KR101916150B1 - Shielding unit for wireless power transfer, Wireless power transfer module comprising the same and Mobile device comprising the same - Google Patents

Abstract

A magnetic shielding unit for wireless power transmission is provided. The magnetic field shielding unit according to an embodiment of the present invention may be applied to at least a part of the spacing space formed between the fragments of the broken Fe alloy and fragments adjacent to some of the fragments in order to improve the flexibility of the shielding unit, Wherein the Fe-based alloy fragments have a magnetic shielding layer having a number of fragments having a particle size of less than 500 μm of 60% or more of the total number of fragments. Accordingly, it is possible to minimize the influence of heat due to the leakage magnetic field, malfunction of the electronic parts, and the health of the user of the portable device due to the leakage magnetic field in the wireless power transmission. Further, even when combined with various types of antennas for wireless power transmission having various structures, shapes, sizes, and intrinsic characteristics (inductance, resistivity, etc.), the inductance characteristics of the combined antenna itself are further improved, The increase of the resistivity characteristic of the accompanying antenna is minimized, and the characteristic of the antenna for wireless power transmission can be more remarkably expressed.

Description

Technical Field [0001] The present invention relates to a magnetic shielding unit for wireless power transmission, a wireless power transmission module including the wireless power transmission module, and a portable device including the wireless power transfer module,

The present invention relates to a wireless power transmission module, and more particularly, to a wireless power transmission module capable of preventing a magnetic field from affecting a human body of a portable terminal device or a user using the wireless power transmission module and significantly improving antenna characteristics, A wireless power transmission module including the same, and a portable device.

Wireless power technologies of portable electronic devices such as mobile phones, personal digital assistants (PDAs), iPads, notebook computers, and tablet PCs are emerging. The new type of wireless power transmission technology is a technology that enables a portable electronic device to charge a battery by directly transmitting electric power to a portable electronic device by adopting an electromagnetic induction method or an electromagnetic resonance method without a power line, There is an increasing trend of electronic devices.

The wireless power transmission requires a wireless power transmission module and a wireless power reception module for receiving the wireless power transmission module. The modules are commonly equipped with an electromagnetic shielding material (magnetic material). Specifically, in an example of a wireless power transmission technique, an electromagnetic induction type wireless power transmission may be such that a magnetic field (power signal) transmitted from a transmitting antenna is received at a receiving antenna and is then switched back to an electric field to transmit power wirelessly. It is necessary to concentrate the direction of the transmitted magnetic field to the receiving antenna and to prevent leakage to other directions, and this function can be achieved through the electromagnetic shielding material.

However, the magnetic field that can not be focused by the wireless power receiving antenna after being transmitted according to the performance of the electromagnetic shielding material lowers the wireless power transmission efficiency and the power signal transmission / reception distance. In addition, the inside of the electronic device equipped with the receiving wireless power transmission module Degrade the performance of the component, and adversely affect the person using the electronic device.

Meanwhile, the performance of the antenna for wireless power transmission can be replaced with the performance of the antenna with high and low quality factor (Q). The quality factor Q is 2? FL / R (f: frequency, L: R: resistance), and it is usually judged that the higher the quality index, the better the performance of the antenna.

In particular, the higher the magnetic permeability of the magnetic material included in the electromagnetic shielding material, the more the inductance characteristics of the antenna are improved, and the quality index (Q) of the antenna is improved. And the resistance value of the antenna itself may be increased rather than the resistance value of the antenna itself depending on the degree of the surface resistance of the electromagnetic shielding material, thereby causing a decrease in the quality index Q of the antenna.

Accordingly, development of an electromagnetic shielding material capable of remarkably improving wireless power transmission efficiency and transmission / reception distance of a power signal by minimizing interference of an antenna performance or improving performance of an antenna in a desired frequency band used for transmission / reception of a wireless power signal This is urgent.

Korean Patent Publication No. 10-2014-0088256

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and it is an object of the present invention to provide a portable terminal device and a portable terminal device, It is an object of the present invention to provide a magnetic shielding unit which can be further increased without interfering with the characteristics of an antenna to be combined with various kinds of antennas for wireless power transmission having characteristics (inductance, resistivity, etc.).

It is another object of the present invention to provide a wireless power transmission module capable of remarkably increasing the wireless power transmission efficiency and the wireless power transmission distance by further improving the characteristics of the antenna for wireless power transmission through the magnetic shielding unit according to the present invention .

It is another object of the present invention to provide a portable device in which a wireless power transmission efficiency of a portable device power supply is improved and a wireless power transmission distance is increased through the wireless power transmission module according to the present invention.

It is yet another object of the present invention to provide a combined magnetic field shielding unit capable of simultaneously improving the characteristics of an antenna having different uses in addition to wireless power transmission through a magnetic shielding unit for wireless power transmission according to the present invention.

It is another object of the present invention to provide a composite module capable of remarkably improving transmission / reception efficiency and transmission / reception distance of a wireless power signal and a data signal through a combined magnetic field power unit according to the present invention.

In order to improve the flexibility of the shielding unit and reduce the occurrence of eddy currents, the present invention has been made to solve at least the above problems, Wherein the Fe-based alloy debris has a magnetic shielding layer with a number of debris smaller than 500 m in particle size of 60% or more of the total number of debris.

According to an embodiment of the present invention, the magnetic shielding unit may further include a protective member disposed on one surface of the magnetic shield layer and an adhesive member disposed on the other surface of the magnetic shield layer.

In addition, the protective member is bonded to one surface of the magnetic shield layer through a first adhesive layer provided on one surface of the magnetic shield layer. The adhesive member is adhered to the other surface of the magnetic shield layer through a second adhesive layer provided on one surface, The dielectric included in the first adhesive layer and the second adhesive layer may be formed such that a part of the adhesive layer of at least one of the first adhesive layer and the second adhesive layer penetrates into the spacing space between the Fe alloy fragments.

In addition, the dielectric may be filled in all of the spaced spaces between adjacent Fe-based alloy debris.

The Fe-based alloy debris may be derived from an Fe-based amorphous alloy ribbon.

The Fe-based alloy may be an alloy containing iron (Fe), silicon (Si) and boron (B).

Further, the shape of the Fe-based alloy debris may be irregular.

In addition, the number of fragments having a particle diameter of less than 200 占 퐉 may be 50% or more of the total number of fragments of the Fe-based alloy fragments. More preferably, the number of fragments having a particle diameter of less than 100 占 퐉 may be less than 50% of the total number of fragments.

The magnetic shielding unit may include a plurality of magnetic shielding layers, and a dielectric layer may be interposed between adjacent magnetic shielding layers to adhere magnetic field shielding layers and reduce eddy currents.

At this time, one of the magnetic shield layers may have different permeability from the other magnetic shield layer.

The dielectric layer may be an insulating adhesive layer or a heat-dissipating adhesive layer.

Also, the thickness of the single layer of the magnetic shielding layer may be 15 to 35 mu m.

Further, the present invention provides a method of manufacturing a shielding unit, which is filled in at least a part of a space formed between a fragmented Fe-based alloy fragments and some adjacent ones of the fragments in order to improve the flexibility of the shielding unit and reduce eddy currents, And a magnetic shielding layer including a dielectric, and satisfies at least one of the following conditions (1) and (2) for the first antenna and the second antenna described below.

