KR101508172B1 - Circuit Board for NFC Antenna with Wireless Charging - Google Patents

Abstract

The present invention relates to an antenna circuit board for NFC that also functions as a wireless charging device in which charging efficiency is increased by increasing the width or diameter of the outermost coils facing each other in a wireless charging coil pattern located on the same plane of a substrate.
The NFC antenna circuit board serving as a wireless rechargeable battery of the present invention includes a substrate, at least one wireless recharging coil pattern formed on an upper surface or an upper surface of the substrate, a plurality of wireless rechargeable coil patterns formed along the upper surface rim of the substrate, A coil pattern for an upper surface NFC (short-range wireless communication); a connection terminal provided on one side of the substrate and connected to the wireless charging coil pattern and the upper surface NFC coil pattern, The coil of the upper NFC coil pattern located in the area adjacent to the outer coil is bypassed to the lower side of the substrate so as to be connected to the NFC coil so that the lower NFC coil is located close to the edge of the substrate, The width or diameter between the outermost coils facing each other of the one or more wireless charging coil patterns formed on the same plane is smaller than the width And the coil of the NFC coil pattern is formed to extend outwardly in the range of the allowable clearance distance S generated by bypassing.

Description

[0001] The present invention relates to a circuit board for an NFC (short-range mobile communication)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circuit board of an antenna for an NFC (abbreviation for near field communication, hereinafter referred to as "NFC" A wireless charging method of increasing the charging efficiency by increasing the width or diameter between the outermost and / or the innermost coils facing each other in the wireless charging coil pattern located on the same plane of the circuit board on the circuit board of the provided antenna To an NFC antenna circuit board.

BACKGROUND OF THE INVENTION [0002] Recent developments in communication and information processing technologies have led to an explosive increase in the use of portable mobile communication terminals such as mobile phones, PDAs, and notebook computers having various functions such as the Internet, video calls, and document operations.

Such a portable mobile communication terminal is provided with a payment service functioning as a credit card or a traffic card in response to a new mobile environment triggered by the emergence of a smart phone, a service for transferring travel information for goods information or visitors, Service, access control, advertisement service, and so on.

On the other hand, recently, NFC technology has attracted attention as a technology for enabling such a service in a portable mobile communication terminal. The NFC technology is a radio frequency identification (RFID) technology, and it is a non-contact communication technology using a frequency band of 13.56 MHz, which is a next generation short range communication technology that is relatively low in security and low in cost because of its short communication distance.

Recently, attempts have been made to add a wireless charging function to an antenna having the above-mentioned NFC function in order to further enhance user convenience of a portable mobile communication terminal.

The wireless charging can be performed without directly connecting the portable mobile communication terminal to the charger or connecting the portable mobile communication terminal to the charger without using the USB charger terminal and connecting the portable mobile communication terminal to the charger. Method.

Current wireless charging methods include magnetic induction, magnetic resonance, and electromagnetic wave, among which magnetic induction is the most popular. The magnetic induction method is a method in which two nearby coils generate induced currents to charge and have advantages of high power transmission efficiency, relatively easy to implement technically, and relatively low cost.

As an example of adding the wireless charging function to the antenna having the NFC function as described above, there is an antenna in which an NFC antenna and a wireless charging antenna are integrated on one board. The present invention is also applied to a wireless power transmission device for wirelessly charging a portable mobile communication terminal such as a pad.

FIG. 1 shows an example of an antenna circuit board for NFC that combines an NFC coil pattern and a wireless charging coil pattern in one substrate so that the NFC and the wireless charging function can be performed together.

1 (a), the circuit board 10 of the conventional NFC antenna for wireless charging has a substrate 12, a wireless charging coil pattern 14, an NFC coil pattern 16, and a connection Terminals A and B, respectively.

A wireless charging coil pattern 14 is spirally wound on the upper surface of the substrate 12 and an NFC coil pattern 16 is formed on the outer side of the wireless charging coil pattern 14, And a plurality of columns (rows) are formed in a winding shape.

