KR102348411B1 - Shielding unit for complex-antenna unit and complex-transmission module comprising the same - Google Patents

Abstract

The present invention relates to a shielding unit for a composite antenna unit and a composite transmission module including the same, and more particularly, to a composite antenna unit that blocks the effect of a magnetic field on the main body and battery of a portable terminal device and improves antenna characteristics at the same time It relates to a shielding unit and a complex transmission module including the same.

Description

Shielding unit for complex-antenna unit and complex-transmission module comprising the same

The present invention relates to a shielding unit for a composite antenna unit and a composite transmission module including the same.

In general, an antenna refers to a device that converts an electrical signal into a radio signal, and can be classified into a dielectric antenna using dielectric properties and a magnetic antenna using magnetic properties. All antennas can be used in various areas, but their efficiency varies depending on the shape or structure. In the past, studies on dielectric antennas using high-k materials were active, but as higher frequencies were used, the problem of antenna performance degradation due to miniaturization emerged. In recent years, these antennas are used to perform near field communication (NFC) and wireless power transmission (WPT) through various mobile terminals (smartphones, tablet PCs, etc.). , attempts to compound the Magnetic Security Transmission (MST) function are continuing.

First, the near-field communication (NFC) refers to a technology for transmitting data between terminals at a short distance of 10 cm with a contactless short-range wireless communication module using a 13.56 Mz frequency band as one of RFID, which is an electronic tag. NFC is a file transfer method, as well as mobile payment, and is widely used in supermarkets and general stores to transmit product information or travel information for visitors, traffic, and access control locks.

In addition, the 'Android Beam' provided in smartphones recently announced by Google is a short-distance communication (NFC)-based short-distance information transmission and reception function. It provides a function of transferring to another phone, and in this regard, Korean Patent Application Laid-Open No. 2015-001754 discloses an NFC tag-based content sharing method and an NFC gateway for the same.

Next, wireless power transmission (WPT) is a very convenient wireless charging and batteryless market in preparation for wired charging and increasing demand for charging due to the expansion of battery-using devices such as mobile devices, smart home appliances, and LoT (Internet of Things). It is a technology that has caused the rapid rise of technology that enables charging of batteries or driving of electronic devices even wirelessly.

The above technology is conceptually a technology that appeared 100 years ago by Tesla, and has recently been put to practical use according to the development of related technologies such as materials. As for the wireless power transmission (WPT), various technologies such as an electromagnetic induction method, a magnetic resonance method, and an RF method are being developed. In the case of the electromagnetic induction method, a frequency between several kHz and 20 MHz is used, and as the frequency of 13.56 MHz and short-range communication (NFC) is mixed and the harm to the human body increases as the frequency band goes to the high frequency band, the wireless charging function is 100 kHz to 6 MHz. It is a trend implemented below.

Next, the magnetic secure transmission (MST) function is It is a technology used between a magnetic card, a universal payment method, and a POS (Point Of Sale) terminal that can read information on magnetic cards. is going on

As a payment method using a conventional smart phone, methods using 2D barcode or NFC (Near Field Communication) have been proposed, but these 2D barcode or NFC method payment methods are difficult to apply universally because there is no reading device suitable for POS terminals. , In particular, in the case of NFC, the NFC performance standardized in many smart phones is lacking, and there was a disadvantage that a separate device for reading it must be provided.

However, in order to be able to transmit magnetic information to the POS terminal through a smartphone instead of the conventional magnetic card while using the POS terminal generally used in stores, etc. as it is, the MST that forms a magnetic field by interaction with the POS terminal The development of components for magnetic secure transmission, such as an antenna, is more demanded.

On the other hand, short-range wireless communication (NFC), wireless power transmission (WPT), and magnetic security transmission (MST) as described above commonly use electromagnetic field energy generated from an antenna, and wireless communication or transmission is possible through the transceiver. .

However, these technologies also have a limit of “transmission/reception distance of electromagnetic field energy”, contrary to what is expected to bring very surprising convenience to users. do. That is, since the induced electromotive force induced in the loop antenna in the form of a spiral coil is determined by Faraday's law and Lenz's law, magnetic flux linkage with the secondary coil (antenna coil) in order to obtain a high voltage signal The larger the amount, the more advantageous. The amount of magnetic flux increases as the amount of soft magnetic material included in the secondary coil increases and the magnetic permeability of the material increases.

The portable terminal device having the secondary coil as described above inevitably has a magnetic field shielding sheet because there is a problem in that the function of other parts included in the terminal device due to the magnetic field may be deteriorated or the human body may be harmed by the magnetic field.

The magnetic field shielding sheet serves to isolate other components in the portable terminal device from the magnetic field, and at the same time induces the concentration of the magnetic field between the transmitter/receiver to improve communication between transmission and reception, and to prevent deterioration of functions of other components due to the magnetic field.

As the magnetic permeability increases, the magnetic field shielding sheet is excellent in transmission/reception communication performance, and factors determining the magnetic permeability include a saturation magnetization value (Ms) of a magnetic material according to a material, a microstructure of the material, and the like. On the other hand, the material of the magnetic material is a factor determining the saturation magnetization value, and at the same time, the limit frequency may be determined accordingly. That is, there are cases where even a magnetic field shielding sheet having high magnetic permeability cannot be used depending on a desired frequency range, and even if used, the amount of material, that is, the thickness must be significantly increased to compensate for the low efficiency or poor efficiency. There is this.

