KR101516005B1 - Near Field Communication Antenna using wire - Google Patents

Abstract

The present invention relates to a near field communications (NFC) antenna using a wire. The invention includes: a wire part with more than one wire; an antenna which combines more than one wire parts in various patterns and is connected to a flexible printed circuit board with spot-welding on one side of the wire parts; and an antenna impeded sheet in which the antenna is mounted with an ultrasound impeded method, and forms fixing grooves to fix the flexible printed circuit board on the side of the wire. The present invention can prevent declining of the performance of the antenna by the resistance included in the wire, by widening the cross-section area of the antenna through allowing the wire part formed of multiple rows of wires to transmit signals using the antenna formed of multiple rows. Further, the invention can install the antenna in a narrow space by minimizing the space of the antenna through the separation of the wire part formed of multiple rows of wires with regular intervals, while separating the wires with regular intervals. The invention prevents shorts between the wire parts by separating the wire parts. Further, the invention can exchange the signals smoothly by eliminating the cause of communications failure and reducing operation distance from the signal loss of the signal bandwidth of which the user wants, while the resonant frequency is changed due to change of the inductance based on the characteristics of wire and wire parts.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to an NFC antenna using a wire,

More particularly, the present invention relates to an NFC antenna using a wire, and more particularly, to a method of manufacturing a NFC antenna using a wire by coating a thin flat wire on a sheet, forming a single wire portion by combining a plurality of flat wire wires, The present invention relates to an NFC antenna using a wire that can be easily installed in various places by minimizing the thickness occupied by an antenna by forming one antenna and mounting the antenna on a sheet.

Generally, a wire used for fabricating an NFC antenna is formed by forming an antenna substrate having insulation on one surface of a metal layer such as copper or aluminum as shown in Korean Patent Registration No. 10-1379832, And an antenna circuit and an antenna substrate were connected using an anisotropic conductive adhesive to fabricate an NFC antenna.

However, when the anisotropic conduction adhesive is used to connect the pattern of the antenna and the substrate, etching the metal layer, inserting an anisotropic conductive adhesive film between the substrate and the circuit, or spraying an anisotropic conductive adhesive, It is necessary to complete the process of connecting the antenna circuit and the antenna through the press process. Therefore, the manufacturing cost of the antenna circuit and the substrate are increased due to the increase of the number of processes for fixing the antenna circuit and the substrate.

In addition, defects may occur in the pattern due to short-circuiting or short-circuit due to etching failure during the etching process. In order to prevent damage to the product during the process of bonding the anisotropic conductive adhesive to the substrate and circuit, There is a problem that an additional process is required to be used.

The NFC antenna using the wire according to the present invention includes an antenna in which one or more wires are joined together, an antenna in which the wires are joined together in one or more patterns, and the flexible circuit board is connected to one side of the wire by spot welding, An antenna embedded sheet having a fixing groove for mounting a flexible circuit board to be mounted on an end of a wire portion, the antenna being embedded in an ultrasonic wave embedded system and transmitting a signal using an antenna having a plurality of wires formed of a plurality of wires, It is possible to prevent the performance of the antenna from being lowered due to the resistance included in the wire by widening the cross-sectional area of the antenna. Also, the wire portion composed of a plurality of wires arranged at equal intervals, The resonance frequency is changed due to the change of the inductance so that the antenna can be easily installed in a narrow space and the gap between the wire portions is separated so as to prevent shorting between the wire portions, The present invention has been made in order to solve the above-mentioned problems, and to provide a signal transmission system capable of smoothly transmitting a signal.

According to the present invention, a signal is transmitted using an antenna in which a plurality of wires are formed in a plurality of rows, thereby reducing the performance of the antenna due to the resistance included in the wire, The antenna unit can be easily installed in a narrow space by arranging the wire unit having a plurality of wires spaced apart from each other by a predetermined distance so as to minimize the space occupied by the antenna, The resonance frequency is changed due to the change of the inductance so that the short circuit does not occur, thereby reducing the operation distance due to the signal loss of the desired signal band and eliminating the cause of the communication failure and smoothly transmitting the signal.

By forming the cross-section of the wire in the form of a square, it can be manufactured in a plurality of rows and a plurality of columns to widen the cross-sectional area through which the signal can be transmitted, so that the signal transmitted along the wire receives the influence of the resistance included in the wire to a minimum, The strength of the signal is reduced and the transmission distance is reduced, thereby preventing the signal from being transmitted smoothly.

In addition, by coating the wires, even when the patterns of the antennas are overlapped, the resistance and the inductance values are uniformly maintained without affecting the wires overlapping each other, so that the performance of the antenna can be maintained constant.