Here, it is important that the coil located at the outermost portion of the wireless charging coil pattern 14 and the coil located at the innermost portion of the NFC coil pattern 16 are spaced apart from each other so that interference does not occur.

The connection terminals A and B are provided on one side of the substrate 12 and the connection terminal A is a connection terminal for supplying power to the wireless charging coil pattern 14 or drawing out the induced power , And the connection terminal B is a connection terminal for inputting or outputting the communication signal to the NFC coil pattern 16.

As shown in Fig. 1 (b), on the lower surface of the substrate 12, there are formed the same or similar size and shape A wireless charging coil pattern 14 'is formed.

Unlike the wireless charging coil patterns 14 and 14 ', the NFC coil patterns 16 are not formed on the lower surface of the substrate 12, The function of the NFC can be sufficiently exhibited. Of course, the NFC coil patterns 16 can be formed on both sides of the substrate 12, if necessary.

The circuit board 10 of the NFC antenna serving as the wireless charging unit is integrally combined with a protective sheet or a release sheet on the upper and lower surfaces of the circuit board 10 and is applied to a portable mobile communication terminal as an antenna. As shown in FIG.

The method of forming the wireless charging coil patterns 14 and 14 ', the NFC coil patterns 16 and the connection terminals A and B in the circuit board 10 of the NFC antenna serving as the wireless charging device The matters described in Patent Documents 2 and 3 can be referred to.

1. Patent Document 1: Korean Patent Publication No. 10-1177302 2. Patent Document 2: Korean Patent Application No. 10-2012-0100714 3. Patent Document 3: Korean Patent Application No. 10-2012-0100715

However, it is known that the charging efficiency in an NFC antenna that also serves as a wireless charging device has efficiency of 80 to 90% as compared with a wired charging method, though it differs depending on which wireless charging method is adopted.

Therefore, although various efforts have been made to increase the charging efficiency in the NFC antenna for wireless charging, a wireless power transmission device such as a portable mobile communication terminal or a wireless charging pad is demanded from a manufacturer or a consumer, It is difficult to improve the product because it is a strong product.

For example, in order to increase the charging efficiency by increasing the impedance value of the wireless charging coil pattern, a method of narrowing the thickness of the coil forming the wireless charging coil pattern and narrowing the space between the coils may be attempted. Normally, There is a problem that this method is difficult to adopt due to many difficulties in the manufacturing process, considering that the thickness is about 0.6 mm and the gap between the coils is about 0.1 mm.

Although the method of increasing the coil height of the wireless charging coil pattern is also useful for raising the impedance value, in the NFC antenna which is commonly used for wireless charging, it is required that the thickness of the entire antenna be 0.5 to 0.45 mm or less There is a problem that this is also difficult to adopt.

It is also known that the method of increasing the number of coil turns (the number of turns) of the wireless charging coil pattern or increasing the width or diameter between the outermost and innermost coils facing each other in the coil pattern can also increase the impedance value, There is also a problem that it is difficult to adopt this because of the size of the substrate or interference with the NFC coil pattern.

In order to improve the charging efficiency by raising the impedance value of the wireless charging coil pattern in consideration of the above problems, the present invention provides a wireless charging coil pattern formed on an uppermost and / And an object of the present invention is to provide an antenna circuit board for NFC that increases the width or diameter of the antenna and increases the number of coil turns (the number of turns) but does not increase the interference with the NFC coil pattern.

To this end, an NFC antenna circuit board serving as a wireless rechargeable battery according to the present invention comprises a substrate, at least one wireless recharging coil pattern formed on an upper surface or an upper surface of the substrate, And a connection terminal provided on one side of the substrate and connected to the wireless charging coil pattern and the top NFC coil pattern, wherein the one or more wireless charging coils The coil of the top NFC coil pattern located in the area adjacent to the outermost coil of the pattern is bypassed to the bottom side of the substrate so as to be connected to the NFC coil so that the NFC coil is positioned close to the rim of the substrate, A width between the outermost coils facing each other of one or more wireless charging coil patterns formed on the same plane of the substrate, Is formed to extend outwardly in a range of a clearance distance (S) formed by bypassing a coil of the coil pattern for upper surface NFC.