However, the thick shielding sheet goes against the current trend of slimming the portable terminal device itself, and it is difficult to be employed in the slimmed terminal, and even if the thickness is increased, it is difficult to realize the desired level of communication strength.

In addition, when short-range wireless communication (NFC), wireless power transmission (WPT), and magnetic secure transmission (MST) functions, which may be used in different frequency bands, are combined into one portable terminal, it is superior only to a certain limited frequency band. The use of a shielding sheet having magnetic permeability has a very difficult problem in maintaining or improving only one function of each complex function, and simultaneously maintaining or improving other functions out of the limit frequency range.

Accordingly, a study on a magnetic shielding sheet that can significantly improve the characteristics of each antenna of the complex antenna at the same time, be implemented as thinned to meet the slimming trend of portable terminals, and significantly express the basic properties required for a magnetic shielding sheet is urgently needed.

The present invention has been devised to solve the above problems, and in an antenna unit in which a plurality of antennas with different frequency ranges used are combined, the characteristics of each antenna are significantly improved at the same time, and it is thinned to meet the slimming trend of portable terminals. It is implemented and to provide a shielding unit for a composite antenna unit that can significantly express the basic physical properties required for the magnetic shielding sheet.

In addition, the present invention simultaneously expresses significantly improved antenna characteristics even when antennas of different frequency bands are complexed through the shielding unit for a complex antenna unit according to the present invention, and as it becomes slim, complex transmission suitable for use in portable terminal devices, etc. It is to provide a module, a mobile device including the same, a smart home appliance, and a device for the Internet of Things (Internet of Things).

In order to solve the above problems, the present invention provides magnetic secure transmission (MST), wireless power transmission (WPT) and near field communication (NFC) in order to improve the characteristics of the antenna of the composite antenna unit, Mg-Cu-Zn-based It provides a shielding unit for a composite antenna unit comprising a first magnetic field shielding member comprising at least one selected from the group consisting of ferrite and Ni-Mg-Cu-Zn-based ferrite.

According to a preferred embodiment of the present invention, the shielding unit may further include a second magnetic field shielding member of a material different from that of the first magnetic field shielding member, and the second magnetic field shielding member includes a plurality of magnetic flakes. may include

In addition, one of the plurality of magnetic flakes may have a space spaced apart from the adjacent other magnetic flakes.

In addition, all or a part of the spaced space may be filled with an eddy current brake material.

In addition, the plurality of magnetic flakes may be derived from an amorphous ribbon sheet, and the amorphous ribbon sheet may include at least one selected from an amorphous alloy and a nanocrystalline alloy.

In addition, the amorphous alloy may include silicon-based steel.

In addition, the magnetic flakes may have an average particle diameter of 1 μm to 5 mm, and may have an irregular shape.

In addition, the eddy current braking material may be an insulating adhesive or a thermally conductive heat dissipation adhesive.

In addition, the second magnetic field shielding member may be provided as a single-layer member or a multi-layer member in which a plurality of second magnetic field shielding members are stacked, and the multi-layer member may be one in which 3 to 10 second magnetic field shielding members are stacked, , When the second magnetic field shielding member is a multi-layer member, an insulating adhesive layer or a thermally conductive heat dissipating adhesive layer interposed between each of the second magnetic field shielding members may be further provided.

In addition, the present invention provides a composite antenna unit including an antenna for magnetic secure transmission (MST), an antenna for wireless power transmission (WPT), and an antenna for near field communication (NFC) and is disposed on one side of the composite antenna unit to generate a magnetic field It provides a composite transmission module including a shielding unit according to the present invention for improving the characteristics of the organic and antenna.

According to an embodiment of the present invention, the inductor constituting the MST antenna is formed of a loop having at least one winding, and the inductor generates a magnetic field that spreads over an area corresponding to the sensing opening of the magnetic reader head. can be configured to form.

In addition, the inductor may be made of a material that is not saturated under a current flowing through the inductor.

Also, the ratio of the inductance to the resistance value of the inductor may be 10 μH/Ω to 80 μH/Ω.

In addition, the area formed by the loop may be 600 to 1700 mm 2 .

In addition, each of the antenna for magnetic secure transmission, the antenna for wireless power transmission, and the antenna for short-range wireless communication may be provided to be spaced apart from each other.

In addition, the present invention provides a mobile device, a smart home appliance, and an Internet of Things (Internet of Things) device including the complex transmission module according to the present invention.

Hereinafter, the terms used in the present invention will be described.

As used herein, the meaning of “formed on one side” or “formed on a layer” of a specific layer as used in the present invention includes both cases where it is formed directly facing the specific layer or is formed indirectly after one or more other layers are inserted on top of the layer. By including, for example, when "B layer formed on one surface of layer A", layer A and layer B directly face each other, or layer B is formed on layer C after the third layer C is formed on layer A including cases where

The term "member" used in the present invention is meant to include all of a sheet, a film, or a plate, unless the shape thereof is otherwise specified. For example, the shielding member is a shielding sheet , a shielding film, and a shielding plate are all included.

The shielding unit for a composite antenna unit according to a preferred embodiment of the present invention is to simultaneously significantly improve the characteristics of each antenna in an antenna unit in which a plurality of antennas having different frequency ranges used are combined, and to conform to the slimming trend of portable terminals. In spite of being implemented to be thin, the basic physical properties required for a magnetic field shielding sheet can be remarkably expressed.

