KR102314729B1 - Multi layer antenna module - Google Patents

Abstract

Laminated sheets having radiation patterns formed on the upper and lower surfaces of the shielding sheet are stacked, respectively, and radiation patterns are connected through via holes formed in at least one of the shielding sheet and the stacked sheets to form an antenna pattern in the vertical direction of the electromagnetic wave shielding sheet. An antenna module is presented. The proposed laminated antenna module includes a lower laminated sheet having a first radiation pattern formed thereon, an electromagnetic wave shielding sheet laminated on top of the lower laminated sheet, an upper laminated sheet and a lower laminated sheet having a second radiation pattern formed and stacked on top of the electromagnetic wave shielding sheet , It includes a connection portion for connecting the first radiation pattern and the second radiation pattern through the electromagnetic wave shielding sheet and the upper laminated sheet.

Description

Stacked antenna module {MULTI LAYER ANTENNA MODULE}

The present invention relates to a stacked antenna module, and more particularly, to a stacked antenna module embedded in a mobile terminal to perform short-distance communication or electronic payment (eg, Samsung Pay, etc.).

With the development of technology, mobile terminals such as mobile phones, PDAs, PMPs, navigation devices, and laptops have provided basic functions such as calls, video/music playback, directions, etc. Additional functions are provided. Accordingly, the mobile terminal is provided with a plurality of antennas for wireless communication such as wireless Internet and Bluetooth.

In addition, in recent years, there is a trend to apply functions such as information exchange, payment, ticket reservation, and search between terminals using short-distance communication (ie, NFC, Magnetic Secure Transmission (MST)) to portable terminals. To this end, the portable terminal is equipped with an antenna module for a portable terminal (ie, an NFC antenna module) used in a short-range communication method. At this time, the NFC antenna module used is a contactless short-range wireless communication module using a frequency band of about 13.56 MHz as one of the RFID tags, and transmits data between terminals at a short distance of about 10 cm. NFC is widely used not only for payment, but also for product information or travel information transmission for visitors in supermarkets and general stores, transportation, and access control locks.

In recent years, the application of metal covers (hereinafter referred to as metal covers) to mobile terminals such as tablets and smart phones has been increasing. At this time, as shown in FIG. 1 , when the entire rear cover 11 of the mobile terminal is made of a metal material, it is difficult to implement the performance of the NFC antenna 13 mounted on the mobile terminal body 12 . Accordingly, research for implementing the performance of the NFC antenna is in progress.

For example, as shown in FIG. 2 , in the related art, a slit 22 (Slit, or opening) is formed in the metal cover to implement the performance of the NFC antenna in the mobile terminal 20 to which the metal cover 21 is applied, and the slit Mount the NFC antenna so that it partially overlaps with (22). Accordingly, the performance of the NFC antenna can be realized through a coupling effect between the NFC antenna and the metal cover through the slit 22 .

However, when the slit or the opening is formed to implement the performance of the NFC antenna, the manufacturing process of the mobile terminal becomes complicated, which increases the manufacturing cost, and there is a problem in that the slit or the opening must be reflected in the exterior design.

On the other hand, as shown in FIG. 3 , as the user environment of the portable terminal is diversified in recent years, short-distance communication is possible not only in the plane direction (ie, the rear surface of the portable terminal) but also in the vertical direction (ie, the side surface of the portable terminal). user demand is increasing.

However, as shown in FIG. 4 , since the conventional NFC antenna 30 is formed in the form of winding the coil pattern 32 on the upper surface of the ferrite sheet 31 , it is difficult to implement the antenna performance in the vertical direction. There is this.

Korean Patent Application Laid-Open No. 10-2009-0126323 (Name: NFC module, especially NFC module for mobile phone) Korean Patent Registration No. 10-1098263 (Name: NFC Loop Antenna)

The present invention has been proposed to solve the above-mentioned problems in the prior art, stacking laminated sheets having radiation patterns on the upper and lower surfaces of the shielding sheet, respectively, and generating radiation patterns through via holes formed in at least one of the shielding sheet and the laminated sheets. An object of the present invention is to provide a laminated antenna module that is connected to form an antenna pattern in the vertical direction of the electromagnetic wave shielding sheet.