(1) An antenna having an outer diameter of 37.5 mm x 37.5 mm, which was formed by turning 16 turns of two coils of 0.26 mm in diameter, each of which was connected to an LCR meter on a rectangular magnetic shielding unit of 50 mm x 50 mm in width and length, The first antenna having an inductance (Ls) of 8.46 占 H and a resistivity (Rs) of 451 占 퐉 and a Q value of 11.8 was measured with an LCR meter under the condition of an inner diameter of 20 mm x 20 mm and a shape of a quadrangle (Q) of the first antenna measured by an LCR meter at a frequency of 100 kHz / 1 V in a state where the first antenna is held at a constant pressure after pressing the antenna at a constant pressure of 12.0 or more, (2) The antenna was formed by turning 16 turns of two coils having a diameter of 0.3 mm and connected to an LCR meter on a quadrangular magnetic field shielding unit having an outer diameter of 30.5 mm x 40.0 mm and an inner diameter of 20 mm x 27 mm, (Ls) of 3.59 占,, resistivity (Rs) of 126 m?, And a Q value of 100 mW / The quality factor (Q) of the second antenna measured by an LCR meter at a frequency of 100 kHz / 1 V in a state where the second antenna is held at a constant pressure after positioning the second antenna at 17.9 is 18.0 or more.

The present invention also provides a magnetic field shielding unit for wireless power transmission according to the present invention; And a wireless power transmission antenna unit disposed on the magnetic-field-shielding unit for wireless power transmission.

Further, the present invention provides a magnetic field shielding apparatus comprising: a first magnetic shielding unit; And a second magnetic-field-shielding unit having magnetic characteristics different from that of the first magnetic-field-shielding unit at a predetermined frequency.

The present invention also provides an antenna unit including at least one of an antenna for magnetic security and an antenna for short-range wireless communication (NFC) and a wireless power transmission antenna; And a combined magnetic field shielding unit disposed on one surface of the antenna unit to induce a magnetic field and improve antenna characteristics.

In addition, the present invention provides a portable device including a wireless power transmission module or a composite module according to the present invention as a receiving module.

According to the present invention, the magnetic field shielding unit for wireless power transmission minimizes the malfunction due to heat generation due to the generation of the eddy current and the electromagnetic interference of various signal processing circuit parts in the electronic parts provided in the portable equipment or the like owing to the magnetic field leaked in the wireless power transmission, It is possible to prevent degradation of function and durability of the parts and to minimize the influence of the leakage magnetic field on the health of the user of the portable device.

In addition, it is possible to improve the focusing of the magnetic field toward the antenna, reduce the magnetic loss due to eddy currents, etc., and combine with various kinds of antennas for wireless power transmission having various structures, shapes, sizes, and intrinsic characteristics (inductance, It is possible to further improve the inductance characteristic of the combined antenna itself and minimize the increase in the specific resistance characteristic of the antenna accompanied by the magnetic shielding unit, thereby more remarkably manifesting the characteristics of the antenna for wireless power transmission.

Furthermore, the combined-magnetic-field-shielding unit further improves the antenna characteristics of the antenna for wireless power transmission, thereby remarkably increasing the wireless power transmission efficiency and transmission distance, and improving the characteristics of the antennas involved in data communication and the like, The present invention can be widely applied to various mobile devices such as a mobile device including a wireless charging module or a composite module, a smart home appliance, or an Internet of Things device.

1 and 2 are sectional views showing a magnetic field shielding unit for wireless charging according to an embodiment of the present invention. FIG. 1 is a view showing a case where a part of a spacing space included in a magnetic shielding layer is filled with an insulator, Shows a case in which all of the spacing spaces are filled with an insulator,
3 is a photograph of a first antenna for measurement of a condition (1) according to the present invention,
Figure 4 is a photograph of a second antenna for measurement of condition (2) according to the invention
5 and 6 are schematic views illustrating a manufacturing process using a crushing apparatus used for manufacturing a magnetic field shielding unit according to an embodiment of the present invention, and FIG. 5 is a schematic view showing a manufacturing process using a crushing apparatus for crushing through a concavo- 6 is a view showing a manufacturing process using a crushing device for crushing through a metal ball provided on a support plate,
7 is a cross-sectional view of a magnetic field shielding unit for wireless charging according to an embodiment of the present invention having three layers of magnetic shielding layers including Fe-based amorphous alloy fragments,
8A is a view showing a case where the first magnetic-field shielding unit and the second magnetic-field shielding unit are laminated, FIG. 8B is a cross-sectional view of the second magnetic- FIG. 8C is a view showing a case where a first magnetic-field shielding unit is inserted at a thickness smaller than that of the second magnetic-field-shielding unit on one surface of a second magnetic-field-shielding unit; FIG. ,
9 is an exploded perspective view of a wireless charging module according to an embodiment of the present invention,
FIG. 10 is an exploded perspective view of a composite module according to an embodiment of the present invention, and FIG.
11 is a photograph of the shredding apparatus used in manufacturing the magnetic shielding unit according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

1, the magnetic shielding unit 100 for wireless power transmission according to an embodiment of the present invention includes a magnetic shielding layer 110, and the magnetic shielding layer 110 is formed of a fragment of an Fe- And at least a portion S1 and S3 of the spacing space S between the adjacent Fe-based alloy fragments 111a and 111b. The magnetic shielding unit 100 includes a protective member 140 adhered to the upper portion of the magnetic shielding layer 110 through a first adhesive layer 140b and an adhesive layer 140 disposed under the magnetic shielding layer 110, The adhesive member 130 may include a second adhesive layer 130b for adhering to the lower portion of the magnetic shielding layer 110 and a release film 130b for protecting the second adhesive layer 130b, (150) may be further provided.

First, the magnetic shielding layer 110 is formed of fragments 111 of a fractured Fe-based amorphous alloy for improving the flexibility of the shielding unit and reducing eddy currents. As shown in FIG. 1, the magnetic shield layer 110 is formed of shredded Fe-based alloy fragments 111a, 111b, 111c, and 111d, which is one single piece, for example, The resistivity is remarkably increased to suppress the occurrence of eddy currents. The resistivity value differs depending on the kind of the magnetic material, and the magnetic material having a remarkably high resistivity such as ferrite has a considerably small concern about the magnetic loss due to the eddy current. On the other hand, the Fe-based alloy, which is a magnetic material included in one embodiment of the present invention, has a remarkably small resistivity and thus has a large magnetic loss due to eddy current, so that it is difficult to exhibit the desired level of physical properties when the ribbon sheet is used. However, when the ribbon sheet is crushed, the fractured Fe-based alloy fragments have a remarkable increase in resistivity due to the presence of a space between the fragments, and the magnetic loss due to the eddy current is remarkably reduced. As a result, The inductance reduction of the antenna for wireless power transmission can be compensated.

On the other hand, the magnetic shielding layer 110 formed of the shredded fragments 111 can have excellent flexibility. This is because the ribbon sheet of an Fe-based alloy, for example, an Fe-based alloy, is remarkably small in elastic modulus and is strong in brittleness and is easily fragmented when an impact is applied or bent on the ribbon sheet. In order to satisfy the initial design property (Ex. There is a problem of property change such that the physical property value may be decreased more than the initially set physical property when the ribbon sheet is fragmented into minute pieces even if the ribbon sheet of the alloy is produced. Therefore, even if the magnetic material such as the manufactured ribbon sheet satisfies the initial design value, if the magnetic field shielding unit is changed during the manufacturing or use of the magnetic field shielding unit so that it does not satisfy the initial design property, the target wireless power transmission efficiency and transmission distance It may not be secured. In particular, recent electronic devices such as smart phones are designed to be lightweight and slim, so that the magnetic shielding unit is also required to be thinned, which can be more easily broken in the case of a very thin thickness ribbon sheet, and this problem becomes even more serious .

However, the magnetic field shielding unit included in the embodiment of the present invention is remarkably improved in flexibility of the shielding unit as the Fe-based alloy ribbon sheet is crushed from the beginning and is provided in a fragmented state, so that even if the thickness of the shielding unit is reduced, There is a possibility that cracks may be further generated in the Fe-based alloy fragments. In addition, the Fe-based alloy is included in the shielding unit in a fragmented state, and the initial physical property is designed so that the shielding unit including the Fe-based alloy in the fragmented state can exhibit excellent characteristics in the wireless power transmission from the beginning, Since the physical property values can be continuously maintained in the manufacturing step of the shielding unit, the assembly step of mounting the shielding unit in the antenna unit and the assembly step in the finished product, and the use stage of the finished product, the shielding unit having the ordinary non- It is possible to fundamentally eliminate a fear of a decrease in physical properties due to unintentional fragmentation that occurs and a significant decrease in power transmission / reception performance due to this.