In addition, in the case of a composite transmission module including such a shielding unit for a composite antenna unit, as each individual antenna simultaneously exhibits significantly improved antenna characteristics, the communication strength for transmission and reception is improved, so that even if the communication distance increases, the desired data transmission or radio Charging or payment may be smoothly performed.

Furthermore, the module implemented through the thinned shielding unit and the electronic device itself including the same can be slimmed down, so that it can be widely used as a product that meets the needs of recent consumers.

1 is a perspective view schematically showing a composite transmission module according to an embodiment of the present invention;
2 is a cross-sectional schematic view of a second magnetic field shielding member according to an embodiment of the present invention;
3 is a cross-sectional schematic view of a shielding unit according to an embodiment of the present invention;
4 is a cross-sectional schematic view of a second magnetic field shielding member according to an embodiment of the present invention;
5 is a cross-sectional view of a shielding unit according to an embodiment of the present invention;
6 and 7 are schematic diagrams illustrating a flake device used in an embodiment of the present invention.
8 is a schematic diagram of a compression device used in an embodiment of the present invention.
9 and 10 are cross-sectional views of the shielding sheet before manufacturing the second magnetic shielding member according to an embodiment of the present invention.
11 and 12 are cross-sectional views of a magnetic field shielding unit according to an embodiment of the present invention.
13 is a state diagram of a portable electronic device having a magnetic secure transmission module according to an embodiment of the present invention.
14 is a schematic configuration diagram for explaining the operation of FIG. 13 .
15 is a plan view of an antenna for magnetic secure transmission (MST) included in a complex antenna unit according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail.

As described above, there are cases where even a magnetic shielding sheet having high magnetic permeability cannot be used depending on a desired frequency band, and even if used, the amount of material, that is, the thickness, must be significantly thickened to compensate for the decrease in efficiency or poor efficiency. There was a problem being In addition, the thick shielding sheet goes against the current trend of slimming the portable terminal device itself, and it is difficult to be employed in the slimmed terminal, and even if the thickness is increased, it is difficult to realize the desired level of communication strength.

Specifically, a ferrite magnetic field shielding sheet has been widely used in the conventional near field communication (NFC). ^{Ferrite magnetic material has a specific resistance of 10 6} or higher compared to metallic magnetic material, so it has less eddy current loss, and has been used as a suitable material in high frequency range as it exhibits constant magnetic permeability and low electrical properties up to high frequency range. However, while the ferrite magnetic material has a limit frequency of 10 ~ 10 ⁴ MHz that can have super permeability (the degree may vary depending on the specific microstructure), while considering the influence of the human body, wireless power transmission (WPT) ) or magnetic secure transmission (MST), considering that the frequency range is 400 kHz or less, the initial permeability is almost 0 in the frequency band used for WPT or MST due to the limit of the limit frequency range of the ferrite material itself. As for the antenna unit in which each antenna using different frequency bands is combined, there was a problem that it was very insufficient to fully simultaneously realize the desired physical properties such as antenna characteristics, and the thickness of the ferrite sheet was reduced to improve the physical properties. In case of thickening, there was a problem that a thinned shielding member of a desired thickness could not be realized.

In addition, in order to improve the antenna characteristics for each antenna using a different frequency band from a different point of view, the number of antennas after selecting a material suitable for the frequency used for each antenna in consideration of the limit frequency of the shielding sheet material, etc. This means that shielding sheets each composed of as many different materials must be provided, and this goes against the thinness and causes complexity of the manufacturing process, which is a problem of productivity deterioration, considering the recent slimming of portable terminal devices.

Furthermore, in the case of wireless power transmission (WPT), a permanent magnet is usually provided in the wireless power transmitter to prevent magnetic flux leakage. The magnetic field shielding sheet made of ferrite is easily magnetized by the permanent magnet, that is, magnetically saturated by the permanent magnet, and behaves like a shielding sheet made of a material with remarkably low magnetic permeability. There was a problem that I couldn't.

Furthermore, since the direction of the spin arranged by the permanent magnet is opposite to the direction of the magnetic flux of the alternating magnetic field due to the antenna, the magnetic field is canceled and the inductance of the receiving antenna is rather decreased when a magnetic sheet known to have high magnetic permeability, for example, a ferrite sheet is used. There was a problem in that the desired physical properties could not be obtained, such as a remarkably lowered wireless power communication strength between the transceiver and a lowered charging efficiency.

In addition, the conventional ferrite shielding sheet has a problem in that it is difficult to manufacture a shielding sheet having a desired shape because the shielding sheet is bent by performing a high-temperature firing process during manufacture, and thus shape deformation may occur.

Accordingly, in the present invention, as a shielding unit for a composite antenna unit that induces a magnetic field according to magnetic secure transmission (MST), wireless power transmission (WPT), and near field communication (NFC), the shielding unit has the characteristics of the antenna of the composite antenna unit. By providing a shielding unit for a composite antenna unit, characterized in that it includes a first magnetic shielding member containing Mg-Cu-Zn-based ferrite to improve the solution of the above-mentioned problem was sought. Through this, a wide range of frequency bands can be simultaneously supported from an antenna using a kHz-class low-frequency band to an antenna using a MHz-class high-frequency band. As the magnetic flux is reduced and the communication strength between the transceiver is completely maintained or improved, the antenna characteristics can be significantly improved, and at the same time, it is very suitable for a slimming portable terminal device because of its excellent physical properties even if it is implemented as thin and thin.