In order to achieve the above object, a laminated antenna module according to an embodiment of the present invention includes a lower laminated sheet having a first radiation pattern formed thereon, an electromagnetic wave shielding sheet stacked on the lower laminated sheet, a second radiation pattern is formed, and electromagnetic wave shielding and a connection part for connecting the first radiation pattern and the second radiation pattern through the upper laminated sheet and the lower laminated sheet, the electromagnetic wave shielding sheet, and the upper laminated sheet stacked on top of the sheet.

The connection part is formed through one side of the lower laminated sheet, the electromagnetic wave shielding sheet, and the upper laminated sheet, and is formed through a first via hole connecting the first radiation pattern and the second radiation pattern and the other side of the lower laminated sheet and the upper laminated sheet and may include a second via hole connecting the first radiation pattern and the second radiation pattern.

The connection unit may connect the first radiation pattern and the second radiation pattern to form an antenna pattern in a vertical direction of the electromagnetic wave shielding sheet.

The lower laminated sheet is composed of a first adhesive sheet, the upper surface of which is adhered to the lower surface of the electromagnetic wave shielding sheet, and a plurality of radiation lines spaced apart from each other, and a first radiation pattern coupled to the lower surface of the first adhesive sheet, the first radiation pattern A first polyimide sheet coupled to a lower surface, a plurality of radiation lines and a plurality of terminals disposed one-to-one correspondingly, a first terminal portion coupled to one lower surface side of the first polyimide sheet, a plurality of radiation lines, Consisting of a plurality of terminals arranged in a one-to-one correspondence, the second terminal portion coupled to the other side of the lower surface of the first polyimide sheet, the first terminal portion, the second terminal portion, and the lower protection coupled to the lower surface of the first polyimide sheet The sheet and one surface may include a second adhesive sheet attached to the lower surface of the lower protective sheet and the other surface attached to the rear cover or main body of the mobile terminal.

The upper laminated sheet consists of a third adhesive sheet adhered to the upper surface of the electromagnetic wave shielding sheet, a plurality of radiation lines spaced apart from each other, and a second radiation pattern coupled to the upper surface of the third adhesive sheet, the second radiation pattern on the upper surface A second polyimide sheet coupled thereto, a third terminal portion comprising a plurality of terminals disposed in a one-to-one correspondence with a plurality of radiation lines, a third terminal portion coupled to one side of the upper surface of the second polyimide sheet, and a plurality of radiation lines and one-to-one A fourth terminal portion and a third terminal portion, the fourth terminal portion, and an upper protective sheet consisting of a plurality of terminals disposed to correspond to one another, coupled to the other side of the upper surface of the second polyimide sheet, and coupled to the upper surface of the second polyimide sheet may include

The electromagnetic wave shielding sheet may be formed in the same area and shape as the lower laminated sheet and the upper laminated sheet.

In order to achieve the above object, a laminated antenna module according to another embodiment of the present invention includes a lower laminated sheet on which a first radiation pattern is formed, an electromagnetic wave shielding sheet stacked on top of the lower laminated sheet, a second radiation pattern is formed, and electromagnetic waves and a connection part for connecting the first radiation pattern and the second radiation pattern through the upper laminated sheet and the electromagnetic wave shielding sheet stacked on top of the shielding sheet.

The connection part is formed through one side of the electromagnetic wave shielding sheet, the first via hole connecting the first radiation pattern and the second radiation pattern, and the other side of the electromagnetic shielding sheet, the first radiation pattern and the second radiation pattern A second via hole for connecting may be included.

The connection unit may connect the first radiation pattern and the second radiation pattern to form an antenna pattern in a vertical direction of the electromagnetic wave shielding sheet.

The lower laminated sheet includes a first radiation pattern comprising a plurality of radiation lines spaced apart from each other, a first polyimide sheet coupled to a lower surface of the first radiation pattern, a lower protective sheet coupled to a lower surface of the first polyimide sheet, and one surface It may include a first adhesive sheet attached to the lower surface of the lower protective sheet, the other surface is attached to the rear cover or main body of the mobile terminal.

The electromagnetic wave shielding sheet includes a second adhesive sheet having a lower surface adhered to the lower laminated sheet, a shielding sheet adhered to the upper surface of the second adhesive sheet, and a third adhesive having a lower surface adhered to the shielding sheet and an upper surface adhered to the lower surface of the upper laminated sheet It may also include sheets.