Here, the width or the diameter between the coils located at the innermost outermost portions of the wireless charging coil patterns facing the same plane of the substrate is determined by the allowable separation distance S The number of coil turns (the number of turns) of the wireless charging coil pattern can be increased toward the outside.

The coil for bypassing from the top surface NFC coil pattern to the bottom surface of the substrate is connected to the bottom NFC coil via a pair of via holes passing through the substrate, The NFC coil may be formed at a position corresponding to the outermost coil of the top NFC coil pattern.

The NFC antenna circuit board serving as a wireless rechargeable battery according to the present invention includes a wireless charging coil pattern formed on the upper and lower surfaces of the substrate so as to correspond to the upper and lower surfaces of the substrate, And the width or diameter between the outermost coils facing each other is formed to extend outwardly in the range of the allowable separation distance S. [

Also, the above-described features of the present invention can be achieved by bypassing the lower NFC coil from the coil of the innermost coil of the upper NFC coil pattern.

The bypass from the top NFC coil pattern to the bottom NFC coil is formed at one or more of the side edges of one or more of the upper, lower, left, and right sides of the substrate when the same plane of the substrate is taken as a reference .

In this case, when the lead-out input coils for connecting to the connection terminals are formed to extend in the coils constituting both ends of the wireless charging coil pattern, the coil for drawing out and the coils for the lower surface NFC adjacent thereto are spaced apart from each other .

Meanwhile, the antenna circuit board for NFC which also serves as a wireless rechargeable battery according to the present invention is characterized in that, when the same plane of the substrate is used as a reference, Is longer than the length of the region closest to the upper surface wireless charging coil pattern.

In addition, when the same plane of the substrate is used as a reference, the innermost coil of the NFC coil pattern at the start and end points of the coil, which is bypassed from the upper surface NFC coil pattern to the lower surface of the substrate, The distance between the innermost coil of the remaining top NFC coil pattern and the outermost coil of the adjacent wireless charging coil pattern is the same as the distance between the innermost coil of the remaining top NFC coil pattern and the outermost coil.

According to the present invention, it is possible to increase the width or diameter between the outermost and / or the innermost coils facing each other in the wireless charging coil pattern with reference to the same plane of the substrate or to increase the number of coil turns There is an advantage that the interference with the NFC coil pattern can be prevented from increasing.

Therefore, in the NFC antenna circuit board which also serves as the wireless charging of the present invention, even when the limitation of the size and height of the substrate is applied, the wireless charging coil pattern has a larger impedance value and the charging efficiency can be improved .

Fig. 1 shows an example of an antenna circuit board for NFC that also functions as a wireless charging device according to the prior art. Fig. 1 (a) shows its upper surface and Fig. 1 (b) shows its lower surface.
Fig. 2 shows a first embodiment of an antenna circuit board for NFC serving as a wireless rechargeable battery according to the present invention. Fig. 2 (a) shows the upper surface thereof and Fig. 2 (b) shows the lower surface thereof.
3 is another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the terminology used herein is for the purpose of description only and should not be construed as limited to the specific embodiments set forth herein.

2A and 2B, the NFC antenna circuit board 1000 serving as a wireless rechargeable battery of the present invention is formed so as to correspond to the upper and lower surfaces of the substrate 120 having a constant shape, And NFC coil patterns 160 and 160 formed along the rim of the substrate 120 so as to be spaced apart from the wireless charging coil pattern 140 formed on the upper surface of the substrate 120. The wireless charging coil patterns 140 and 140 ' (Hereinafter, referred to as " top NFC coil pattern ") when the upper or lower surface of the substrate is required to be divided in the following description), the wireless charging coil patterns 140 and 140 ' And connection terminals A and B connected to the coil pattern 160 for NFC.