Specifically, FIG. 1 is a perspective view schematically showing a composite transmission module according to a preferred embodiment of the present invention. The composite transmission module 100 includes a composite antenna unit 110 and a shielding unit 120 .

First, the shielding unit 120 for a composite antenna unit that induces a magnetic field according to magnetic secure transmission (MST), wireless power transmission (WPT), and near field communication (NFC) will be described.

The shielding unit 120 includes at least one selected from the group consisting of Mg-Cu-Zn-based ferrite and Ni-Mg-Cu-Zn-based ferrite to simultaneously improve the characteristics of each antenna provided in the composite antenna unit. It includes a first magnetic field shielding member.

At this time, at least one selected from the group consisting of the Mg-Cu-Zn-based ferrite and the Ni-Mg-Cu-Zn-based ferrite has electromagnetic wave shielding properties and heat dissipation properties at the same time, and as a material that can have a predetermined mechanical strength. , through which, in the antenna characteristics of the antenna unit in which antennas of different frequency bands are used, remarkably excellent antenna characteristics such as the magnetic flux density phenomenon between the transmitting and receiving units can be simultaneously expressed through a synergistic action with the first magnetic field shielding member, It is not easily magnetized even with a permanent magnet provided for magnetic field alignment between parts, so that the desired physical properties can be fully expressed.

In addition, at least one selected from the group consisting of the Mg-Cu-Zn-based ferrite and the Ni-Mg-Cu-Zn-based ferrite may be prepared at a lower temperature than the conventional ferrite produced by high-temperature firing (low-temperature firing ) It has a dense and uniform microstructure to achieve excellent magnetic permeability, so the shielding sheet manufactured through this does not have a bending problem as in the case of manufacturing at high temperature, so there is almost no shape deformation, so it is applied and applied to products This has the advantage of being easy.

Furthermore, at least one selected from the group consisting of the Mg-Cu-Zn-based ferrite and the Ni-Mg-Cu-Zn-based ferrite can achieve high magnetic permeability even at a thin thickness unlike conventional ferrite, so that the thickness can be reduced. There is an advantage in that it is easy to manufacture a lightweight, thin and compact product suitable for the current electronic device development trend. In addition, compared to the conventional ferrite material, it shows stable and excellent initial permeability even in a wide frequency band, so that each antenna using a different frequency band is applied to a complex antenna unit, thereby making it easy to implement the desired physical properties.

In addition, the shape of the first shielding member may be a shape of a shielding unit known in the art, and may be a polygon, a circle, an oval, a donut, etc., but is not limited thereto, and the shape of the following second shielding member is also the first It may be the same as or different from the shielding member. In addition, the thickness of the second shielding member may be designed differently depending on the purpose, and thus is not particularly limited in the present invention, but may be 0.01 μm to 1 mm.

Meanwhile, the magnetic field shielding unit according to a preferred embodiment of the present invention may further include a second magnetic field shielding member in addition to the above-described first magnetic field shielding member. The second magnetic field shielding member may be a shielding sheet including a magnetic material having a material and/or microstructure different from that of the magnetic material included in the first magnetic field shielding member. Preferably, the second magnetic field shielding member may include a magnetic material including a plurality of magnetic flakes.
Specifically, FIGS. 2 and 4 are cross-sectional schematic views of a second magnetic field shielding member 10 having a ribbon sheet layer 9 according to a preferred embodiment of the present invention, and as shown in the schematic diagram of FIG. 2 , a plurality of It includes magnetic flakes 2, and the plurality of magnetic flakes 2 are spaced apart between the magnetic flakes 2 and thus may have an empty space 4 between adjacent magnetic flakes 2, and An eddy current brake material 5 may be filled in all or part of the same empty space 4 .
In addition, according to a preferred embodiment of the present invention, as shown in Figure 2, the second magnetic field shielding member 10 is composed of a single-layer ribbon sheet layer 9, or as shown in Figure 4, the second magnetic field The shielding member 120' may be a multi-layer member in which a plurality of individual single-layer ribbon sheet layers 121a, 121b, 121c are stacked.
The second magnetic field shielding member is preferably a multi-layer member composed of multiple layers rather than a single-layer member in terms of physical properties, and more preferably a multi-layer member in which the single-layer second magnetic field shielding member is stacked in 3 to 10 layers. And, if it is laminated in less than 3 layers, the expression of desired physical properties may be reduced, and if it exceeds 10 layers, there may be a problem that goes against the thinning of the shielding unit.
In addition, when the second magnetic field shielding member is a multi-layer member composed of a plurality of layers, between each ribbon sheet layer 121a, 121b, 121c, which is a single layer, as shown in FIG. 4 , an insulating adhesive layer 121d or a thermally conductive heat dissipation adhesive layer (121d) may be further included.
The thickness of the second magnetic field shielding member may be that of a conventional shielding member, preferably 0.01 μm to 1mm, but is not limited thereto. In addition, the shape may be employed without limitation in the case of a conventional shielding member shape, and may be polygonal, circular, oval, donut-shaped, etc., but is not limited thereto.

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Hereinafter, the configuration of the second magnetic field shielding member will be described in more detail.