The upper laminated sheet consists of a plurality of radiation lines spaced apart from each other, a second radiation pattern coupled to the upper surface of the electromagnetic wave shielding sheet, a second polyimide sheet coupled to the upper surface of the second radiation pattern, and a plurality of radiation lines and one Consists of a plurality of terminals arranged in a one-to-one correspondence, a first terminal portion coupled to one side of the upper surface of the second polyimide sheet, and a plurality of terminals arranged in one-to-one correspondence with a plurality of radiation lines, the second It may include a second terminal portion coupled to the other side of the upper surface of the polyimide sheet, the first terminal portion, the second terminal portion, and an upper protective sheet coupled to the upper surface of the second polyimide sheet.

The electromagnetic wave shielding sheet may be formed in the same area and shape as the lower laminated sheet and the upper laminated sheet.

According to the present invention, the laminated antenna module stacks the laminated sheets having the radiation pattern on the upper and lower surfaces of the shielding sheet, respectively, and connects the radiation patterns through the via hole formed in at least one of the shielding sheet and the laminated sheet to form the electromagnetic wave shielding sheet vertically. By forming the antenna pattern in the direction, it is possible to implement the NFC antenna performance and the MST (Magnetic Secure Transmission) antenna performance required as a standard in a mobile terminal to which a metal cover is applied. It has the effect of implementing an antenna performance equal to or higher than that of the NFC antenna module and the MST antenna module.

In addition, the laminated antenna module laminates the laminated sheets having the radiation pattern on the upper and lower surfaces of the shielding sheet, respectively, and connects the radiation patterns through a via hole formed in at least one of the shielding sheet and the laminated sheet to the antenna in the vertical direction of the electromagnetic wave shielding sheet. By forming the pattern, there is an effect that can implement NFC antenna performance and MST antenna performance in the vertical direction (ie, the side of the mobile terminal) as well as in the plane direction (ie, the rear surface of the mobile terminal).

In addition, the laminated antenna module laminates the laminated sheets having the radiation pattern on the upper and lower surfaces of the shielding sheet, respectively, and connects the radiation patterns through a via hole formed in at least one of the shielding sheet and the laminated sheet to the antenna in the vertical direction of the electromagnetic wave shielding sheet. By forming the pattern, there is an effect that can minimize the deviation of the NFC antenna performance and the MST antenna performance depending on the angle.

In addition, the laminated antenna module laminates the laminated sheets having the radiation pattern on the upper and lower surfaces of the shielding sheet, respectively, and connects the radiation patterns through a via hole formed in at least one of the shielding sheet and the laminated sheet to the antenna in the vertical direction of the electromagnetic wave shielding sheet. By forming the pattern, it is possible to implement more than the minimum standard antenna (ie, NFC antenna, MST antenna) characteristics for performing NFC communication on the side and back of the mobile terminal, and maintain antenna performance equal to or greater than that of the case mounted on a non-metallic cover. can have an effect.

In addition, the stacked antenna module arranges a shielding sheet having the same area and shape as the stacked sheet on which the radiation pattern is formed between the stacked sheets, and connects the radiation patterns through the via holes formed in the shielding sheet, thereby forming the stacked antenna module. Since the outermost surface can be used as a radiation pattern forming area, an open area (ie, an area in which a radiation pattern cannot be formed) can be minimized.

In addition, the stacked antenna module maximizes the radiation pattern formation area and minimizes the open area, thereby increasing the area (or length) of the radiation pattern to maximize antenna performance.

1 to 4 are views for explaining a conventional NFC antenna module.
5 is a view for explaining a stacked antenna module according to the first embodiment of the present invention.
6 and 7 are views for explaining the lower laminated sheet of FIG.
8 and 9 are views for explaining the upper laminated sheet of FIG.
FIG. 10 is a view for explaining the connection part of FIG. 5;
11 and 12 are views for explaining the antenna characteristics of the stacked antenna module according to the first embodiment of the present invention.
13 is a view for explaining the lower laminated sheet of the laminated antenna module according to the second embodiment of the present invention.
14 is a view for explaining the electromagnetic wave shielding sheet of the stacked antenna module according to the second embodiment of the present invention.
15 is a view for explaining the upper laminated sheet of the laminated antenna module according to the second embodiment of the present invention.
16 is a view for explaining the connection part of the electromagnetic wave shielding sheet of the stacked antenna module according to the second embodiment of the present invention.