The Fe-based alloy may be an alloy containing iron (Fe), silicon (Si), and boron (B). The Fe-based alloy may have a different composition from that of the three elements, for example, Cobalt (Co), nickel (Ni), or the like can be further added. The Fe-based alloy is preferably an alloy containing 70 to 90 at% of Fe. When the content of Fe is increased, the saturation magnetic flux density of the alloy can be increased, but on the contrary, a crystalline ribbon can be produced. The Si and B elements function to increase the crystallization temperature of the alloy to make the alloy more easily amorphous. The content of the Si and B elements is specifically 10 to 27 at% in the case of Si, 12 at%, but the present invention is not limited thereto and may be carried out in accordance with the desired properties.

The Fe-based alloy fragments may originate from an Fe-based amorphous alloy ribbon and may be heat-treated to control the desired permeability. The Fe-based alloy to which the heat treatment is applied may include amorphous or nano-crystal grains. The crystal phase of the Fe-based alloy may vary depending on the composition of the alloy, the composition ratio, and / or the heat treatment temperature / time.

On the other hand, with respect to the magnetic permeability of the Fe-based alloy, the magnetic material included in the conventional magnetic shielding material is advantageous for magnetic shielding as the permeability increases, but the relationship between the magnetic permeability and the antenna characteristics can not be regarded as a simple proportional relationship A too high permeability may not achieve the desired level of wireless power transmission efficiency and transmission distance. More specifically, when a single adult having a high permeability improves the inductance characteristic of the antenna in combination with the antenna for wireless power transmission, the increase in the specific resistance property of the antenna can be made larger than the increase in the inductance characteristic. In this case, the antenna characteristic may be lowered or the degree of improvement of the antenna characteristic may be smaller than that when the magnetic field shielding unit having a low magnetic permeability and the wireless power transmission antenna are combined. Therefore, it is preferable that the magnetic-field shielding layer is provided with the Fe-based alloy having an appropriate permeability so as to improve the inductance of the antenna when the magnetic-field shielding unit is combined with the antenna and minimize the increase of the resistivity, The permeability of the layer may be 100 to 1300, more preferably 100 to 1000.

However, since the temperature and the heat treatment time may differ depending on the specific composition ratio of the Fe-based alloy and the desired permeability, the temperature and time in the heat treatment process for the Fe-based alloy ribbon are not particularly limited.

Further, the Fe-based alloy debris may have an irregular shape as a single piece. Further, in the case where one edge of the Fe-based alloy debris is curved so as to have a curved surface or one surface thereof is curved, the magnetic shielding layer including the debris having such a shape increases in flexibility and is not unintended even when an external force is applied to the magnetic shielding unit There is an advantage that additional fine fragmentation of the fragments can be prevented.

The particle size of the crushed Fe-based alloy fragments may be 1 탆 to 5 탆, preferably 1 to 1000 탆. The particle size of the debris means a particle diameter measured through an optical microscope with respect to the debris, which means the longest distance from one point to another on the surface of the debris.

However, since the particle size of the Fe-based alloy particles satisfies the above-described preferable range of the particle diameter, the antenna characteristics can not be improved in all cases, and when adjusted to have a proper particle diameter distribution, The transmission antenna characteristics can be further improved.

For this purpose, the particle diameter distribution of the plurality of Fe-based alloy fragments 111 included in the magnetic shielding layer 110 is preferably 60% or more, more preferably 80% or more of the number of fragments having a particle diameter of less than 500 μm , And even more preferably at least 90%. If the number of the fragments having a particle diameter of less than 500 탆 is less than 60% of the total number of fragments, the magnetic permeability of the Fe-based alloy itself is high and the resistivity of the antenna coil is further improved, May be very insignificant, and the efficiency of a desired function such as wireless charging due to heat leakage due to eddy current and magnetic leakage may occur.

The grain size distribution of the plurality of Fe-based alloy fragments 111 included in the magnetic shielding layer 110 may be 50% or more of the number of fragments having a grain size of less than 200 占 퐉. If fragments having a particle size of less than 500 탆 are high but fragments having a particle diameter of less than 200 탆 are contained in a small amount, improvement of the eddy currents remarkably and generation of antenna characteristics may be insignificant, flexibility of the shielding unit may not be sufficient, There is a fear of fragmentation and deterioration of the physical properties. However, when the number of fragments of a fine particle size increases, the number of fragments having a particle diameter of less than 100 mu m may be less than 50% of the total number of fragments, because it is advantageous in improving flexibility but may cause deterioration of magnetic properties. .

Next, the dielectric 112 filled in at least a part of the spacing space between some adjacent fragments 111a / 111b, 111b / 111d of the Fe-based alloy fragments 111 will be described.

The dielectric material 112 further minimizes the eddy current generated by partially or totally insulating the adjacent Fe-based alloy debris and fixes the shattered Fe-based alloy debris 111 so as not to move within the magnetic shielding layer 110 And can prevent the alloy from being oxidized due to the permeation of moisture and to prevent further fracture or microfragmentation of the fragments 111 when an external force is applied or bent to the magnetic shielding layer.

As shown in FIG. 1, the dielectric 112 has a space S1, S2, S3 between the first Fe alloy fragments 111a and the second Fe alloy fragments 111b, S3 may be filled with the dielectrics 112a1 and 112a2 but may remain as a void space in a state where the dielectric is not filled in the spacing space S2 so that the Fe alloy fragments can be partially insulated.

On the other hand, as shown in FIG. 2, the dielectric 112 'may be filled in the spaces between the adjacent fragments 111a to 111d to insulate all of the Fe-based alloy fragments as shown in FIG.

The material of the dielectric body 112 and 112 'may be a material known as a dielectric material, and a material having adhesiveness in terms of fixing the Fe-based alloy fragments may be preferable, and a material having such properties May be used without limitation. As a non-limiting example, the dielectric material 112, 112 'may be a composition that is formed by curing the dielectric forming composition, formed by cooling after heat by heat, or exhibiting an adhesive force at room temperature under pressure. As an example of a composition that is cured to form a dielectric, the dielectric forming composition includes at least one of a thermoplastic resin and a thermosetting resin, and may include a curing agent. The dielectric forming composition may further comprise a curing accelerator and a solvent.

Specifically, the thermoplastic resin may be at least one selected from the group consisting of polyethylene, polypropylene, polystyrene, polyvinyl chloride, acrylonitrile-butadiene-styrene resin (ABS), acrylonitrile-styrene resin (AN), acrylic resin, methacrylic resin, (PET), polybutylene terephthalate (PBT), phenoxy resin, polyurethane resin, nitrile butadiene resin, and the like.

The thermosetting resin may contain at least one of a phenol resin (PE), a urea resin (UF), a melamine resin (MF), an unsaturated polyester resin (UP) and an epoxy resin, May be an epoxy resin. Examples of the epoxy resin include bisphenol A, bisphenol F, bisphenol S, canceled bisphenol A, hydrogenated bisphenol A, bisphenol AF, biphenyl, naphthalene, fluorene, phenol novolac, Novolak type, trishydroxylphenylmethane type, tetraphenylmethane type and the like, or the like can be used alone or in combination.

When the thermosetting resin is mixed with a thermoplastic resin, the content of the thermosetting resin may be 5 to 95 parts by weight based on 100 parts by weight of the thermoplastic resin.

