The present disclosure relates to a shield can mounted on an electronic device and for shielding electromagnetic waves to block noises.
Recently, as electronic devices have become more complex and have advanced specifications, the number of antennas mounted (or installed) is increasing. For example, recent smartphones are equipped with an antenna for transmitting and receiving signals in mobile communication frequency bands, an antenna for short-range communication such as Bluetooth and near-field communication (NFC), a global positioning system (GPS) antenna and a ultra-wideband (UWB) antenna for transmitting and receiving position information, and the like.
However, as an electronic device is gradually becoming slimmer and smaller, there is a problem in that a space for mounting electronic components and antennas is insufficient, and due to a reduction of the mounting space, interference occurs between the electronic components and the antennas mounted on the electronic device, there degrading the performance of the antennas.
Therefore, a shield can for shielding electromagnetic waves is mounted on the electronic device, and there is a problem in that as the shield can is additionally disposed, the mounting space becomes more insufficient, and a layout structure and circuits of the electronic components become complicated.
The present disclosure has been made in efforts to solve the problems and is directed to providing a shield can, which operates as an antenna while shielding electromagnetic waves by defining a radiation region resonating in one or more frequency bands according to the formation of slits.
In order to achieve the object, a shield can disposed on an upper surface of a printed circuit board and configured to cover electronic components mounted on the printed circuit board according to an embodiment of the present disclosure includes a first slit formed in the shield can and dividing the shield region into a first internal region and a first external region spaced apart from the first internal region, a shield region that is the first external region divided by the first slit, and a first radiation region that is the first internal region divided by the first slit.
The first radiation region and the shield region may be spaced by 1 mm or more from each other with the first slit interposed therebetween, and the first radiation region may have one of a meander line shape and a patch shape.
The shield can according to the embodiment of the present disclosure may further include a second slit spaced apart from the first slit, formed in the first external region, and dividing the first external region into a second internal region and a second external region spaced apart from the second internal region, and a second radiation region that is the second internal region divided by the second slit.
The shield region may be the second external region divided by the second slit among the first external region, and the second radiation region and the shield region may be spaced by 1 mm or more from each other with the second slit interposed therebetween.
The first radiation region may be formed in a meander line shape and resonates in a first frequency band, and the second radiation region may be formed in a patch shape and resonates in a second frequency band differing from the first frequency band.
The shield can according to an embodiment of the present disclosure includes a first power feeding region formed on a lower surface of the shield can and connected to the first radiation region, and a second power feeding region formed on the lower surface of the shield can and connected to the second radiation region.
According to the present disclosure, the shield can may operate as the antenna by forming the slits (or the slots) and forming the metal radiation region.
In addition, since the shield can operates as the antenna and thus the separate antenna is not mounted on the electronic device, it is possible to minimize the mounting space for mounting the antenna and the shield can. Therefore, the electronic device for mounting the shield can according to the embodiment of the present disclosure can secure the mounting space and become slimmer and smaller compared to the electronic device in which the antenna and the conventional shield can are mounted.
In addition, since the shield can does not require the additional antenna, it is possible to reduce the manufacture cost of the electronic device.
Hereinafter, the most preferred embodiment of the present disclosure will be described with reference to the accompanying drawings in order to describe the present disclosure in detail to the extent that those skilled in the art can easily carry out the technical spirit of the present disclosure. First, in adding reference numerals to components in each drawing, it should be noted that the same components have the same reference numerals as much as possible even when they are shown in different drawings. In addition, in describing embodiments of the present disclosure, when it is determined that the detailed description of related known configurations or functions may obscure the gist of the present disclosure, a detailed description thereof will be omitted.
Referring to
Slits (i.e., a first slit S1 and a second slit S2 or slots) for forming a portion of the shield can 100 as a radiation region is formed in the shield can 100. Radiation regions 120 and 130 in various shapes may be formed in the shield can 100 by the slits S1 and S2, and the radiation region in a meander line shape or a patch shape (plate shape) may be formed depending on a frequency band in which the radiation region resonates.
In this case, in
Referring to
The shielding region 110 is a region disposed in outer circumferences of the slits S1 and S2 formed to form the radiation region. As the slits S1 and S2 are formed in an upper surface of the shield can 100, a first accommodation hole 112 in which the first radiation region 120 is accommodated is defined in the shielding region 110, and a second accommodation hole 114 in which the second radiation region 130 is accommodated is defined in the shielding region 110.
The first radiation region 120 is a region of the upper surface of the shield can 100, which operates as a radiator that resonates with a signal in a first frequency band. The first radiation region 120 is a region disposed in an inner circumference of the first slit S1 formed to form the radiation region. In this case, the first radiation region 120 is defined in a region positioned on the inner circumference of the first accommodation hole 112 defined in the shielding region 110.
The first radiation region 120 is formed in a meander line shape with a predetermined line width. In this case, for example, the first radiation region 120 operates as a radiator that is formed in the meander line shape with one or more bent portions and resonates with the signal in the first frequency band, and is formed in the meander line shape with seven bent portions and resonates with a signal in a Bluetooth low energy (BLE) frequency band. Here, since a line width of the first radiation region 120 may be variously changed depending on the electronic components to be accommodated, the resonant frequency band, or the like, the value is not limited.
Meanwhile, when the first radiation region 120 and the shielding region 110 are disposed adjacent to each other, signal interference occurs and the antenna performance of the first radiation region 120 is inevitably degraded. Therefore, the first radiation region 120 is disposed to be spaced by a set distance or more from the first accommodation hole 112. In other words, the first slit S1 positioned between the shielding region 110 and the first radiation region 120 is disposed to have a width that is larger than or equal to a set width. Here, the set distance and the set width are, for example, about 1 mm or more.
