the expanded magnetic sheet 140 , and may overlap the entire lower magnetic sheet 130 . In this case, the metal sheet 150 is essentially disposed in the separation area GA2 between the expanded magnetic sheet 140 and the lower magnetic sheet 130 .

Here, a plurality of metal sheets 150 may be separately formed to be respectively disposed in the separation areas GA2 between the expanded magnetic sheet 140 and the lower magnetic sheet 130 . However, the metal sheet 150 is composed of one sheet to facilitate the manufacturing and assembly process.

Referring to FIG. 27 , the combo antenna module 100 is disposed below the battery when mounted on the portable terminal. Accordingly, the metal sheet 150 is interposed between the battery and the expanded magnetic sheet 140 , and between the connector cable 220 and the expanded magnetic sheet 140 . In this case, the metal sheet 150 may be bent at a position where a step difference occurs between the battery and the connector cable 220 in the process of mounting the combo antenna module 100 on the portable terminal.

Referring to FIG. 28 , the metal sheet 150 is disposed in the separation areas GA2 between the extended magnetic sheet 140 and the lower magnetic sheet 130 so that a magnetic field (electromagnetic wave) flows into the connector cable 220 . block it from being That is, the metal sheet 150 is disposed in the separation area GA2 to block (shield) the fine TX magnetic field flowing into the connector cable 220 through the separation area GA2 .

Through this, the mobile terminal provided with the combo antenna module 100 prevents the generation of fine noise of the connector cable 220, and thereby prevents the fine flicker phenomenon of the display module. Meanwhile, the metal sheet 150 may absorb and radiate heat generated from the combo antenna module 100 in addition to electromagnetic wave shielding.

29 shows the results of testing the MST antenna performance of the portable terminal having the combo antenna module 100 according to the second embodiment of the present invention.

First, the MST antenna performance test environment is described. The mobile terminal and the reader on which the combo antenna module 100 is mounted are center-aligned, and the mobile terminal is arranged to be spaced apart by about 2 cm above the reader. While the mobile terminal is moved by 1 cm along the X and Y axes, it is tested whether the MST communication between the mobile terminal and the reader is successful. In this case, the MST antenna performance test is performed on the entire area of the mobile terminal, and the ratio of the MST communication success area compared to the total area is defined as the recognition rate.

As a result of the MST antenna performance test, mobile terminals having the combo antenna module 100 of the first embodiment of the present invention have a recognition rate of about 54.90%, and having the combo antenna module 100 of the second embodiment of the present invention. Mobile terminals have a recognition rate of about 54.90%.

As such, the combo antenna module and the portable terminal having the same according to the second embodiment of the present invention are provided by disposing the metal sheet 150 in the spaced area GA2 between the extended magnetic sheet 140 and the lower magnetic sheet 130 . , it is possible to prevent the generation of fine noise of the connector cable 220 to improve the fine flicker phenomenon of the display module while maintaining the MST antenna performance at the same level as that of the combo antenna module according to the first embodiment and the portable terminal having the same.

30 shows a performance test result of an NFC antenna operating in a card mode. Here, FIG. 30 is a test result for ACM1252, which is a type of NFC reader, and in the case of load modulation, the height of the mobile terminal (that is, the distance between the mobile terminal and the reader) is 0 cm, 1 cm, 2 cm, 3 cm. This is the test result in

As a result of the NFC card mode test, the mobile terminal having the combo antenna module 100 according to the first embodiment of the present invention has a recognition distance of about 70 mm, and the combo antenna module 100 according to the second embodiment of the present invention. ) provided with a mobile terminal has a recognition distance of about 70mm.

As such, the combo antenna module and the portable terminal having the same according to the second embodiment of the present invention are provided by disposing the metal sheet 150 in the spaced area GA2 between the extended magnetic sheet 140 and the lower magnetic sheet 130 . , It is possible to maintain the recognition distance performance of the NFC antenna equivalent to that of the combo antenna module according to the first embodiment and the mobile terminal having the same while improving the fine flicker phenomenon of the display module by preventing the occurrence of fine noise of the connector cable 220 there is.

In addition, the combo antenna module and the mobile terminal having the same according to the second embodiment of the present invention are measured at the same level as the combo antenna module according to the first embodiment and the mobile terminal having the same in the load modulation test result, and all tests In the item, it satisfies the load modulation standard required by the mobile terminal.

In addition, referring to FIG. 31 , the combo antenna module according to the second embodiment of the present invention and the mobile terminal having the same are the combo antenna module according to the first embodiment and the portable terminal having the same in the NFC reader mode recognition distance test result. It is measured at the same level as the terminal and satisfies the recognition distance standard required by the mobile terminal in all test items.

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

100: combo antenna module 110: antenna sheet
111: base sheet 112: first radiation pattern
113: second radiation pattern 114: third radiation pattern
120: upper magnetic sheet 130: lower magnetic sheet
140: extended magnetic sheet 150: metal sheet

Claims (12)

battery;
a combo antenna module disposed under the battery; and
and a connector cable disposed adjacent to the combo antenna module,
The combo antenna module is
a lower magnetic sheet disposed under the battery;
an extended magnetic sheet disposed under the battery; and
and a metal sheet disposed on the expanded magnetic sheet and disposed in a spaced region between the lower magnetic sheet and the expanded magnetic sheet. According to claim 1,
The metal sheet is a conductive sheet of a mobile terminal. According to claim 1,
The metal sheet overlaps a portion of the lower magnetic sheet and a portion of the expanded magnetic sheet. According to claim 1,
The metal sheet is bent in a step region between the battery and the connector cable. According to claim 1,
The lower magnetic sheet and the extended magnetic sheet are spaced apart from the lower portion of the connector cable to have a spacing within a set range to form a separation region. An antenna sheet having a plurality of radiation patterns formed thereon;
an expanded magnetic sheet disposed on the antenna sheet;
a lower magnetic sheet disposed under the antenna sheet; and
A combo antenna module including a metal sheet disposed on the expanded magnetic sheet and overlapping a spaced region between the lower magnetic sheet and the expanded magnetic sheet. 7. The method of claim 6,
The metal sheet is a conductive sheet combo antenna module. 7. The method of claim 6,
wherein the metal sheet overlaps a portion of the lower magnetic sheet and a portion of the expanded magnetic sheet. 7. The method of claim 6,
The lower magnetic sheet and the extended magnetic sheet are spaced apart to have a spaced distance within a set range to form a spaced area. 10. The method of claim 9,
The set range is 5% or more and 15% or less of the length of the antenna sheet, and the antenna sheet length is a length in a direction perpendicular to the first side and the second side of the antenna sheet. 7. The method of claim 6,
One of the plurality of radiation patterns is exposed through a spaced area between the extended magnetic sheet and the lower magnetic sheet. 7. The method of claim 6,
The combo antenna module further comprising an upper magnetic sheet interposed between the antenna sheet and the expanded magnetic sheet.

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