The curing agent can be used without any particular limitation as long as it is a known one. Non-limiting examples of the curing agent include an amine compound, a phenol resin, an acid anhydride, an imidazole compound, a polyamine compound, a hydrazide compound and a dicyandiamide compound Or a mixture of two or more thereof. The curing agent is preferably composed of at least one material selected from an aromatic amine compound curing agent and a phenol resin curing agent. The aromatic amine compound curing agent or the phenolic resin curing agent has an advantage of less change in adhesion property even when stored at room temperature for a long period of time. Examples of the aromatic amine compound curing agent include m-xylene diamine, m-phenylenediamine, diaminodiphenylmethane, diaminodiphenylsulfone, diaminodearyl diphenylmethane, diaminodiphenyl ether, 1,3-bis (4 (4-aminophenoxy) phenyl] sulfone, 4,4'-bis (4-aminophenoxy) -Aminophenoxy) biphenyl, 1,4-bis (4-aminophenoxy) benzene, and the like, which may be used alone or in combination. Examples of the phenol resin curing agent include phenol novolac resins, cresol novolac resins, bisphenol A novolak resins, phenol aralkyl resins, poly-p-vinylphenol t-butylphenol novolak resins, and naphthol novolac resins. These may be used alone or in combination. The content of the curing agent is preferably 20 to 60 parts by weight per 100 parts by weight of the thermoplastic resin and / or the thermosetting resin. When the content of the curing agent is less than 10 parts by weight, the curing effect against the thermosetting resin is insufficient, On the other hand, if it exceeds 60 parts by weight, the reactivity with the thermosetting resin becomes high, and the physical properties such as handling property and long-term storage property of the magnetic shielding unit may be lowered.

Since the curing accelerator can be determined depending on the specific types of the thermosetting resin and the curing agent to be selected, the present invention is not particularly limited thereto, and examples thereof include amine, imidazole, phosphorus, boron, phosphorus - boron-based curing accelerators, which can be used alone or in combination. The content of the curing accelerator is preferably about 0.1 to 10 parts by weight, and more preferably 0.5 to 5 parts by weight per 100 parts by weight of at least one of the thermoplastic resin and the thermoplastic resin.

In addition, the dielectric material 112, 112 'formed through the dielectric composition described above penetrates into the spaced space between the Fe-based alloy fragments of at least one of the first adhesive layer 140b and the second adhesive layer 130b described later The composition of the dielectric and the adhesive layer of at least one of the first adhesive layer 140b and the second adhesive layer 130b may be the same.

The thickness of the magnetic shielding layer 110 including the above-described Fe-based alloy fragments 111 and the dielectric material 112 penetrating into the spacing space of the fragments is not limited to the above-mentioned Fe-based amorphous alloy ribbon And the thickness of one layer of the magnetic shielding layer 110 may be 15 to 35 占 퐉 except for the thickness of the dielectric covering one or both of the upper and lower layers of the fragments.

The shape of the magnetic shielding layer may be a polygonal shape such as a pentagon, a circle, an ellipse, or a shape in which a curved line and a straight line are mixed, in addition to a rectangular shape and a square shape corresponding to the shape of the application site to which the magnetic shielding unit is applied . For example, it may have the same shape (annular shape) corresponding to the shape of the antenna (Ex. Annular shape). At this time, it is preferable that the size of the magnetic shielding unit is about 1 to 2 mm larger than the corresponding antenna size.

1 or 2, a protective film 140a having a base film 140a and a first adhesive layer 140b formed on one surface of the base film 140a is formed on the magnetic shielding layers 110 and 110 ' The magnetic shielding layer 110 and 110 'may further include an adhesive member 130 at the bottom of the magnetic shielding layer 110 and 110'.

First, the base film 140a of the protective member 140 may be a protective film normally provided in the magnetic shielding unit. In the process of attaching the shielding sheet to the substrate having the antenna, the heat / pressure And the film is made of a material whose mechanical strength and chemical resistance are sufficient to protect the magnetic shielding layers 110 and 110 'against external physical and chemical stimuli Can be used. As a non-limiting example, polypropylene, polyimide, crosslinked polypropylene, nylon, polyurethane resin, acetate, polybenzimidazole, polyimideamide, polyetherimide, polyphenylene sulfide (PPS). (PET), polytrimethylene terephthalate (PTT) and polybutylene terephthalate (PBT), polyvinylidene fluoride (PVDF), polytetrafluoroethylene (PTFE) and polychlorotrifluoroethylene PCTFE), and polyethylene tetrafluoroethylene (ETFE), which may be used alone or in combination.

The base film 140a may have a thickness of 1 to 100 탆, preferably 10 to 30 탆, but is not limited thereto.

The protective member 140 may include a first adhesive layer 140b on one surface of the base film 140a and the protective member 140 may be bonded to the magnetic shielding layer 110 through the first adhesive layer 140b. Lt; / RTI > The first adhesive layer 140b may be a conventional adhesive layer, but may be a dielectric forming composition as described above. The first adhesive layer 140b minimizes the generation of eddy currents, and the first adhesive layer 140b may be formed on the magnetic shielding layer 110 The compatibility with the dielectric material 112 can be increased and an improved adhesion can be exhibited. Accordingly, the composition of the dielectric 112 and the composition of the first adhesive layer 140b may be the same, but are not limited thereto. The thickness of the first adhesive layer 140b may be 3 to 50 탆, but is not limited thereto and may be changed according to the purpose.

Next, the adhesive member 130 serves to attach the magnetic field shielding units 100 and 100 'to an antenna or a substrate provided with the antenna. 1, the adhesive member 130 may include a second adhesive layer 130b for attaching the magnetic field shielding unit 100 or 100 'to a surface to be attached, and the second adhesive layer 130b may include a second adhesive layer 130b, And a release film 130a for protecting the optical disc 100a. The release film 130a can be used without limitation in the case of a known release film which can be easily removed from the second adhesive layer 130b, and the present invention is not particularly limited thereto.

The second adhesive layer 130b may be formed by applying an adhesive composition to the lower portions of the magnetic shielding layers 110 and 110 'or by forming a second adhesive layer 130b, which is formed by applying an adhesive composition on the release film 130a, May be attached to the layers 110 and 110 '. Alternatively, the second adhesive layer may be a double-sided adhesive member coated with an adhesive on both sides of the film-shaped supporting substrate to reinforce the mechanical strength. The adhesive layer formed on the supporting substrate may be a lower surface of the magnetic shielding layer 110 or 110 ' And the release film 130a may be adhered until the one adhesive layer formed on the lower portion of the supporting substrate is adhered to the adherend surface.

In addition, the second adhesive layer 130b penetrates into the space formed by separating the Fe-based debris existing on the inner side of the shielding layer from the one surface portion of the magnetic shielding layer to be attached, so that the Fe-based debris can be partially or completely isolated . The second adhesive layer 130b may be derived from the dielectric materials 112 and 112 'described above. Accordingly, the adhesive composition for forming the second adhesive layer 130b may be the dielectric forming composition described above. Even if the second adhesive layer 130b does not originate from the dielectric layers 112 and 112 'described above, it is possible to improve the adhesive strength by increasing the compatibility between the second adhesive layer 130b and the dielectric layers 112 and 112' provided in the magnetic- The composition for forming the second adhesive layer 130b may be the same as the dielectric-forming composition described above, but the present invention is not limited thereto and may be a different composition.

Meanwhile, the magnetic-field shielding unit 100 or 100 'according to the present invention shields a magnetic field leaked to the outside and further focuses the magnetic field with a radio-power transmission antenna and a radio-power reception antenna which are opposed to each other, (1) and (2) are satisfied with respect to the first antenna and the second antenna as described below in accordance with significantly lowering the antenna characteristics.

First, the first antenna connected to the LCR meter is placed on a quadrangular magnetic field shielding unit having a size of 50 mm x 50 mm in width and a condition of 100 kHz / 1 V The quality factor (Q) of the first antenna measured by the LCR meter may be 12.0 or more, preferably, 14.0 or more.