In addition, by manufacturing the antenna and the flexible circuit board by spot welding while using the antenna as a wire, the process for manufacturing the antenna is reduced, so that the consumable material is not used and the economical efficiency is excellent. There is a merit that it can reduce the defective performance and minimize the defects, thus facilitating the quality control.

Also, even if the wire and the wire portion are bent by the characteristics of the wire and the wire portion constituting the antenna, the inductance of the antenna is changed and the frequency is changed to reduce the operation distance due to the signal loss of the desired signal band, It is advantageous to eliminate it.

In addition, since the cross section of the wire is formed in the shape of a small square compared to the width of the wire, the space occupied by the wire is minimized, so that the wire can be easily installed and used in a narrow space without restriction of space.

1 is an exploded perspective view showing an NFC antenna using a wire according to the present invention.
2 and 3 are a perspective view and a front view showing an embodiment of an antenna formed on an NFC antenna using a wire according to the present invention.
FIGS. 4 to 6 are an exploded perspective view, a plan view, and a front view, respectively, of an antenna and an antenna embedded sheet of an NFC antenna using wires according to the present invention.
FIG. 7 is a perspective view showing another embodiment of an antenna embedded sheet formed on an NFC antenna using a wire according to the present invention. FIG.

In order to achieve the above object, the present invention is as follows.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.

The NFC antenna 100 using the wire of the present invention comprises an antenna 10 and an antenna embedded sheet 20 as shown in Figs. 1 to 7.

First, the antenna 10 includes a wire 11 formed by arranging at least one wire 11a as shown in FIG. 1 to FIG.

Here, the wire 11a is preferably used as a flat wire having a relatively large cross-sectional area in comparison with a circular shape so that a signal transmitted along the wire 11a can be smoothly transmitted.

In addition, the flat wire is generally referred to as a ribbon wire, and the shape of the flat wire can be formed as a curved rectangle (for example, a long hole shape) at both sides. It should be noted that the detailed description will be omitted.

In addition, the wire 11a is configured so that a surface having a relatively large area is installed in a direction in which it is in close contact with the antenna embedded sheet 20. [

This is because when the wire 11a is mounted on the antenna embedded sheet 20, the area where the wire 11a is exposed to the outside from the antenna embedded sheet 20 is minimized so that the antenna 10 and the antenna embedded sheet 20) is minimized.

As described above, the wire 11a having a circular cross section may be used, but it is preferable to use a flat wire for the above-mentioned points.

The outer surface of the wire 11a may be coated with a material such as enamel.

This is to prevent the signals transmitted along the adjacent wires 11a from affecting each other when the wires 11a are arranged in a plurality of lines.

In addition, the material coated on the wire 11a is generally made of various materials. In the present invention, the enamel has been described as an example. However, it is obvious that various kinds of materials can be selected depending on the purpose of the user A detailed description thereof will be omitted.

Even if the wire 11a is formed in various patterns by coating the outer side of the wire 11a as described above, even if the wire 11a overlaps with the wire 11a, the signal transmitted along the wire 11a is transmitted to the adjacent wire 11a and the wire 11a, It is possible to prevent variations in inductance of the wire 11a due to a short circuit or the like even if the wire 11a overlaps with the wire 11 so that the pattern can be formed in various patterns irrespective of overlapping of the wire 11a and the wire 11 .

For example, when a pattern is formed in the spiral direction on the antenna embedded sheet 20 by using one wire 11a as shown in Figs. 2 to 3, generally one end portion of the wire 11a (a) is exposed to the outside of one side of the antenna embedded sheet 20 and the other end portion (b) is finished inside the antenna embedded sheet 20, Even if the other end portion b of the wire 11a overlaps the wire 11a across the pattern, the signals flowing along the wire 11a are not influenced by each other, The end portions a and b of the wire 11a are smoothly exposed to the outside of the antenna embedded sheet 20 while the other side b is traversed the pattern so that one end portion a of the wire 11a is exposed, And the other end portion (b) can be easily connected to another member .

Accordingly, the one end portion (a) and the other end portion (b) of the wire 11a can be smoothly exposed to the outside of the antenna embedded sheet 20 due to the above-described structure.

When the antenna 10 is mounted on the antenna embedded sheet 20 as described above, one end portion (a) of the wire 11a is exposed to the outside of the antenna embedded sheet 20 basically The other end portion b may be located inside the antenna embedded sheet 20 and the one end portion a and the other end portion b of the wire 11a It may be configured to be exposed to the outside of the antenna embedded sheet 20.