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

Hereinafter, the stacked antenna module according to the first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 5 , the stacked antenna module 100 is configured to include a lower stacked sheet 110 , an electromagnetic wave shielding sheet 120 , an upper stacked sheet 130 , and a connection unit 140 . In this case, the lower laminated sheet 110 , the electromagnetic wave shielding sheet 120 , and the upper laminated sheet 130 are formed to have the same shape and area. Here, the stacked antenna module 100 operates as an NFC antenna for short-range communication or a Magnetic Secure Transmission (MST) antenna for electronic payment.

The lower laminated sheet 110 is formed of a flexible circuit board and is attached to the rear cover (metal cover) of the mobile terminal or the rear body of the mobile terminal. At this time, as shown in Figure 6, the lower laminated sheet 110 is formed with a first radiation pattern 112 consisting of a plurality of radiation lines spaced apart from each other.

Referring to FIG. 7 , when describing the cut surface (based on AA' in FIG. 6 ), the lower laminated sheet 110 is a first adhesive sheet 111 , a first radiation pattern 112 , and a first polyimide sheet ( 113 ), a first terminal portion 114 , a second terminal portion 115 , a lower protective sheet 116 , and a second adhesive sheet 117 .

The first adhesive sheet 111 is adhered to the lower surface of the shielding sheet. That is, the first adhesive sheet 111 is formed of an adhesive material generally used for the construction of the flexible circuit board, and the upper surface is adhered to the lower surface of the shielding sheet.

The first radiation pattern 112 is coupled to the lower surface of the first adhesive sheet 111 . In this case, the first radiation pattern 112 includes a plurality of radiation lines formed of a copper material and spaced apart from each other by a predetermined distance. The first radiation pattern 112 has an upper surface coupled to a lower surface of the first adhesive sheet 111 .

The first polyimide sheet 113 is coupled to the lower surface of the first radiation pattern 112 . That is, the upper surface of the first polyimide sheet 113 is coupled to the lower surface of the first radiation pattern 112 .

The first terminal part 114 is configured to include a plurality of terminals formed of a copper material. The first terminal part 114 is coupled to one side of the lower surface of the first polyimide sheet 113 . In this case, the plurality of terminals included in the first terminal unit 114 are disposed to correspond to a plurality of radiation lines constituting the first radiation pattern 112 in one-to-one correspondence.

The second terminal part 115 includes a plurality of terminals formed of a copper material. The second terminal part 115 is coupled to the other side of the lower surface of the first polyimide sheet 113 . That is, the second terminal part 115 is coupled to the lower surface of the first polyimide sheet 113 in the same manner as the first terminal part 114 . The second terminal part 115 is coupled to the other side opposite to the one side to which the first terminal part 114 is coupled. In this case, the plurality of terminals included in the second terminal unit 115 are disposed to correspond to the plurality of radiation lines constituting the first radiation pattern 112 in one-to-one correspondence.

The lower protective sheet 116 is coupled to the lower surface of the first terminal part 114 , the second terminal part 115 , and the first polyimide sheet 113 . In this case, the lower protective sheet 116 refers to a coverlay generally used for a flexible printed circuit board.

The second adhesive sheet 117 is attached to the rear cover of the mobile terminal or the rear of the main body. That is, the second adhesive sheet 117 is formed of an adhesive material generally used for the construction of a flexible circuit board, and the upper surface is attached to the lower surface of the lower protective sheet 116 , and the lower surface is the rear cover or the rear surface of the body. is attached

The electromagnetic wave shielding sheet 120 is composed of a sheet of an electromagnetic wave blocking material such as a ferrite sheet. The electromagnetic wave shielding sheet 120 is formed to have the same shape and area as the lower laminated sheet 110 and the upper laminated sheet 130 . The electromagnetic wave shielding sheet 120 is laminated on the upper surface of the lower laminated sheet 110 by bonding the lower surface to the upper surface of the lower laminated sheet 110 . In this case, the electromagnetic wave shielding sheet 120 is adhered to the upper surface of the first adhesive sheet 111 and laminated on the upper surface of the lower laminated sheet 110 .

The upper laminated sheet 130 is formed of a flexible circuit board and laminated on the electromagnetic wave shielding sheet 120 . At this time, as shown in Figure 8, the upper laminated sheet 130 is formed with a second radiation pattern 132 consisting of a plurality of radiation lines spaced apart from each other. The upper laminated sheet 130 has a lower surface attached to the electromagnetic wave shielding sheet 120 and laminated on the upper surface of the electromagnetic wave shielding sheet 120 .