As shown in FIG. 3, the first antenna is an antenna formed by turning 16 turns of two coils having a diameter of 0.26 mm, an outer diameter of 37.5 mm x 37.5 mm, an inner diameter of 20 mm x 20 mm, Square and has an inductance (Ls) of 8.46 μH, a specific resistance (Rs) of 451 mΩ, and a Q value of 11.8 when measured with an LCR meter under the condition of 100 kHz /

The influence of the magnetic field shielding unit on the inductance characteristic and the resistivity characteristic of the first antenna coil can be evaluated through the above condition (1). If the magnetic field shielding unit satisfies the condition (1) It is possible to achieve an improved wireless power transmission efficiency / transmission distance and / or a data transmission efficiency / transmission distance in the case of using for transmission / reception of a wireless power signal or transmission of various data signals.

Next, as a condition (2), a second antenna connected to the LCR meter is placed on a quadrangular magnetic field shielding unit of 50 mm x 50 mm in width and 100 kHz / 1 V The quality factor (Q) of the second antenna measured by the LCR meter satisfies 18.0 or more.

As shown in FIG. 4, the second antenna is an antenna formed by turning 16 turns of two coils having a diameter of 0.3 mm, an outer diameter of 30.5 mm 40.0 mm, an inner diameter of 20 mm 27 mm, And is an antenna having an inductance (Ls) of 3.59 占 H, a specific resistance (Rs) of 126 m? And a Q value of 17.9 when measured with an LCR meter under the condition of 100 kHz /

The influence of the magnetic field shielding unit on the inductance characteristic and the resistivity characteristic of the second antenna coil can be evaluated through the above condition (2). If the magnetic field shielding unit satisfies the condition (2) It is possible to achieve an improved wireless power transmission efficiency / transmission distance and / or a data transmission efficiency / transmission distance in the case of using for transmission / reception of a wireless power signal or transmission of various data signals.

Therefore, if the magnetic-field-shielding unit according to the embodiment of the present invention satisfies the conditions (1) and (2) at the same time, various kinds of wireless Even when combined with the power transmission antennas, the characteristics of the combined antenna can be significantly increased at the same time, so that the physical properties suitable for wireless charging can be more easily and remarkably expressed.

The magnetic field shielding unit according to an embodiment of the present invention may be manufactured by a manufacturing method described below, but the present invention is not limited thereto.

First, step (a) of preparing a heat-treated Fe-based alloy ribbon may be performed. The Fe-based alloy ribbon may be produced by a known method such as rapid cooling solidification (RSP) by melt spinning. The manufactured Fe-based alloy ribbon may be subjected to a heat treatment process to adjust the permeability after cutting so as to have a predetermined width. The annealing temperature may be selected depending on the composition of the Fe-based alloy, the composition ratio, and the degree of the magnetic permeability of the desired amorphous alloy. In order to exhibit excellent physical properties over a desired operating frequency range, To 600 ° C, more preferably 400 ° C to 500 ° C, and still more preferably 440 ° C to 480 ° C for 30 minutes to 2 hours. If the heat treatment temperature is less than 300 ° C, the permeability may be too low or too high as compared with the desired permeability level, the brittleness may be weak and it may be difficult to fracture due to fracture, and the heat treatment time may be prolonged. Also, when the heat treatment temperature exceeds 600 ° C, there is a problem that the permeability is significantly lowered.

Next, step (b) of forming a dielectric material in the spacing space between the Fe-based alloy fragments produced by shattering the Fe-based alloy ribbon can be performed.

One embodiment of the step (b) is characterized in that a protective member having a first adhesive layer formed on one side of an Fe-based alloy ribbon is adhered, and an adhesive member having a second adhesive layer formed on the other side thereof is adhered, So that the Fe-based alloy ribbon can be sliced into irregular pieces. Thereafter, pressure is applied to the laminate to penetrate the first adhesive layer and the second adhesive layer into the spaced spaces between the Fe alloy fragments to fix and support the fragments, and insulate the fragments from each other to significantly reduce the generation of eddy currents, It is possible to prevent the amorphous alloy from being oxidized. The method of applying pressure to the laminate may be carried out in such a manner that pressure is applied to the laminate together with the crushing in the crusher or a separate pressing process is performed to further increase the degree of penetration of the first and second adhesive layers after the laminate is crushed You can do more.

Specifically, as shown in FIG. 5, a plurality of first rollers 11 and 12 having projections and depressions 11a and 12a and second rollers 21 and 22 corresponding to the first rollers 11 and 12, respectively, The laminate 100a is crushed and pressed by passing the laminate 100a through the crusher having the third roller 13 and the fourth roller 23 corresponding to the third roller 13 The magnetic layer shielding unit 100 can be manufactured by further pressing the laminate 100b.

6, a support plate 30 having a plurality of metal balls 31 mounted on one surface thereof and rollers 41 and 42 positioned above the support plate 30 for moving the object to be crushed A laminate 100a including an Fe-based alloy ribbon sheet is placed in a crushing apparatus provided therein, and pressure is applied through the metal ball 31 to break the ribbon sheet. The shape of the ball 31 may be spherical, but is not limited thereto. The shape of the ball 31 may be triangular, polygonal, ellipse, or the like. The shape of the ball provided in the single first roller may be one shape, .

As shown in FIG. 7, the magnetic shielding unit 100 '' includes a plurality of magnetic shielding layers 110A, 110B and 110C, and an eddy current is generated between the adjacent magnetic shielding layers 110A / 110B and 110B / The dielectric layers 131 and 132 may be interposed. In some cases, if a shielding unit is implemented by using only a single magnetic shielding layer and combined with an antenna for wireless power transmission, the transmission efficiency of a desired level of a wireless power signal may not be exhibited. Accordingly, the magnetic-field shielding unit according to an embodiment of the present invention includes a plurality of magnetic shielding layers to increase the magnetic shielding capacity, thereby further improving the inductance of the antenna for wireless power transmission, while increasing the specific resistance relatively It may be more suitable to achieve a high quality index and achieve excellent wireless power transmission efficiency and transmission distance.

When a plurality of magnetic shielding layers are provided in the magnetic shielding unit, the magnetic shielding layer preferably has 2 to 10, more preferably 2 to 4, magnetic shielding layers, but is not limited thereto. On the other hand, if the number of laminated layers of the magnetic shielding layer is more than 10, the resistivity of the magnetic field shielding layer is increased compared to the increase of the inductance of the wireless power transmission antenna. The quality factor of the antenna may be insignificantly increased, and the thickness of the antenna may be increased, which may be undesirable for thinning the capacitor unit.

When a plurality of magnetic shielding layers 110A, 110B and 110C are provided as shown in FIG. 7, dielectric layers 131 and 132 are formed between adjacent magnetic shielding layers 110A / 110B and 110B / 110C to reduce eddy currents. 132 may be interposed, and the dielectric layers 131, 132 may be an insulating adhesive layer. At this time, the insulating adhesive layer may be formed through the dielectric forming composition described above. Specifically, a plurality of Fe-based alloy ribbons are laminated via the insulating adhesive layers 131 and 132, and the ribbon is crushed to form a magnetic shielding unit 100 " having a plurality of magnetic shielding layers 110A, 110B and 110C In this case, the dielectric included in the upper portion of the second magnetic shielding layer 110B adjacent to the lower portion of the first magnetic shielding layer 110A may be a dielectric that is interposed between the two magnetic shielding layers 110A and 110B The adhesive layer 131 may be formed so as to penetrate into the spacing space between the lower portion of the first magnetic shielding layer 110A and the Fe-based debris located in the upper portion of the second magnetic shielding layer 110B. The thicknesses of the adhesive layers 131 and 132 may be selected from the group consisting of a first adhesive layer 130b of a protective member and a second adhesive layer 130b which may be provided on a lower portion of the laminated magnetic shielding layers 110A, 110B, 2 adhesive layer 140b, It is not.