As shown in FIG. 2 , the second magnetic field shielding member 10 includes a plurality of magnetic flakes 2 . The shielding unit including the second magnetic field shielding member 10 generates a magnetic field to block the effect on the portable terminal by the electromagnetic wave signal generated from the first antenna (primary coil) installed in the transmitter (and/or receiver). The inductor serves as an inductor for inducing a second antenna (secondary coil) provided in the portable terminal device with high sensitivity to receive the transmitted electromagnetic wave signal at the same time. However, a decrease in the magnetic flux density of the received magnetic field occurs depending on the material and microstructure of the shielding unit, specifically, the second magnetic field shielding member, and more specifically, loss due to hysteresis or eddy current loss and The magnetic flux density may be lowered by residual loss, and as the second magnetic field shielding member according to the present invention includes a plurality of flaked magnetic materials, the decrease in magnetic resistance (R) of the first magnetic field shielding member There is an advantage that the quality factor of NFC communication, WPT transmission, and MST transmission is increased by making it larger than the decrease of the inductance (L) value, so that the efficiency of each communication or transmission can be significantly increased.

In addition, as the magnetic material is provided with a plurality of flakes 2, it is possible to reduce losses due to eddy currents, thereby further preventing a decrease in magnetic flux density. It has the advantage of blocking the heat problem.

Furthermore, as one magnetic flake among the plurality of magnetic material flakes is provided to be spaced apart from the adjacent magnetic material flakes, the size increases as the flaked magnetic materials come into direct contact with each other, and the problem of increasing eddy current loss can be prevented.

In addition, as the eddy current braking material 5 is filled in the space spaced apart between the magnetic flakes 2 , there is an advantage of permanently blocking direct contact or electrical connection between the magnetic flakes 2 , thereby lowering the magnetic flux density due to the eddy current can be further prevented.

The shape of the magnetic flake 2 is amorphous, and there is no limitation on a specific shape. In addition, preferably, the magnetic material flakes 2 have an average particle diameter of 1 μm to 5 mm, preferably an average particle diameter of 10 μm to 3 mm, and more preferably, an average particle diameter of 10 μm to 1 mm. have. In this way, by reducing the flake particle size of the magnetic material, the diamagnetic field is increased to remove the loss due to the hysteresis to increase the uniformity of magnetic permeability, and the heat problem caused by the eddy current generated by the alternating magnetic field can also be blocked. have.

The magnetic flake may be flaked from an amorphous ribbon sheet, and the amorphous ribbon sheet may include at least one selected from an amorphous alloy and a nanocrystalline alloy, and a saturation magnetic field in consideration of a saturation magnetization value (Ms) This larger amorphous alloy may be more desirable. The amorphous ribbon sheet may have a thickness of 0.01 to 60 μm, but the thickness may vary depending on the manufacturing method and purpose. More preferably, the amorphous alloy may include silicon-based steel in order to express more improved physical properties.

In addition, the microstructure of the magnetic material is one of the factors determining the magnetic permeability, and 20% or more of the silicon-based steel may have a microstructure with a particle diameter of 50 nm or less in terms of the area ratio of the structure, and more preferably a particle diameter of 5 to 30 nm It is preferable that the crystal grains of are formed to implement a structure in which the area ratio is in the range of 50% to 90% in the alloy structure.

In addition, the silicon-based steel may include, preferably, an Fe-Si-B-based alloy, a Fe-Si-B-Co-based alloy, or a Fe-Si-B-Cu-Nb-based alloy.

To explain this in more detail, the Fe-Si-B-based alloy has a high saturation magnetic flux density, but since it is difficult to form amorphous when the content of Fe element is excessive, in the present invention, the content of Fe is 70 to 90 atomic%. It is preferable to be

In addition, when the sum of Si and B is in the range of 10 to 30 atomic%, the amorphous forming ability of the alloy is the best. In order to prevent corrosion in this basic composition, corrosion-resistant elements such as Cr and Co may be added within 20 atomic%, and other metal elements may be included in small amounts as needed to impart other characteristics. In addition, the Fe-Si-B alloy may have, for example, a crystallization temperature of 508°C and a Curie temperature (Tc) of 399°C. However, the crystallization temperature may vary depending on the content of Si and B or other metal elements added in addition to the ternary alloy component and the content thereof.

In addition, a Fe-Si-B-Cu-Nb alloy can be used, and in this case, Fe is 73 to 80 atomic%, the sum of Si and B is 15 to 26 atomic%, and the sum of Cu and Nb is 1 to 5 atomic% % is preferred.

Next, the eddy current braking material 5 filling the space between the plurality of magnetic flakes 2 constituting the above-described second magnetic field shielding member to separate the flakes will be described.

The eddy current braking material 5 is filled in the space between the flakes to prevent the flakes from agglomeration and direct contact, thereby preventing an increase in the eddy current loss due to an increase in the size of the flakes. In addition, as the generated eddy current generates heat, the reduction of the eddy current has an advantage in that heat generation can be reduced. Furthermore, when the spaced space between the magnetic flakes remains as an empty space, moisture can penetrate through the gap, and the penetration of moisture causes oxidation of the amorphous ribbon, resulting in deterioration of shielding performance and poor appearance. The eddy current braking material 5 has the advantage of blocking moisture penetration.

The eddy current braking material 5 may be an insulating adhesive or a thermally conductive heat dissipation adhesive, and in the case of an insulating adhesive, a conventional insulating adhesive component used in the art may be used without limitation, and an adhesive that is deformable when pressed at room temperature is Thermoplastic adhesives that are used or that deform upon application of heat may be used. As a non-limiting example, a polymer resin including at least one selected from wax, epoxy resin, melanin resin, silicone resin, acrylic resin, ethylene propylene rubber resin (EPDM) and polyvinyl alcohol resin (PVA) may be used. have.