Referring to FIG. 9 , referring to the cut surface (based on BB' in FIG. 8 ), the upper laminated sheet 130 includes a third adhesive sheet 131 , a second radiation pattern 132 , and a second polyimide sheet ( 133), the third terminal portion 134, the fourth terminal portion 135, and is configured to include an upper protective sheet (136).

The third adhesive sheet 131 is adhered to the upper surface of the shielding sheet. That is, the third adhesive sheet 131 is formed of an adhesive material generally used for the construction of the flexible circuit board, and the lower surface is adhered to the upper surface of the shielding sheet.

The second radiation pattern 132 is coupled to the upper surface of the third adhesive sheet 131 . In this case, the second radiation pattern 132 is formed of a copper material and includes a plurality of radiation lines spaced apart from each other by a predetermined distance. The lower surface of the second radiation pattern 132 is coupled to the upper surface of the third adhesive sheet 131 .

The second polyimide sheet 133 is coupled to the upper surface of the second radiation pattern 132 . That is, the lower surface of the second polyimide sheet 133 is coupled to the upper surface of the second radiation pattern 132 .

The third terminal part 134 includes a plurality of terminals formed of a copper material. The third terminal part 134 is coupled to one side of the upper surface of the second polyimide sheet 133 . In this case, the plurality of terminals included in the third terminal part 134 are disposed to correspond to the plurality of radiation lines constituting the second radiation pattern 132 in one-to-one correspondence.

The fourth terminal part 135 is configured to include a plurality of terminals formed of a copper material. The fourth terminal part 135 is coupled to the other side of the upper surface of the second polyimide sheet 133 . That is, the fourth terminal part 135 is coupled to the lower surface of the second polyimide sheet 133 in the same manner as the third terminal part 134 . The fourth terminal part 135 is coupled to the other side opposite to the one side to which the third terminal part 134 is coupled. At this time, the plurality of terminals included in the fourth terminal part 135 are disposed to correspond to a plurality of radiation lines constituting the second radiation pattern 132 in one-to-one correspondence.

The upper protective sheet 136 is coupled to upper surfaces of the third terminal part 134 , the fourth terminal part 135 , and the second polyimide sheet 133 . In this case, the upper protective sheet 136 refers to a coverlay generally used for a flexible printed circuit board.

The connection unit 140 electrically connects the first radiation pattern 112 and the second radiation pattern 132 . That is, the connection part 140 electrically connects the first radiation pattern 112 formed on the lower laminated sheet 110 and the second radiation pattern 132 formed on the upper laminated sheet 130 .

To this end, as shown in FIG. 10 , the connection part 140 includes a first via hole 142 and a second via hole 144 .

The first via hole 142 electrically connects the first terminal part 114 , the first radiation pattern 112 , the second radiation pattern 132 , and the third terminal part 134 . That is, the first via hole 142 includes the first polyimide sheet 113 , the first radiation pattern 112 and the first adhesive sheet 111 , the electromagnetic wave shielding sheet 120 , the third adhesive sheet 131 , and the second It is formed through one side of the second radiation pattern 132 and the second polyimide sheet 133 . The first via hole 142 electrically connects the first terminal part 114 , the first radiation pattern 112 , the second radiation pattern 132 , and the third terminal part 134 through internal plating.

The second via hole 144 electrically connects the second terminal part 115 , the first radiation pattern 112 , the second radiation pattern 132 , and the fourth terminal part 135 . That is, the second via hole 144 includes the first polyimide sheet 113 , the first radiation pattern 112 and the first adhesive sheet 111 , the electromagnetic wave shielding sheet 120 , the third adhesive sheet 131 , and the second via hole 144 . The second radiation pattern 132 and the second polyimide sheet 133 are formed through the other side. The second via hole 144 electrically connects the second terminal part 115 , the first radiation pattern 112 , the second radiation pattern 132 , and the fourth terminal part 135 through internal plating.

As such, as shown in FIG. 11 , the stacked antenna module 100 connects the radiation patterns formed on the lower stacked sheet 110 and the upper stacked sheet 130 through a via hole, in the vertical direction of the electromagnetic wave shielding sheet 120 . to form a wound antenna pattern.