In another embodiment, the dielectric layers 131 and 132 may be a heat-dissipating adhesive layer. The heat-dissipating adhesive layer may be formed by mixing a known heat dissipation filler such as nickel, silver, or carbon with an adhesive component such as acrylic, urethane, And the specific composition and content thereof may be in accordance with a known composition and content, so that the present invention is not particularly limited thereto.

When a plurality of the magnetic shielding layers 110A, 110B, and 110C are provided, the compositions of the Fe-based alloys included in the respective magnetic shielding layers may be the same or different. Also, even though the composition is the same, the magnetic permeability of each of the magnetic shielding layers may be different due to the difference in heat treatment time and the like. The thickness of each of the magnetic shielding layers may be the same or different depending on the purpose.

The magnetic field shielding unit 100, 100 ', 100 " for wireless power transmission according to an embodiment of the present invention may be applied to the Qi scheme, and a portion of the magnetic field lines generated from the permanent magnets may be connected to an attractor The present invention can be applied to a PMA-based wireless charging method that is induced through a wireless communication system. In addition, it is noted that the magnetic field shielding unit 100, 100 ', 100 "for wireless power transmission according to an embodiment of the present invention can be applied to a self-resonance method in which wireless charging is performed at a frequency of several tens of kHz to 6.78 MHz.

Meanwhile, the magnetic field shielding unit for wireless power transmission according to the present invention further includes a magnetic shielding unit of different kind in addition to the magnetic shielding unit including the above-described Fe alloy fragments to realize a combined magnetic shielding unit, Quot; means a shielding unit having magnetic characteristics different from that of the first magnetic-field shielding unit at a predetermined frequency.

The magnetic property may refer to a magnetic characteristic inherent to a magnetic body included in a shielding unit such as a saturated magnetic field, a permeability, and an investment loss ratio, etc., as a magnetic characteristic expressed by a shielding unit.

Referring to FIG. 8A, the complex magnetic-field shielding unit 1000 includes a first magnetic-field-shielding unit, which is a magnetic-field shielding unit for wireless power transmission having a magnetic-field shielding layer 110, 110 ' And a second magnetic shielding unit 1200 having a magnetic characteristic different from that of the first magnetic shielding unit 1100 at a predetermined frequency. When the two shielding units 1100 and 1200 are stacked, The first magnetic-field shielding unit 1100 and the second magnetic-field shielding unit 1200 may be mutually attached through an adhesive layer (not shown), and a first adhesive layer 1400b may be formed on one surface And a bonding member 1300 having a second adhesive layer 1300b formed on a lower surface of the second magnetic shielding unit 1200 may be further provided.

A magnetic shielding unit comprising heterogeneous shielding sheets with different magnetic properties at a given frequency may be adapted to improve the respective antenna characteristics in a composite antenna unit having two or more antennas operating in different frequency bands. For example, the first magnetic-field-shielding unit 1100 may be configured to have a relatively higher magnetic permeability than the second magnetic-field-shielding unit 1200 in a frequency band of 100 to 300 kHz, which is a low- The first magnetic field shielding unit 1100 and the second magnetic shielding unit 1200 may be arranged to have a relatively larger saturation magnetic field than the second magnetic field shielding unit 1200 in the frequency band of 100 to 300kHz, The investment loss rate of the first magnetic field shielding unit 1100 may be set to be relatively smaller than the investment loss rate of the second magnetic field shielding unit 1200. [

In this specific example, when the second magnetic shielding unit 1200 including the ferrite sheet as a magnetic body includes the first magnetic shielding unit 1100 including the above-described wireless charging magnetic shielding unit 100, 100 ', 100 " ). ≪ / RTI >

Since the first magnetic-field-shielding unit 1100 has a relatively higher magnetic permeability than the second magnetic-field-shielding unit 1200 in the frequency band of 100 to 300 kHz, the first magnetic-field shielding unit 1100 has a magnetic permeability of 100 to 300 kHz transmitted from the non- The AC magnetic field generated in accordance with the power signal is induced to the first magnetic-field shielding unit 1100 side having a relatively high magnetic permeability, so that the first antenna disposed on the first magnetic-shielding unit 1100 side can transmit the radio- So that it can be received. Also, since the second magnetic-field-shielding unit 1200 has a relatively higher magnetic permeability than the first magnetic-field-shielding unit 1100 in the frequency band of 13.56 MHz, when the short-range wireless communication (NFC) is performed, The alternating magnetic field generated by the 13.56 MHz high frequency signal is guided to the second magnetic field shielding unit 1200 side having a relatively high magnetic permeability at the corresponding frequency so that the radio frequency signal to the NFC antenna disposed on the second magnetic shielding unit 1200 side Can be received with high efficiency.

Also, even though the first magnetic-field shielding unit 1100 and the second magnetic-field shielding unit 1200 have the same permeability in a frequency band of 100 to 300 kHz, the investment loss rate of the first magnetic- The loss rate of the magnetic permeability due to the investment loss rate at the time of wireless power transmission is reduced as a result of having the value relatively smaller than the investment loss rate of the magnetic field shielding unit 1200. [

Meanwhile, the ferrite sheet included in the second magnetic-field-shielding unit 1200 may be relatively high in the ratio of the real part and the imaginary part of the complex permeability than the Fe-based alloy fragments in the frequency band of 13.56 MHz, The AC magnetic field generated by the 13.56 MHz high frequency signal generated from the antenna installed in the RF reader is induced to the second magnetic shield unit 1200 side having a relatively high real / imaginary part ratio, Frequency signal to the NFC antenna disposed in the region corresponding to the antenna 1200 in a high efficiency.

Also, even though the first magnetic-field shielding unit 1100 and the second magnetic-field shielding unit 1200 have the same magnetic permeability at a frequency of 13.56 MHz, the investment loss rate of the second magnetic- Unit 1100 has a relatively smaller value than the investment loss rate of the unit 1100, the loss of the permeability due to the investment loss rate in the short distance wireless communication (NFC) is reduced. Accordingly, the alternating magnetic field generated by the 13.56 MHz high frequency signal generated in the RF reader is directed to the second magnetic shield unit 1200 having a relatively high magnetic permeability, so that the NFC So that the high-frequency signal can be received at a high efficiency.

On the other hand, the arrangement relationship of the first magnetic shielding unit 1100 and the second magnetic shielding unit 1200 may be arranged to correspond to each antenna position performing a different function, and thus the second magnetic shielding unit 1200 The first magnetic shielding unit 1100 having the same thickness as the first magnetic shielding unit 1200 may be inserted into the second magnetic shielding unit 1200 (see FIG. 8B) A first magnetic shielding unit 1100 having a thickness may be inserted into one surface of the second magnetic shielding unit 1200 (see FIG. 8C).

The second magnetic-field-shielding unit 1200 includes a magnetic body such that the second magnetic-field-shielding unit 1200 has different magnetic characteristics from the first magnetic-field-shielding unit 1100 at a predetermined frequency. The second magnetic- Layer or may be layered in the form of a polymer sheet in which the magnetic powder is dispersed in the polymer.

The magnetic body included in the second magnetic-field-shielding unit 1200 is a known magnetic body that can be provided in the magnetic-field-shielding unit. The magnetic body included in the second magnetic-shielding unit 1200 may have a magnetic characteristic different from that at a predetermined frequency Mn-Zn ferrite, super-core (Fe-Si), FeSiCr, permalloy, MPP (Moly), and the like can be used without limitation, -Permalloy Powder) and a sandstarch. The amorphous alloy may be an amorphous ribbon made of any one of Fe, Co, and Ni amorphous alloys.