One end portion (a) of the wire 11a is formed to be exposed to the outside of the antenna embedded sheet 20 and the other end portion (b) is formed to be positioned inside the antenna embedded sheet 20 And is configured to expose one end portion (a) and the other end portion (b) of the wire 11a to the outside of the antenna embedded sheet 20 so as to conveniently connect the wire 11a and the contact member You may.

In addition, both the one end portion (a) and the other end portion (b) of the wire 11a may be located inside the antenna embedded sheet 20, or may be positioned in the opposite direction as described above .

When the wire 11a is formed in a square shape, the width w of the wire 11a may be 0.07 to 0.3 mm and the height h may be 0.02 to 0.3 mm, as shown in FIGS. 0.04 mm.

This is because it is possible to prevent the performance of the antenna 10 from lowering due to the resistance included in the wire 11a as the cross section of the wire 11a becomes wider when a signal is transmitted through the wire 11a, If the threshold value is exceeded, the thickness of the wire portion 11 becomes thick. Therefore, the wire 11a is configured with the above-mentioned threshold value.

When the wire 11a is lower than the threshold value described above, the space occupied by the antenna 10 can be reduced. However, since the signal is affected by the resistance included in the wire 11a, the performance of the antenna may be lowered The above-mentioned threshold value is set in order to prevent the occurrence of the above-mentioned problem.

In other words, a signal transmitted along the wire 11a can be transmitted smoothly as the cross-sectional area of the wire 11a becomes wider. However, as the cross-sectional area increases, the thickness occupied by the wire 11a becomes thicker, The wire 11a is formed at the above-mentioned critical value.

In forming one wire portion 11, at least one wire 11a may be formed, and the number of wires 11a may be between one and 12 lines.

This is because, as described above, the larger the number of wires 11a is, the higher the signal transmission efficiency can be, but the wider the space occupied by the wires 11a is.

In the present invention, five wires 11a are formed on one wire 11 as an example.

When forming the wires 11a in a plurality of lines, it is preferable that the distance l1 between the wires 11a is 0.05 mm to 0.5 mm.

When the wires 11a are arranged in a plurality of lines, if the wires 11a are narrower than the threshold, the wires 11a may overlap each other and the thickness of the antenna 10 may be thicker. The space occupied by the wire 11 integrated with the wires 11a is widened and the space occupied by the antenna 10 is widened so that the antenna 10 can not be positioned in a narrow space , And the distance 11 between the wires 11a is set to the above-mentioned threshold value.

In addition, the above-mentioned threshold value is set in consideration of the portion where the outer surface of the wire 11a is coated.

As described above, the wire portion 11 is formed by arranging one or more wires 11a.

It is also preferable that the wire portion 11 is made of a plurality of rows such as a wire 11a instead of a single row.

For example, as shown in FIG. 6, the wire section 11 is arranged between the first row and the fifth row.

In the present invention, it is assumed that the wire portions 11 are formed in three rows.

The reason why the wire portions 11 are formed in one row to three columns is that signals of various frequency bands can be transmitted according to the length and the pattern of the antenna 10, So that the signal can be transmitted safely while matching the frequency band capable of smoothly transmitting the signal.

When the wire portions 11 are constituted by a plurality of rows, the distance 12 between the wire portions 11 may be 0.3 to 1.5 mm.

This is because if the distance l1 between the wires 11a is less than the above-mentioned threshold value, the thickness of the wire portion 11 may be increased and the thickness of the antenna 10 may be thicker than the above- The distance l2 between the wire portions 11 is specified with the above-mentioned threshold value.

Here, the distance 12 between the wires 11 refers to the distance 12 between one pattern and another pattern.

In other words, the wires 11a and the wire portions 11 forming the antenna 10 are formed in a plurality of rows and a plurality of rows at regular intervals, so that as the cross-sectional area of the wires 11a is widened, The resistance value included in the wire 11a is lowered so that the signal transmitted along the wire 11a is easily transmitted while being less influenced by the resistance value included in the wire 11a.

As described above, the wire 11a and the wire 11 can be formed to have a larger number of wires than the above-mentioned threshold value in order to widen the cross-sectional area of the wire 11a and the wire 11. However, It is difficult to attach the antenna 10 to the cellular phone cover (not shown in the figure) or the battery (not shown in the figure) while the volume of the antenna 10 is increased. Therefore, The width w, the height h, the spacings 11 and 12 and the number of the wires 11a and the wire portions 11 as shown in Fig.

In addition, it is obvious that the wire portion 11 may be formed in various patterns according to the purpose of the user, and a detailed description thereof will be omitted.