The stacked antenna module 100 is disposed on the rear or rear cover of the main body of the mobile terminal. At this time, as shown in FIG. 12 , although the metal rear cover performs a shielding role, a radiation field is formed in a plane direction and a vertical direction by an electromagnetic signal radiated from the side of the stacked antenna module 100 .

Accordingly, the stacked antenna module 100 may implement an antenna (ie, an NFC antenna, a Magnetic Secure Transmission (MST) antenna) characteristic of at least the minimum standard for performing NFC communication on the side and rear surfaces of the mobile terminal, and is mounted on a non-metal cover. Antenna performance equal to or higher than that of the mounted case can be maintained.

Hereinafter, a stacked antenna module according to a second embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The stacked antenna module 300 is configured to include a lower stacked sheet 310 , an electromagnetic wave shielding sheet 320 , an upper stacked sheet 330 , and a connection part 340 . In this case, the lower lamination sheet 310 , the electromagnetic wave shielding sheet 320 , and the upper lamination sheet 330 are formed to have the same shape and area.

The lower laminated sheet 310 is formed of a flexible circuit board and is attached to the rear cover (metal cover) of the mobile terminal or the rear body of the mobile terminal. A first radiation pattern 311 is formed on a lower surface of the lower laminated sheet 310 that is attached to the rear cover or the rear surface of the main body. In this case, the first radiation pattern 311 is composed of a plurality of radiation lines spaced apart from each other.

Referring to FIG. 13 , referring to the cut surface, the lower laminated sheet 310 includes a first radiation pattern 311 , a first polyimide sheet 312 , a lower protective sheet 313 , and a first adhesive sheet 314 . ) is included.

The first radiation pattern 311 is coupled to the lower surface of the electromagnetic wave shielding sheet 320 . In this case, the first radiation pattern 311 is formed of a copper material and includes a plurality of radiation lines spaced apart from each other by a predetermined distance. The upper surface of the first radiation pattern 311 is coupled to the lower surface of the electromagnetic wave shielding sheet 320 .

The first polyimide sheet 312 is coupled to the lower surface of the first radiation pattern 311 . That is, the upper surface of the first polyimide sheet 312 is coupled to the lower surface of the first radiation pattern 311 .

The lower protective sheet 313 is coupled to the lower surface of the first polyimide sheet 312 . In this case, the lower protective sheet 313 refers to a coverlay generally used for a flexible printed circuit board.

The first adhesive sheet 314 is attached to the rear cover of the mobile terminal or the rear of the main body. That is, the first adhesive sheet 314 is formed of an adhesive material generally used for the construction of a flexible circuit board, and the upper surface is attached to the lower surface of the lower protective sheet 313 , and the lower surface is the rear cover or the rear surface of the body. is attached

The electromagnetic wave shielding sheet 320 is made of a sheet made of an electromagnetic wave shielding material such as a ferrite sheet and laminated on the lower laminated sheet 310 . At this time, as shown in FIG. 14 , the electromagnetic wave shielding sheet 320 is attached to the upper surface of the second adhesive sheet 321 , the second adhesive sheet 321 , the lower surface of which is adhered to the upper surface of the lower laminated sheet 310 . The shielding sheet 322 is configured to include a third adhesive sheet 323 having a lower surface attached to the upper surface of the shielding sheet 322 and an upper surface attached to the lower surface of the upper laminated sheet 330 .

The upper laminated sheet 330 is formed of a flexible circuit board and laminated on the electromagnetic wave shielding sheet 320 . A second radiation pattern 331 including a plurality of radiation lines spaced apart from each other is formed on an upper surface of the upper laminated sheet 330 .

Referring to FIG. 15 with reference to the cut surface of the upper laminated sheet 330 , the upper laminated sheet 330 includes a second radiation pattern 331 , a second polyimide sheet 332 , a first terminal portion 333 , The second terminal portion 334 is configured to include an upper protective sheet (335).

The second radiation pattern 331 is coupled to the upper surface of the electromagnetic wave shielding sheet 320 . In this case, the second radiation pattern 331 is formed of a copper material and includes a plurality of radiation lines spaced apart from each other by a predetermined distance. The lower surface of the second radiation pattern 331 is coupled to the upper surface of the third adhesive sheet 323 .