The magnetic field shielding unit 100, 100 ', 100 "or the multiple magnetic shielding unit 1000, 1000', 1000" of the various embodiments according to the present invention may be provided with electromagnetic shielding and / Or a function layer (not shown) for performing heat dissipation. Thus, it is possible to prevent the magnetic field shielding unit having the function layer from significantly increasing the frequency fluctuation width of the antenna combined with electromagnetic waves such as power supply noise Therefore, it is possible to prevent degradation of durability of parts due to heat generation, deterioration of function, and discomfort due to heat transfer to a user. If the functional layer provided on the top and / or bottom of the magnetic shielding unit has a heat dissipating function, the magnetic shielding unit can improve the thermal conductivity in the horizontal direction, and the magnetic shielding layer included in the magnetic shielding unit may be fine Since the air is contained in the space, it can function as a heat insulating layer in which the thermal conductivity of the magnetic shielding layer in the vertical direction is suppressed due to the heat insulating effect by the air in the micro space.

Specifically, the electromagnetic shielding layer, the heat dissipation layer, and / or the composite layer in which the electromagnetic wave shielding layer, the heat dissipation layer, and / or the multilayer structure are stacked on the protective member 130 of the magnetic field shielding unit 100 and / The functional layer may be provided. For example, a metal foil, such as copper or aluminum, having excellent thermal conductivity and electrical conductivity can be attached to the upper portion of the protection member 130 through an adhesive or double-sided tape. Or a combination of these metals may be formed on the protective member 130 by a known method such as sputtering, vacuum deposition, chemical vapor deposition, or the like, for example, Cu, Ni, Ag, Al, Au, Sn, Zn, Mn, Mg, Cr, To form a metal thin film. When the functional layer is provided through an adhesive, the adhesive may be a known adhesive. For example, an acrylic, urethane, or epoxy adhesive may be used. On the other hand, it is also possible to impart a heat radiation performance to the adhesive. To this end, a known filler such as nickel, silver or carbon material may be mixed with the adhesive, and the content of the filler is not limited to the heat radiation performance The present invention is not particularly limited thereto.

In addition, the thickness of the functional layer may be 5 to 100 mu m, and more preferably 10 to 20 mu m to reduce the thickness of the magnetic shielding unit.

The magnetic field shielding unit 100, 100 ', 100 " for wireless power transmission according to an embodiment of the present invention includes the magnetic field shielding unit 100' and the wireless power transmission antenna 152 as shown in FIG. 9, And an antenna unit 150 having a plurality of antennas. The wireless power transmission module may be a wireless power transmission module for transmitting a wireless signal to the electronic device or a wireless power receiving module for receiving a wireless signal from the wireless power transmission module. In addition, the antenna for wireless power transmission 152 may be an antenna coil wound with a coil having a predetermined inner diameter or may be an antenna pattern printed with an antenna pattern on a substrate, , Size, material, etc. are not particularly limited in the present invention.

In addition, the composite shielding unit 1000, 1000 ', 1000 " according to an embodiment of the present invention may include at least one of an antenna for magnetic security and an antenna for short-range wireless communication (NFC) And can be disposed on one side of the antenna unit including the antenna unit to implement the composite unit. 10, the composite module includes an antenna unit 1500 and a composite shielding unit 1000 '. The antenna unit 1500 includes a short-range wireless communication antenna 1540 provided at the outermost portion of the circuit board 1510 A magnetic security antenna 1530 and a wireless power transmission antenna 1520 which are sequentially and internally spaced apart from each other and may include an adhesive member 1530 provided under the complex magnetic field shielding unit 1000 ' May be attached to the antenna unit (1500) through the antenna unit (1300 ') to form a composite module.

Further, the wireless power transmission module or the composite module according to an embodiment of the present invention may include a wireless power receiving module for receiving a transmitted wireless power signal or a composite receiving module for receiving transmitted wireless power / data. Whereby the wireless charging efficiency, the data receiving efficiency and the charging distance or the data receiving distance can be remarkably improved

The present invention will now be described more specifically with reference to the following examples. However, the following examples should not be construed as limiting the scope of the present invention, and should be construed to facilitate understanding of the present invention.

≪ Example 1 >

Rapid Solidification by Melt Spinning (RSP) Fe _{91 . 6} Si ₂ B ₆ Co _{0 . 2} Ni _{0 .2} amorphous alloy ribbon was cut into a sheet shape and then a 24 탆 thick ribbon sheet was subjected to heat treatment at 460 캜 for 1 hour in an air atmosphere to prepare a ribbon sheet. Thereafter, a double-sided tape (support base PET, KYWON CORP., VT-8210C) having a thickness of 10 mu m and a release film adhered to one surface of the ribbon sheet was attached. PET protective (International Latex, KJ-0714) was attached, and then a crushing device as shown in Figs. 6 and 11 was passed through the crusher three times to manufacture a magnetic shielding unit as shown in Table 1 below.

≪ Examples 2 to 10 >

A magnetic field shielding unit as shown in Table 1 or Table 2 below was prepared by changing the permeability and / or the number of crushing times of the ribbon sheet as shown in Table 1 or 2 below.

≪ Comparative Example 1 &

A magnetic field shielding unit as shown in Table 2 below was manufactured by performing the same procedure as in Example 1,

<Experimental Example 1>

The following properties of the magnetic shielding unit prepared through Examples and Comparative Examples were evaluated and shown in Tables 1 to 3 below.

1. Analysis of Particle Size Distribution of Fragments

The adhesive protective film provided on one side of the magnetic shielding unit specimen having a width of 10 mm and a length of 10 mm was peeled off and the particle size of the fragment was measured with an optical microscope to determine the number of fragments having a particle diameter of less than 500 占 퐉, The number of fragments having a particle diameter of less than 100 占 퐉 and the total number of fragments were counted, and the ratio of fragments smaller than 500 占 퐉, fragments smaller than 200 占 퐉 and fragments smaller than 100 占 퐉 were calculated. At this time, the average particle fractions of five specimens were measured by measuring the particle diameters of five specimens.

2. Antenna Characterization

The inductance and quality index for the first antenna and the second antenna were measured by the following measuring methods (1) and (2) and are shown in Table 1.

Measurement method (1)

A first antenna connected to an LCR meter (HIOKI, IM3523 LCR METER) was placed on a square magnetic field shielding unit of 50 mm x 50 mm, and a Teflon jig with a weight of 500 g was placed on the first antenna, While holding the antenna, measure the inductance and quality index of the first antenna coil with the LCR meter (HIOKI, IM3523 LCR METER) under the condition of 100kHz / 1V.

* First antenna

3, which was formed by 16 turns of two coils having a diameter of 0.26 mm and a diameter of 0.25 mm. The antenna had an outer diameter of 37.5 mm x 37.5 mm, an inner diameter of 20 mm x 20 mm, a rectangular shape, and a condition of 100 kHz / Inductance (Ls) of 8.46 μH, resistivity (Rs) of 451 mΩ and a Q value of 11.8 when measured with an LCR meter (HIOKI, IM3523 LCR METER)

Measurement method (2)

A second antenna connected to an LCR meter (HIOKI, IM3523 LCR METER) was placed on a square magnetic field shielding unit of 50 mm x 50 mm and a Teflon jig with a weight of 500 g was placed on the second antenna, While holding the antenna, measure the coil inductance and quality index of the second antenna with the LCR meter (HIOKI, IM3523 LCR METER) under the condition of 100kHz / 1V.