Since the substrate 120, the wireless charging coil patterns 140 and 140 ', the NFC coil patterns 160 and the connection terminals A and B have already been described with reference to the background art in the foregoing, Is omitted.

In the first embodiment of the present invention, the wireless charging coil patterns 140 and 140 'correspond to the upper and lower surfaces of the substrate 120, respectively. However, But the present invention is not limited thereto. That is, it is to be understood that the wireless charging coil patterns 140 and 140 'may be formed on only one of the upper surface and the lower surface of the substrate 120, or one or more may be formed on the same plane of the substrate 120.

In order to improve the charging efficiency by increasing the impedance value of the wireless charging coil patterns 140 and 140 ', the wireless charging coil patterns 140 and 140' formed on the same plane of the substrate 120 It is possible to increase the width or diameter (X1, X2, Y1, Y2) between the opposed outermost and / or the innermost coils or to increase the number of coil turns (the number of turns) but increase the interference with the NFC coil pattern 160 And an antenna circuit board for NFC that also functions as a wireless charging device.

In order to achieve this, in the first embodiment of the present invention, an NFC coil (not shown) located in a region (R) adjacent to the outermost coil of the wireless charging coil pattern 140 formed on the upper surface of the substrate 120 The coil of the pattern 160 is bypassed to the lower surface through the via hole 162 vertically penetrating the substrate 120 and the upper NFC coil pattern 160 bypassed to the lower surface of the substrate 120, Is connected to the lower surface NFC coil (164). Therefore, the via hole 162 refers to the beginning and end of the bypass of the coil, which is bypassed from the upper surface NFC coil pattern 160 to the lower surface of the substrate 120.

The NFC coil 164 is formed on the lower surface of the substrate 120 so as to be positioned near the rim of the substrate 120 with respect to the position of the via hole 162. In particular, The NFC coil pattern 160 is located closer to the rim of the substrate 120 within the range from the coil width of the upper NFC coil 160 to the position corresponding to the outermost coil of the upper NFC coil pattern 160. [

Here, the number of coils of the upper surface NFC coil pattern bypassed from the upper surface to the lower surface of the substrate 120 need not necessarily be one, and two or more coils may be bypassed.

The coil of the upper NFC coil pattern is bypassed from the upper surface to the lower surface of the substrate 120 via a pair of via holes 162. The length between the pair of via holes 162 corresponds to the length of the wireless charging coil pattern 140 and the innermost coils of the NFC coil pattern are longer than the length of the nearest adjacent region R. [

In addition, when the same plane of the substrate 120 is used as a reference, the outermost coil of the NFC coil pattern 160 in the pair of via holes 162 and the outermost coil of the wireless charging coil pattern 140 adjacent thereto It is preferable that the distance from the coil is equal to the distance between the innermost coil of the non-bypassed NFC coil pattern 160 and the outermost coil of the wireless charging coil pattern 140 adjacent thereto.

The coil of the NFC coil pattern 160 adjacent to the wireless charging coil pattern 140 is bypassed to the lower surface of the substrate 120 as described above, An allowable separation distance of at least "S " between the coil patterns 140 and 160 is ensured.

The wireless charging coil pattern 140 may be formed to be larger by utilizing the allowable separation distance S. More specifically, one or more wireless charging coil patterns 140 formed on the same plane of the substrate 120, (The edge of the substrate) by the clearance distance S between the outermost coils facing each other.

In order to extend the width or diameter between the outermost coils facing each other in the wireless charging coil pattern 140 more outwardly, it is necessary to increase the width or the diameter of the outermost coil or to increase the size of the outermost coil from the outermost coil The number of coil turns (the number of turns) can be increased.

In addition, it is preferable that the innermost coil of the wireless charging coil pattern 140 is also formed outwardly as in the outermost coil. Specifically, when the same plane of the substrate 120 is used as a reference, It is preferable that the width or the diameter between the coils located at the innermost outermost portions of the coil patterns 140 facing each other is also set larger outward.