The second polyimide sheet 332 is coupled to the upper surface of the second radiation pattern 331 . That is, the lower surface of the second polyimide sheet 332 is coupled to the upper surface of the second radiation pattern 331 .

The first terminal part 333 is configured to include a plurality of terminals formed of a copper material. The first terminal part 333 is coupled to one side of the upper surface of the second polyimide sheet 332 . In this case, the plurality of terminals included in the first terminal part 333 are disposed to correspond to the plurality of radiation lines constituting the second radiation pattern 331 in one-to-one correspondence. Here, the first terminal part 333 is connected to the second radiation pattern 331 through the via hole.

The second terminal part 334 includes a plurality of terminals formed of a copper material. The second terminal part 334 is coupled to the other side of the upper surface of the second polyimide sheet 332 . That is, the second terminal portion 334 is coupled to the lower surface of the second polyimide sheet 332 in the same manner as the first terminal portion 333 . The second terminal part 334 is coupled to the other side opposite to the one side to which the first terminal part 333 is coupled. At this time, the plurality of terminals included in the second terminal part 334 are disposed to correspond to the plurality of radiation lines constituting the second radiation pattern 331 in one-to-one correspondence. Here, the second terminal part 334 is connected to the second radiation pattern 331 through the via hole.

The upper protective sheet 335 is coupled to the upper surfaces of the first terminal part 333 , the second terminal part 334 , and the second polyimide sheet 332 . In this case, the upper protective sheet 335 refers to a coverlay generally used for a flexible printed circuit board.

The connection part 340 electrically connects the first radiation pattern 311 and the second radiation pattern 331 . That is, the connection part 340 electrically connects the first radiation pattern 311 formed on the lower stacked sheet 310 and the second radiation pattern 331 formed on the upper stacked sheet 330 .

To this end, as shown in FIG. 16 , the connection part 340 includes a first via hole 342 formed on one side of the electromagnetic wave shielding sheet 320 and a second via hole 344 formed on the other side of the electromagnetic wave shielding sheet 320 . ) is included.

The first via hole 342 is formed through one side of the second adhesive sheet 321 , the shielding sheet 322 , and the third adhesive sheet 323 . That is, the first via hole 342 electrically connects the first radiation pattern 112 and the second radiation pattern 132 through internal plating.

The second via hole 344 is formed through the other side of the second adhesive sheet 321 , the shielding sheet 322 , and the third adhesive sheet 323 . The first via hole 342 electrically connects the first radiation pattern 112 and the second radiation pattern 132 through internal plating.

As described above, the laminated antenna module stacks the laminated sheets having the radiation pattern on the upper and lower surfaces of the shielding sheet, respectively, and connects the radiation patterns through a via hole formed in at least one of the shielding sheet and the laminated sheets in the vertical direction of the shielding sheet. By forming an antenna pattern with a metal cover, it is possible to implement the NFC antenna performance and MST antenna performance required as a standard in a mobile terminal to which a metal cover is applied, and the conventional NFC antenna module and MST mounted in a mobile terminal to which a cover made of a material other than metal is applied. There is an effect of implementing an antenna performance equal to or higher than that of the antenna module.

In addition, the laminated antenna module laminates the laminated sheets having the radiation pattern on the upper and lower surfaces of the shielding sheet, respectively, and connects the radiation patterns through a via hole formed in at least one of the shielding sheet and the laminated sheet to form an antenna pattern in the vertical direction of the shielding sheet. By forming , there is an effect that can implement NFC antenna performance and MST antenna performance in the vertical direction (ie, the side of the mobile terminal) as well as in the plane direction (ie, the rear surface of the mobile terminal).

In addition, the laminated antenna module laminates the laminated sheets having the radiation pattern on the upper and lower surfaces of the shielding sheet, respectively, and connects the radiation patterns through a via hole formed in at least one of the shielding sheet and the laminated sheet to form an antenna pattern in the vertical direction of the shielding sheet. By forming , there is an effect that can minimize the deviation of the NFC antenna performance and the MST antenna performance depending on the angle.