* Second antenna

4, which is formed by 16 turns of two coils each having a diameter of 0.3 mm, and has an outer diameter of 30.5 mm x 40.0 mm, an inner diameter of 20 mm x 27 mm, an elliptical shape, a condition of 100 kHz / Inductance (Ls) of 3.59 μH, resistivity (Rs) of 126 mΩ and a Q value of 17.9 when measured with an LCR meter (HIOKI, IM3523 LCR METER)

Example 1 Example 2 Example 3 Example 4 Example 5 Example 6 Example 7 Magnetic field shielding unit Type of magnetic body Fe _91.6 Si ₂ B ₆ Co _0.2 Ni _0.2 Investment ratio 500 700 900 500 500 500 500 Number of layers One One One One One One One Thickness of magnetic shielding layer (탆) 27 27 27 27 27 27 27 Crushing frequency / frequency ○ / 6 ○ / 6 ○ / 6 ○ / 4 ○ / 3 ○ / 2 ○ / 5 Particle size
Distribution Less than 500 탆 (number%) 98 100 100 82 77 63 92 Particle size less than 200 탆 (number%) 58 82 80 44 32 22 52 Particle diameter less than 100 탆 (number%) 20 32 40 17 4 0 10 Properties The first antenna Inductance (μH) 11.5 12.2 12.8 11.5 11.4 11.4 11.5 Resistivity (mΩ) 487 503 510 525 569 581 512 Quality Index (Q) 14.85 15.26 15.75 13.76 12.59 12.33 14.11 The second antenna Inductance (μH) 4.94 5.16 5.40 4.91 4.91 4.90 4.93 Resistivity (mΩ) 149 156 163 159 173 179 155 Quality Index (Q) 20.08 20.78 20.78 19.33 17.77 17.14 19.94

Example 8 Example 9 Example 10 Comparative Example 1 Magnetic field shielding unit Type of magnetic body Fe _91.6 Si ₂ B ₆ Co _0.2 Ni _0.2 Investment ratio 500 500 350 500 Number of layers One One One One Thickness of magnetic shielding layer (탆) 27 27 27 27 Crushing frequency / frequency ○ / 8 ○ / 9 ○ / 6 ○ / 1 Particle size
Distribution Less than 500 탆 (number%) 100 100 92 52 Particle size less than 200 탆 (number%) 72 79 54 8 Particle diameter less than 100 탆 (number%) 46 53 16 0 Properties The first antenna Inductance (μH) 11.2 10.8 11.01 11.4 Resistivity (mΩ) 476 483 476 606 Quality Index (Q) 14.79 14.04 14.55 11.81 The second antenna Inductance (μH) 4.52 4.38 4.73 4.91 Resistivity (mΩ) 143 143 146 199 Quality Index (Q) 19.79 18.52 20.03 15.44

As can be seen from Tables 1 and 2,

In the case of Comparative Example 1 in which the number of the fragments having a particle diameter of less than 500 탆 is less than 60% of the total number of fragments, it can be confirmed that the quality indexes for the first antenna and the second antenna are lowered in comparison with the embodiment, It can be expected that the transmission / reception efficiency / transmission / reception distance of the power signal is not good.

Further, even in the case where the number of fragments having a particle diameter of less than 500 占 퐉 is 60% or more of the total number of fragments, in the case of Example 4 in which the number of fragments having a particle diameter of less than 200 占 퐉 is less than 50% It can be confirmed that the quality indexes for the first antenna and the second antenna are degraded.

In the case of Example 9 in which the number of micro-fragments increases and the number of fragments having a particle diameter of less than 100 占 퐉 is 50% or more of the total number of fragments, the quality for the first antenna and the second antenna It can be confirmed that the index is decreased.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100, 100 ', 100 ": magnetic field shielding unit for wireless power transmission
110, 110 ', 110 &quot;: magnetic field shield layer
130: first adhesive member 140: protective member
150: Antenna unit for wireless power transmission
1000, 1000 &quot;, 1000 &quot;: Combined magnetic field shielding unit
1100, 1100 ', 1100 &quot;: first magnetic-field shielding unit
1200, 1200 ', 1200 &quot;: second magnetic field shielding unit
1300, 1300 ', 1300 ": Adhesive members 1400, 1400', 1400"
1500: Antenna unit

Claims (15)

And a dielectric material filled in at least a part of the spaced space formed between the fragments of the Fe-based alloy and the adjacent fragments of the fragments so as to improve the flexibility of the shielding unit and reduce the occurrence of eddy currents, Wherein the fragments of the Fe-based alloy have a particle size of less than 500 占 퐉 of at least 60% of the total number of fragments, at least 50% of the total number of fragments having a particle size of less than 200 占 퐉, Wherein the magnetic shielding layer is less than 50% of the total number of fragments. 2. The apparatus of claim 1, wherein the magnetic shielding unit
And a shielding member disposed on one side of the magnetic shielding layer and an adhesive member disposed on the other side of the magnetic shielding layer. 3. The method of claim 2,
The protective member is bonded to one surface of the magnetic shield layer through a first adhesive layer provided on one surface of the magnetic shield layer. The adhesive member is bonded to the other surface of the magnetic shield layer through a second adhesive layer provided on one surface, Wherein the dielectric material is formed by a part of the adhesive layer of at least one of the first adhesive layer and the second adhesive layer penetrating into the spacing space between the Fe alloy fragments. The method according to claim 1,
Wherein the Fe-based alloy is derived from an Fe-based amorphous alloy ribbon, and the crystalline phase is amorphous or comprises nanocrystalline grains. The method according to claim 1,
Wherein the Fe-based alloy comprises iron (Fe), silicon (Si), and boron (B). The method according to claim 1,
Wherein the magnetic shielding unit comprises a plurality of magnetic shielding layers and a dielectric layer interposed between adjacent magnetic shielding layers for adhering between the magnetic shielding layers and for reducing eddy currents. delete The method according to claim 1,
Wherein the magnetic shielding layer has a single layer thickness of 15 to 35 占 퐉. The method according to claim 6,
Wherein the dielectric layer is an insulating adhesive layer or a heat dissipation adhesive layer. delete The method according to claim 1,
A magnetic-field shielding unit for wireless power transmission that satisfies at least one of the following conditions (1) and (2) for the following first and second antennas:
(1) A first antenna connected to a LCR meter was placed on a square magnetic field shielding unit having a length of 50 mm and a length of 50 mm, and then the first antenna was pressed with a Teflon jig having a weight of 500 g under the condition of 100 kHz / (Q) of the first antenna measured by an LCR meter is 12.0 or more, and the first antenna is formed by 16 turns of two coils having a diameter of 0.26 mm and an outer diameter of 37.5 mm (Ls) of 8.46 占,, resistivity (Rs) of 451 m? And a Q value of 11.8 when measured with an LCR meter under the condition of 100 kHz / 1V.
(2) A second antenna connected to the LCR meter was placed on a rectangular magnetic shielding unit having a size of 50 mm in length and 50 mm in length. Then, a Teflon jig with a weight of 500 g was pressed in a condition of 100 kHz / (Q) of the second antenna measured by an LCR meter is 18.0 or more, and the second antenna is formed by 16 turns of two coils having a diameter of 0.3 mm. The antenna has an outer diameter of 30.5 mm (Ls) of 3.59 μH, resistivity (Rs) of 126 mΩ, and a Q value of 17.9 when measured with an LCR meter under the condition of 100 kHz / 1 V and an elliptical shape with an inner diameter of 20 mm × 27 mm. A magnetic field shielding unit for wireless power transmission according to any one of claims 1 to 6, 8, 9 and 11; And
And a wireless power transmission antenna unit disposed on the magnetic-field-shielding unit for wireless power transmission. A magnetic field shielding unit for wireless power transmission according to any one of claims 1 to 6, 8, 9 and 11, comprising: a first magnetic-shielding unit; And
(NFC) magnetic shielding unit having a magnetic characteristic different from that of the first magnetic shielding unit at a frequency of 13.56 MHz,
Wherein the first magnetic shielding unit and the second magnetic shielding unit have the same thickness and the first magnetic shielding unit is disposed inside the second magnetic shielding unit so that the second magnetic shielding unit is disposed on the periphery of the first magnetic shielding unit Wherein the magnetic field shielding unit comprises: An antenna unit including at least one of an antenna for magnetic security and an antenna for short-range wireless communication (NFC) and an antenna for wireless power transmission; And
The composite module according to claim 13, which is disposed on one surface of the antenna unit to induce a magnetic field and improve antenna characteristics. A portable device comprising the wireless power transmission module according to claim 12 as a wireless power receiving module.

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