In addition, the thermally conductive heat dissipation adhesive may be filled in the space between the flakes 2 to perform a function of separating the flakes and simultaneously perform a function of dissipating heat generated according to an eddy current. A typical wireless power transmission module or short-distance communication module further includes a heat dissipation unit on the upper or lower portion of the magnetic field shielding sheet. Since it is possible to omit or reduce the thickness of the heat dissipation unit, there is an advantage that can be more advantageous for slimming the composite transmission module. The thermally conductive heat dissipation adhesive may be implemented by providing a thermally conductive heat dissipation filler to the above-described insulating adhesive, and the thermally conductive heat dissipation filler may use a filler known in the art, and the present invention is not particularly limited thereto.
On the other hand, the magnetic field shielding unit according to a preferred embodiment of the present invention is one or more members selected from the protective member (1), the release member (3) and the adhesive member (5) on one or both sides of the first magnetic field shielding member described above. may further include. Specifically, as shown in Figure 3, the protective member (1) or the release member (3) is formed on the upper portion of the first magnetic field shielding member, the adhesive member (5) is formed on the lower portion, the adhesive member (5) The release member 3 may be formed in the lower part of the. In addition, as shown in Fig. 5, the adhesive member 5 is formed on both sides of the first magnetic field shielding member, and the protective member 1 or the release member 3 is formed on the upper surface of the adhesive member 5, , the release member 3 may be formed under the adhesive member 5 . The adhesive member 5 may be the same or different material from the above-described eddy current braking material, and in the case of the same material, it is possible to simultaneously form an adhesive layer and fill the space between the magnetic material flakes by forming an adhesive member once in a manufacturing process to be described later. There is an advantage.
The protective member 1 is, for example, a polyethylene terephthalate (PET) film, a polyimide film, a polyester film, a polyphenyline sulfate (PPS) film, a polypropylene (PP) film, polytetrafluoroethylene (PTFE) ) and a resin film such as a fluororesin film may be used, and the thickness may be a conventional thickness, and may preferably be 1 to 200 μm, but is not limited thereto.

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In addition, the release member can be used without limitation in the case of a normal release member, and even in the case of a thickness, there is no limitation in the case of a normal thickness. The adhesive member 5 may be an ordinary adhesive member and may be an adhesive member in which an adhesive component is disposed only on one side, or may be an adhesive member in which an adhesive component is disposed on both surfaces. The adhesive member may be a conventional adhesive member, and preferably may be the same component as the eddy current braking material, but is not limited thereto. The thickness of the adhesive member may be designed differently depending on the purpose, and may be 0.01 μm to 1 mm, but is not particularly limited in the present invention.

The above-described second magnetic field shielding member may be manufactured through the following method, but is not limited thereto.

Specifically, coating the outer surface of the magnetic material with an eddy current braking material to form a coating layer, forming a protective layer on the outside of the coating layer, and applying pressure to flake the magnetic material to be manufactured by performing a process can In addition, the step of compressing may be further performed after the step of treating the flakes, and the step of manufacturing a sheet or film in the form of a sheet or film may be further performed after the step of compressing (first manufacturing method).

In addition, the second magnetic field shielding member of the present invention comprises the steps of forming a laminated sheet to which a protective film and a double-sided tape having a release film formed on the exposed surface are attached to both sides of the magnetic sheet, and applying pressure to the laminated sheet, including magnetic flakes It may include a process comprising the steps of manufacturing a laminated sheet and flattening and slimming the laminated sheet by laminating the laminated sheet containing magnetic flakes, wherein the double-sided tape is an adhesive on both sides of the tape, an eddy current braking material It may include (second manufacturing method).

Of the preferred method for manufacturing the second magnetic field shielding member of the present invention, the step of treating the flakes by applying pressure in the first manufacturing method or manufacturing the laminated sheet including the magnetic flakes in the second manufacturing method is shown in Figs. The magnetic body can be made into flakes using the flake device shown in 7 .

Specifically, as shown in FIG. 6 , the first flake device 20 includes a metal roller 21 having a plurality of irregularities 21a formed on its outer surface, and a rubber roller 25 disposed to face the metal roller 21 . ), and the second flake device 30 is disposed opposite to the metal roller 31 and the metal roller 31 on which a plurality of spherical balls 31a are mounted on the outer surface, as shown in FIG. 7 . It may be composed of a rubber roller (35).

In addition, the first flake device and It is possible to flake the magnetic material by passing it through the second flake devices 20 and 30 . Then, a plurality of the flake device can be passed through to flake it to a desired size. At this time, the separated plurality of flakes are maintained in a separated state through the double-sided tape adhered to both sides.

In addition, during flake treatment, the coated eddy current braking material or the eddy current braking material present in the double-sided tape is filled in the spaced space (4 in FIG. 1) between the flakes through the pressure applied during the flake treatment, a simplified manufacturing process There is an advantage of expressing the desired physical properties through

In addition, the process of compressing after flake treatment in manufacturing method 1 or flattening and slimming in manufacturing method 2 minimizes the spaced apart space existing between the flakes and allows the eddy current braking material to fill the spaced space well, In order to induce the flakes to exist in the male direction so that heat dissipation occurs well in the horizontal direction, for a specific example, the apparatus shown in FIG. The roller device 40 may be a roll press type consisting of a first pressure roller 41 and a second pressure roller 45 disposed at a predetermined distance from the first pressure roller 41, and the present invention is applicable. The present invention is not limited thereto.