In addition, the laminated antenna module laminates the laminated sheets having the radiation pattern on the upper and lower surfaces of the shielding sheet, respectively, and connects the radiation patterns through a via hole formed in at least one of the shielding sheet and the laminated sheet to form an antenna pattern in the vertical direction of the shielding sheet. By forming the antenna (ie, NFC antenna, MST antenna) characteristics above the minimum standard for performing NFC communication on the side and back of the mobile terminal, it is possible to maintain antenna performance equal to or greater than that of the case mounted on a non-metal cover. there is an effect

In addition, the stacked antenna module arranges a shielding sheet having the same area and shape as the stacked sheet on which the radiation pattern is formed between the stacked sheets, and connects the radiation patterns through the via holes formed in the shielding sheet, thereby forming the stacked antenna module. Since the outermost surface can be used as a radiation pattern forming area, an open area (ie, an area in which a radiation pattern cannot be formed) can be minimized.

In addition, the stacked antenna module maximizes the radiation pattern formation area and minimizes the open area, thereby increasing the area (or length) of the radiation pattern to maximize antenna performance.

Although the 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 can be implemented.

100: stacked antenna module 110: lower stacked sheet
111: first adhesive sheet 112: first radiation pattern
113: first polyimide sheet 114: first terminal part
115: second terminal part 116: lower protective sheet
117: second adhesive sheet 120: electromagnetic wave shielding sheet
130: upper laminated sheet 131: third adhesive sheet
132: second radiation pattern 133: second polyimide sheet
134: third terminal part 135: fourth terminal part
136: upper protective sheet 140: connection portion
142: first via hole 144: second via hole
300: stacked antenna module 310: lower stacked sheet
311: first radiation pattern 312: first polyimide sheet
313: lower protective sheet 314: first adhesive sheet
320: electromagnetic shielding sheet 321: second adhesive sheet
322: shielding sheet 323: third adhesive sheet
330: upper laminated sheet 331: second radiation pattern
332: second polyimide sheet 333: first terminal part
334: second terminal 335: upper protective sheet
340: connection part 342: first via hole
344: 2nd via hole

Claims (5)

A lower portion formed with a first radiation pattern having a first side and a second side opposite the first side, a first end disposed adjacent to the first side and a second end disposed adjacent to the second side laminated sheet;
an electromagnetic wave shielding sheet disposed on the lower laminated sheet;
It has a first side and a second side opposite to the first side and is disposed on top of the electromagnetic wave shielding sheet, a first end is disposed adjacent to the first side and a second end is adjacent to the second side. an upper laminated sheet having a second radiation pattern disposed thereon;
a first connection part passing through the electromagnetic wave shielding sheet and connecting the first end of the first radiation pattern and the first end of the second radiation pattern; and
and a second connection part connecting the second end of the first radiation pattern and the second end of the second radiation pattern through the electromagnetic wave shielding sheet,
The upper laminated sheet,
a second resin sheet having a first side and a second side opposite to the first side, the second resin sheet being disposed under the electromagnetic wave shielding sheet;
a third terminal portion comprising a plurality of third terminals disposed adjacent to the first side of the second resin sheet on the upper surface of the second resin sheet; and
Further comprising a fourth terminal portion comprising a plurality of fourth terminals disposed adjacent to the second side portion of the second resin sheet on the upper surface of the second resin sheet,
The second radiation pattern is disposed to be spaced apart from each other on the lower surface of the second resin sheet, a first end is disposed adjacent to the first side of the second resin sheet, and a second end is disposed adjacent to the first side of the second resin sheet. A plurality of second radiation lines disposed adjacent to the second side,
The plurality of third terminals are connected one-to-one with the plurality of second radiation lines through a via hole passing through the second resin sheet,
The plurality of fourth terminals are connected one-to-one to the plurality of second radiation lines through another via hole passing through the second resin sheet. delete delete According to claim 1,
The lower laminated sheet further includes a first resin sheet having a first side and a second side opposite to the first side, and disposed under the electromagnetic wave shielding sheet,
The first radiation pattern is disposed to be spaced apart from each other on the upper surface of the first resin sheet, a first end is disposed adjacent to a first side of the first resin sheet, and a second end is disposed adjacent to the first side of the first resin sheet. A stacked antenna module including a plurality of first radiation lines disposed adjacent to the second side. 5. The method of claim 4,
The first connection part includes a plurality of first via holes that pass through the electromagnetic wave shielding sheet and connect the first ends of the plurality of first radiation lines and the first ends of the plurality of second radiation lines one-to-one;
The second connection part penetrates the electromagnetic wave shielding sheet and includes a plurality of second via holes for connecting second ends of the plurality of first radiation lines and second ends of the plurality of second radiation lines one-to-one. module.

Images