The second radiation region 130 is a region of the upper surface of the shield can 100, which operates as a radiator that resonates with a signal in a second frequency band. The second radiation region 130 is a region disposed in an inner circumference of the second slit S2 formed to form the radiation region. In this case, the second radiation region 130 is defined in an inner circumferential region of the second accommodation hole 114 defined in the shielding region 110.
The second radiation region 130 is formed in a patch shape (plate shape) with a predetermined line width. In this case, for example, the second radiation region 130 operates as a radiator that is formed in the patch line shape with a predetermined area and resonates with the signal in the second frequency band, and is formed in the patch shape with a quadrangular shape having a predetermined area and resonates with a signal in a ultra-wideband (UWB) frequency band. Here, since the area of the second radiation region 130 may be variously changed depending on the electronic components to be accommodated, the resonant frequency band, or the like, the value is not limited.
Meanwhile, when the second radiation region 130 and the shielding region 110 are disposed adjacent to each other, signal interference occurs and the antenna performance of the second radiation region 130 is inevitably degraded. Therefore, the second radiation region 130 is disposed to be spaced by a set distance or more from the second accommodation hole 114. In other words, the second slit S2 positioned between the shielding region 110 and the second radiation region 130 is disposed to have a width that is larger than or equal to a set width. Here, the set distance and the set width are, for example, about 1 mm or more.
Referring to
The bonding region 140 is a region that is bonded to an attachment region disposed on the circuit board when the shield can 100 is mounted on the circuit board. The bonding region 140 is disposed along an edge of the lower surface of the shield can 100 and has a first bonding surface 140a having a predetermined area.
The first power feeding region 150 is a region connected to a power feeding pad of the circuit board to supply power to the first radiation region 120. In this case, an end portion of the first radiation region 120 extends to a lower portion of the shield can 100 through a side surface of the shield can 100, and the first power feeding region 150 is connected to the end portion of the first radiation region 120. The first power feeding region 150 is connected to a first signal processing element (not illustrated) for processing the signal in the first frequency band through the power feeding pad of the circuit board. In this case, for example, the first power feeding region 150 is spaced by a set distance or more from the bonding region 140, and the set distance is about 1 mm or more.
The second power feeding region 160 is a region connected to the power feeding pad of the circuit board to supply power to the second radiation region 130. In this case, an end portion of the second radiation region 130 extends to a lower portion of the shield can 100 through the side surface of the shield can 100, and the second power feeding region 160 is connected to the end portion of the second radiation region 130. The second power feeding region 160 is connected to a second signal processing element (not illustrated) for processing the signal in the second frequency band through the power feeding pad of the circuit board. In this case, for example, the second power feeding region 160 is spaced by a set distance or more from the bonding region 140, and the set distance is about 1 mm or more.
Meanwhile, in
For example, referring to
As another example, referring to
Referring to
The circuit board 200 is disposed inside the electronic device, and electronic components are mounted on an upper surface of the circuit board on which the shield can 100 is mounted. In this case, a second bonding surface 210 in surface contact with the first bonding surface 140a of the shield can 100 and fixedly bonding the shield can 100 is formed on the upper surface of the circuit board 200.
The second bonding surface 210 is formed on the upper surface of the circuit board 200 through a surface mount device (SMD) process. In this case, the second bonding surface 210 is formed along an outer periphery of the upper surface of the circuit board 200 and formed in a shape corresponding to the shape of the first bonding surface 140a formed on the lower surface of the shield can 100.
A power feeding pad is formed on the upper surface of the circuit board 200 to supply power to the first radiation region 120 and the second radiation region 130 of the shield can 100. For example, a first power feeding pad 220 and a second power feeding pad are formed on the upper surface of the circuit board 200.
The first power feeding pad 220 is formed on the upper surface of the circuit board 200 through the SMD process. The first power feeding pad 220 is connected to a first signal processing element (not illustrated) for processing the signal in the first frequency band.
The first power feeding pad 220 is formed in a region of the upper surface of the circuit board 200, which is in surface contact with the first power feeding region 150 of the shield can 100 mounted on the upper surface of the circuit board 200. As the shield can 100 is mounted on the circuit board 200, the first power feeding pad 220 is in surface contact with the first power feeding region 150 of the shield can 100 and electrically connected to the first power feeding region 150. In this case, the first radiation region 120 of the shield can 100 is in surface contact with the first power feeding pad 220 to receive power and resonates in the first frequency band to transmit the signal in the first frequency band to the first signal processing element (not illustrated).
The second power feeding pad 230 is formed on the upper surface of the circuit board 200 through the SMD process. The second power feeding pad 230 is connected to a second signal processing element (not illustrated) for processing the signal in the second frequency band.
The second power feeding pad 230 is formed in a region of the upper surface of the circuit board 200, which is in surface contact with the second power feeding region 160 of the shield can 100 mounted on the upper surface of the circuit board 200. As the shield can 100 is mounted on the circuit board 200, the second power feeding pad 230 is in surface contact with the second power feeding region 160 of the shield can 100 and electrically connected to the second power feeding region 160. In this case, the second radiation region 130 of the shield can 100 is in surface contact with the second power feeding pad 230 to receive power and resonates in the second frequency band to transmit the signal in the second frequency band to the second signal processing element (not illustrated).
In this case, in
Although the preferred embodiments of the present disclosure have been described above, modifications can be made in various forms, and those skilled in the art can carry out various changes and modifications without departing from the claims of the present disclosure.
Number | Date | Country | Kind |
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10-2021-0049699 | Apr 2021 | KR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/KR2022/004058 | 3/23/2022 | WO |