The first magnetic field shielding member and the second magnetic field shielding member are provided in the shielding unit in a shape in which the other shielding member is accommodated inside the one shielding member, or in the shielding unit in a shape in which another shielding member is laminated on the upper or lower part of the one shielding member. can be provided. Specifically, FIG. 11 is a cross-sectional view of a magnetic field shielding unit according to a preferred embodiment of the present invention. The first magnetic field shielding member 122 is provided with a receiving part 124 for accommodating the second magnetic field shielding member 121, and , by inserting the second magnetic field shielding member 121 into the receiving portion 124, there is an advantage that the thickness of the overall shielding member can be reduced by forming different magnetic field shielding members as one layer. The arrangement of the first magnetic field shielding member 122 or the second magnetic field shielding member 121 may vary depending on the arrangement of the NFC antenna, the MST antenna, and the WPT antenna in the composite antenna unit bonded to the shielding unit, and the antenna The specific arrangement is not limited to the above description, such that a plurality of accommodation units capable of accommodating one magnetic field shielding member may be included depending on the arrangement of the . In addition, any one of an adhesive member, a protective film, and a release film 123 may be independently formed on the upper and lower portions of the magnetic field shielding members 121 and 122 . In addition, specifically, FIG. 12 is a cross-sectional view of a magnetic field shielding unit according to a preferred embodiment of the present invention, wherein the first magnetic field shielding member and the second magnetic field shielding member 8 may be stacked to form a shielding unit, at this time, An adhesive member 5 may be further provided between each shielding member.

Next, a composite transmission module including the magnetic shielding unit according to the present invention described above will be described.

The composite transmission module according to the present invention is a composite antenna unit including an antenna for magnetic secure transmission (MST), an antenna for wireless power transmission (WPT), and an antenna for near field communication (NFC) and is disposed on one side of the composite antenna unit and a magnetic field shielding unit according to the present invention that induces a magnetic field and improves antenna characteristics.

Specifically, as shown in FIG. 1, it is composed of a composite antenna unit 110 and a magnetic field shielding unit 120, and the composite antenna unit 110 is an NFC antenna ( 114a) and an antenna 114b for MST and an antenna 114c for WPT provided sequentially spaced apart from each other on the inside thereof.

The description of the magnetic field shielding unit 120 is the same as described above, and thus will be omitted, and the complex antenna unit 110 will be described in detail below.

The composite antenna unit 110 is for transmitting or receiving a wireless high-frequency signal between portable electronic devices, such as mobile phones, PDA, PMP, tablets, multimedia devices, smart home appliances and LoT electronic devices or between the devices and other transceivers As a result, antennas using the same or different frequency bands are combined into one unit, including an antenna for magnetic secure transmission (MST), an antenna for wireless power transmission (WPT), and an antenna for near field communication (NFC). Functions can be performed as one unit.

The composite antenna unit 110 may be provided on one surface of the above-described magnetic field shielding unit 120, or may be provided in plurality, and may be fixed to one surface of the shielding unit 120 via an adhesive layer. .

The adhesive layer may be a bond having an adhesive property, PVC, rubber, or double-sided tape, and may include a conductive component.

On the other hand, each antenna included in the composite antenna unit 110 may be composed of a polygonal coil such as a circle, oval, spiral or square wound in a clockwise or counterclockwise direction, or by etching a metal foil such as copper foil. may be configured.

In addition, the composite antenna unit 110 may be formed in a printed pattern on the circuit board 112 , and one surface of the circuit board 112 may be attached to one surface of the magnetic field shielding unit 120 described above.

The circuit board 112 is an element serving as a substrate on which antenna patterns and circuits for MST, NFC, and WPT are formed on its upper surface, and is a material having heat resistance and pressure resistance, and is flexible. In consideration of the physical properties of these materials, a film such as PI or PET, which is a thermosetting polymer film, may be employed as the circuit board 112 .

In addition, a connection terminal for electrical connection with the circuit board 112 may be drawn out from both ends of the composite antenna unit 110 .

When describing each antenna included in the composite antenna unit 110 in detail, in FIG. 1 , the NFC antenna 114a has a higher frequency band than the WPT antenna 114c, so the outside of the circuit board 112 is removed. Accordingly, it is formed in a conductive pattern in a rectangular shape with a fine line width, and the WPT antenna 114c requires power transmission and uses a lower frequency band than the NFC antenna 114a, so the NFC antenna inside the NFC antenna 114a. It may be formed with a line width wider than the line width of (114a). In addition, the MST antenna 114b using a lower frequency band than the NFC antenna 114a may be located in the region between the NFC antenna 114a and the WPT antenna 114c, but the positional relationship between each antenna is It may be changed depending on the purpose, and the number of antennas included in one circuit board 112 may also be different from each other.

The NFC antenna 114a may serve as a reception antenna or a transmission antenna provided to transmit or receive data to enable file transmission, mobile payment, etc. through a transmitted or received signal. The specific material, shape, thickness, length, etc. of the NFC antenna may be the same as that of a normal NFC antenna, and thus the present invention is not particularly limited thereto.

In addition, the MST antenna 114b may serve as a reception antenna provided to transmit or receive data for electronic payment through a magnetic signal transmitted or received, or may serve as a transmission antenna. .

The MST antenna 114b may be formed of an inductor, and the inductor may be formed of a loop having at least one winding. Preferably, the loop may consist of 20 or more windings.