The wire 11a and the wire 11 constituting the antenna 10 can be formed in a serial form or a parallel form, which is a method of forming a circuit at present, according to the purpose of the user. The description will be omitted.

Meanwhile, the antenna embedded sheet 20 is configured such that the antenna 10 is mounted on one side in an ultrasonic embedded system.

Here, the ultrasonic wave embedded system, which is a method used by the antenna 10 to be mounted on the antenna embedded sheet 20, is a generally used method, and a detailed description thereof will be omitted.

When the antenna 10 is mounted on the antenna embedded sheet 20 in an ultrasonic embedding manner as described above, the shape of the wire 11a is formed in a square shape, and up to 70% of the height h of the wire 11a The antenna embedded sheet 20 can be mounted in the interior of the seat 20, thereby minimizing the space required for the antenna 10 to be separated.

In addition, when the antenna 10 is mounted on the antenna embedded sheet 20 in an ultrasonic embedding manner, even if the wire 11a and the wire portion 11 are bent, The resonance frequency is changed due to the change of the inductance of the antenna 10 according to the characteristics of the wire portion 11a and the wire portion 11 so that the cause of the decrease in the operating distance and the communication failure due to the signal loss of the desired signal band is eliminated, It is possible to exchange.

It should be noted that the antenna embedded sheet 20 is made of a synthetic resin or the like which is generally used at present, and its detailed description will be omitted.

When the antenna 10 is mounted on the antenna embedded sheet 20 as described above, a flexible circuit board (not shown) capable of transmitting or connecting an electrical signal to one end portion a and the other end portion b of the wire 11a k.

It is preferable to connect the one end portion a and the other end portion b of the wire 11a to the flexible circuit board k using spot welding.

Here, by bonding the wire 11a to the flexible circuit board k by spot welding, the process for attaching the wire 11a and the flexible circuit board k can be reduced.

In order to connect the wire 11a to the flexible circuit board k in the prior art, an anisotropic conductive adhesive film is placed between the wire 11a and the flexible circuit board k, The wire 11a and the flexible circuit board k are completely attached to each other through the pressing process or the anisotropic conductive adhesive is applied between the wire 11a and the flexible circuit board k The number of processes for attaching the wire 11a and the flexible circuit board k increases due to the application and pressing process. However, by fixing the wire 11a and the flexible circuit board k by spot welding as described above, It is possible to minimize the process for fixing the flexible circuit board 11a and the flexible circuit board k to improve the economical efficiency due to the reduction of manufacturing costs and the like and to improve the working efficiency and performance according to the reduction of the manufacturing process .

7, when the antenna 10 and the flexible circuit board k are connected to each other, the flexible circuit board k can be easily fixed to the antenna embedded sheet 20, It is preferable that the fixing groove 21 is formed in the sheet 20.

A protective sheet 30 for protecting the antenna embedded sheet 20 may be further formed on the other side of the antenna embedded sheet 20 on which the antenna 10 is mounted.

Here, the protective sheet 30 includes an adhesive component, so that the protective sheet 30 can be easily adhered to the antenna embedded sheet 20 by its adhesive component. .

In addition, it is obvious that the protective sheet 30 can be adhered to the antenna embedded sheet 20 through heat or the like, and a detailed description thereof will be omitted.

The protective sheet 30 is formed by thinly forming the antenna embedded sheet 20 so that when the antenna 20 is attached to a portable terminal (not shown), a cover (not shown), a battery (not shown) It is configured to prevent the antenna embedded sheet 20 from being damaged by attaching the protection sheet 30 to the other side of the antenna embedded sheet 20 because the antenna can be easily broken.

An antenna 10 is formed on one side of the antenna embedded sheet 20 and a protection sheet 30 is formed on the other side of the antenna embedded sheet 20, A shielding sheet 50, and a second adhesive member 60 in this order.

In detail, the antenna 10 is mounted on one side of the antenna embedded sheet 20, and a first adhesive member 40 such as a double-sided adhesive tape is attached to the upper side of the antenna 10 .

A shielding sheet 50 is formed on the upper side of the first adhesive member 40 so as to block signals such as an electromagnetic wave, a magnetic field and an electric field. A wire using a square wire is used as an upper side of the shielding sheet 50 A second adhesive member 60 such as a double-sided adhesive tape is configured so that the NFC antenna 100 used can be attached to a battery cover (not shown in the drawing) or a battery (not shown in the drawing) of a cellular phone or the like.

Here, the first adhesive member 40, the shielding sheet 50, and the second adhesive member 60 are generally used to install an NFC antenna, a contactless antenna, or the like in a portable terminal such as a mobile phone, Is omitted.

When the NFC antenna 100 using the wire using the square wire is formed as described above, the protection sheet 30 is formed at one end, and the antenna embedded sheet 20 is formed on the other side of the protection sheet 30. [ An antenna 10 is formed on the other side of the antenna embedded sheet 20 and a first adhesive member 40 is formed on the other side of the antenna 10, A shielding sheet 50 is formed on the other side of the member 40 and a second adhesive member 60 is formed on the other side of the shielding sheet 50. The other side of the second adhesive member 60 And is attached to the cover or the battery of the portable terminal.

Hereinafter, the operation according to the preferred embodiment of the present invention will be described.

First, the NFC antenna 100 using wires formed as described above is attached to a cover or a battery of a portable terminal, such as a cellular phone, to which the user intends to attach the antenna.

Since the wire 11a is formed in a square shape, the space occupied by the antenna 10 is minimized, and the thickness occupied by the NFC antenna 100 using the wire is not so large. As a result, So that it can be easily installed in the space.

Also, when the NFC antenna 100 using a wire is used, a signal transmitted through the antenna 10 is easily transmitted.

In detail, the antenna 10 has a plurality of rows and a plurality of wires 11 formed of a wire 11a and the wire 11a, so that the cross-sectional area of the antenna 10 is increased, So that the signal can be smoothly transmitted while preventing the performance of the antenna 10 from being lowered, by transmitting the signal transmitted along the wire 11a with a minimum influence on the resistance included in the wire 11a.

The plurality of wires 11a are spaced apart from each other by a predetermined distance and the plurality of wire portions 11 are also spaced apart from each other by a predetermined distance to minimize the thickness of the antenna 10, will be.

Further, since the NFC antenna 100 using the wire is simple in construction, it is easy to manufacture, thereby reducing manufacturing cost and manufacturing cost, and is excellent in economical efficiency. The wire 11a of a square shape prevents a pattern defect of the wire 11a The antenna 10 and the flexible circuit board k are coupled by spot welding so that the antenna 10 and the flexible circuit board k are coupled to each other by coupling the antenna 10 and the flexible circuit board k by spot welding, It is possible to reduce the process of the contact process.

Even if the one end portion (a) and the other end portion (b) of the wire 11a cross each other, the signals transmitted along the adjacent wires 11a are not overlapped and interfered with each other by the coating process, So that it is smoothly transmitted.

In addition, by fabricating the antenna 10 and the flexible circuit board k by spot welding using the wire 11a as the antenna 10, the process for manufacturing the antenna is reduced, and the consumable material is not used, It is possible to reduce the defective performance of the antenna that can be generated in the antenna fabrication, minimize the defects, and manage the quality easily.

Although the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have knowledge of.

10: Antenna
11: wire portion 11a: wire
20: Sheet for antenna embedded
21: Fixing groove
30: Protective sheet
40: first adhesive member
50: Shielding sheet
60: second bonding member
100: NFC antenna using wire

Claims (8)

The flexible printed circuit board k can be spot welded to one side of the wire portion 11 by forming one or more wire portions 11 in which one or more wires 11a are joined together, An antenna 10 connected thereto;
And an antenna embedded sheet 20 in which the antenna 10 is mounted in an ultrasonic embedded manner and a fixing groove 21 is formed in which a flexible circuit board k connected to one side of the wire portion 11 is fixed NFC antenna using wire with features.
The NFC antenna according to claim 1, wherein the wire (11a) formed on the antenna (10) is a flat wire.
The antenna according to claim 1, wherein the wire (11a) formed on the wire (11) of the antenna (10) is coated and the one end a and the other end b of the wire The antenna embedded sheet 20 is located inside the antenna embedded sheet 20 or both of them are located outside the antenna embedded sheet 20 or only one of the one end portion a and the other end portion b is located in the antenna embedded sheet 20 ≪ / RTI > and the other is located inside.
The antenna according to claim 1, wherein a width (w) of the wire (11a) formed in the wire portion (11) of the antenna (10) mounted on the antenna embedded sheet (20) is 0.07 to 0.3 mm and a height NFC antenna using wire characterized by 0.02 to 0.04 mm.
The NFC antenna according to claim 1, wherein the distance (l1) between one or more wires (11a) formed on the antenna (10) is 0.05 to 0.5 mm.
The NFC antenna according to claim 1, wherein an interval (12) between one or more wire portions (11) formed in the antenna (10) is 0.3 to 1.5 mm.
The antenna according to claim 1, wherein the antenna (10) comprises a wire portion (11) in one to five rows, and the wire portion (11) NFC antenna used.
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