Specifically, as shown in FIG. 13 , the portable electronic device 200 including the composite transmission module 100 including the composite antenna unit including the antenna 114b for MST is set a certain distance from the POS terminal 300 . Even if spaced apart, it is possible to generate an omni-directional magnetic field that can pass through the reader head ( FIGS. 14 and 310 ) in the POS terminal. To this end, the inductor may be configured to form a magnetic field that spreads over an area corresponding to the sensing opening 302 of the magnetic reader head of the POS terminal to detect a sufficient magnetic field in the POS terminal.

The inductor may also have an inductance value that allows properly timed current pulses to reach their maximum, thereby resulting in a maximum induced voltage at the reader header (FIGS. 14, 310). In addition, the inductor may have a sufficiently low resistance value to allow the large current required to generate a strong magnetic field. Accordingly, the inductor may have a ratio of inductance to resistance of 10 μH/Ω to 80 μH/Ω.

In addition, the inductor may lead to a material that is not saturated under the current flowing through the inductor.

The inductor may be formed of a coil having a polygonal shape such as a circular, elliptical, spiral or rectangular shape wound in a clockwise or counterclockwise direction, or may be configured by etching a metal foil such as copper foil.

Here, as shown in FIG. 15 , the outermost width w of the loop may be 15 to 50 mm, and the width d of the winding formed by the loop may be 3 mm. In this case, the loop may be formed such that an area formed by the loop is within 600 to 1700 mm 2 .

On the other hand, the WPT antenna 114c included in the composite antenna unit 110 is provided to transmit power using an inductive coupling method based on an electromagnetic induction phenomenon through a wireless power signal transmitted or received. may be performed or may serve as a transmission antenna. Since such a magnetic induction charging technique is a known technique, a detailed description thereof will be omitted.

The above-described magnetic field shielding unit 120 is made of a plate-shaped member having a predetermined area, and serves to induce a magnetic field generated by the antenna unit 110, and performs different functions as described above, and each other The advantage of being able to simultaneously increase the characteristics of the three types of antennas with the first magnetic field shielding member alone for a composite antenna unit having three types of antenna units (114a, 114b, 114c) each using different or partially overlapping frequency bands This has the advantage of not having to provide a separate shielding member for each antenna characteristic, and through this, a magnetic shielding unit, furthermore, a complex transmission module and various mobile devices, smart home appliances, and the Internet of Things using the same It is very advantageous for realizing a device for use in a slim form while expressing remarkably excellent physical properties.

On the other hand, the composite transmission unit according to the present invention may further include other components provided in a typical transmission module, such as a heat dissipation unit.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art who understand the spirit of the present invention can add components within the scope of the same spirit. , changes, deletions, additions, etc. may easily suggest other embodiments, but this will also fall within the scope of the present invention.

100: composite transmission module 110: composite antenna unit
112: circuit board 114a: antenna for NFC
114b: Antenna for MST 114c: Antenna for WPT
120: shielding unit 1: protective film
3: release film 5: eddy current braking material
9, 121a, 121b, 121c: ribbon sheet layer 121d: adhesive layer

Claims (23)

To improve the characteristics of the antenna of a complex antenna unit including an antenna for magnetic secure transmission (MST), an antenna for wireless power transmission (WPT), and an antenna for near field communication (NFC) operated at different operating frequencies,
a first magnetic field shielding member including a Ni-Mg-Cu-Zn-based ferrite; and
3 to 10 ribbon sheet layers in which an amorphous ribbon sheet comprising at least one selected from an amorphous alloy and a nanocrystalline alloy is flaked into a plurality of magnetic flakes, adjacent to all or part of the space spaced apart between the magnetic flakes a second magnetic field shielding member comprising an eddy current braking material which is a thermally conductive heat dissipation adhesive having a thermally conductive heat dissipation filler disposed thereon and a thermally conductive heat dissipation adhesive layer interposed between each ribbon sheet layer; to provide
The amorphous alloy includes silicon-based steel, and the silicon-based steel has grains having a grain size of 5 to 30 nm in an area ratio of 50% to 90% in the alloy structure.
According to claim 1,
The first magnetic field shielding member and the second magnetic field shielding member are disposed so that the other shielding member surrounds the side surface of the one shielding member, the other shielding member is inserted into the one shielding member, or the upper part of the one shielding member A shielding unit for a composite antenna unit, characterized in that other shielding members are stacked.
According to claim 1,
The magnetic flake is a shielding unit for a composite antenna unit, characterized in that the average particle diameter is 1㎛ ~ 5㎜ atypical.
delete Antenna for near field communication (NFC), an antenna for wireless power transmission (WPT) spaced apart from the inside of the antenna for near field communication (NFC), and an antenna for near field communication (NFC) and wireless power transmission (WPT) and an antenna for magnetic secure transmission (MST) disposed spaced apart between the antennas for the MST, wherein an inductor constituting the antenna for MST is formed of a loop having at least one winding, and the inductor generates a magnetic field from the POS terminal. a composite antenna unit configured to form an omni-directional magnetic field that is emitted to be diffused over an area corresponding to a sensing opening of a magnetic reader head of the POS terminal to be detected and that can penetrate the magnetic reader head; and
A composite transmission module comprising a; the shielding unit according to any one of claims 1 to 3, which is disposed on one surface of the composite antenna unit to induce a magnetic field and improve the antenna characteristics of the composite antenna unit.
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