Meanwhile, in the first embodiment of the present invention, when the substrate is viewed from a plane, the inner coils are bypassed to the rear surface of the substrate with respect to the NFC coil patterns on the left and right sides. However, In addition to the examples, various modifications can be made.

That is, FIG. 3 shows another embodiment of the present invention. When the substrate is viewed from a plane, the inner coils are bypassed to the rear surface of the substrate with respect to the NFC coil patterns on the left, The present invention can be applied to any one or both of the upper, lower, left, and right NFC coil patterns in consideration of the shape of the substrate and required charging efficiency characteristics.

However, in the above embodiments, the coils 180 forming the both ends of the wireless charging coil pattern 140 are adjacent to the coin 180 for connection to the connection terminal A, When the coils 164 are positioned, the coil 160 and the lower surface NFC coil 164 should be sufficiently spaced apart from each other so as not to interfere with each other.

As a result, whether or not to partially bypass the coil to the lower side of the substrate for the NFC coil pattern is considered in consideration of the shape of the substrate and / or the coil pattern for wireless charging, the NFC coil pattern, Can be easily selected. That is, it is possible to increase the width or diameter between the outermost and / or the innermost coils facing each other in the wireless charging coil pattern formed on the substrate, increase the number of coil turns (the number of turns) It is to be understood that those skilled in the art can appropriately select and implement the antenna circuit board for NFC that does not increase radio frequency charging capability, Should be construed as falling within the scope of the present invention.

10, 1000: Circuit board of NFC antenna for wireless charging
12, 120: substrate
14, 140: upper surface wireless charging coil pattern
14 ', 140': When the wireless charging coil pattern
16, 160: coil pattern for NFC
162: Beer hole (starting and end points where the coil pattern for NFC is bypassed to the bottom surface of the substrate)
164: Lower NFC coil
180: a take-out input coil connected to a connection terminal
R: adjacent region
S: Leakage distance caused by some coils of the NFC coil pattern being bypassed to the back side of the substrate

Claims (12)

Board,
At least one wireless rechargeable coil pattern formed on an upper surface or an upper surface of the substrate,
A coil pattern for a top surface NFC (short-range wireless communication) spaced apart from the wireless charging coil pattern and formed along an upper surface rim of the substrate,
And a connection terminal provided on one side of the substrate and connected to the wireless charging coil pattern and the top NFC coil pattern,
The coil of the upper surface NFC coil pattern located in the area adjacent to the outermost coil of the at least one wireless charging coil pattern is bypassed to the lower surface of the substrate to connect with the NFC coil,
The NFC coil is formed to be positioned close to the rim of the substrate,
The width or diameter between the outermost coils facing each other of the at least one wireless charging coil pattern formed on the same plane of the substrate is within the range of the allowable separation distance S generated by bypassing the coils of the top NFC coil pattern Wherein the antenna is formed by extending substantially outwardly.
The method according to claim 1,
The width or diameter between the coils located at the innermost outermost portions of the wireless charging coil patterns facing the same plane of the substrate is smaller than the range of the allowable separation distance S generated by bypassing the upper NFC coil The antenna of the NFC antenna of claim 1,
The method according to claim 1,
Wherein the coils bypassed from the upper surface NFC coil pattern to the lower surface of the substrate are connected to the lower surface NFC coil via a pair of via holes passing through the substrate.
The method of claim 3,
Wherein the NFC coil is formed to be located closer to the edge of the substrate than the coil width of the NFC coil from the position of the via hole.
5. The method of claim 4,
Wherein the NFC coil is formed at a position corresponding to the outermost coil of the top NFC coil pattern.
The method according to claim 1,
A wireless charging coil pattern is formed in correspondence with the upper surface and the lower surface of the substrate,
And the width or diameter between the outermost coils facing each other of the wireless charging coil patterns formed on the same plane of the upper and lower surfaces of the substrate are formed to extend outwardly in the range of the allowable separation distance S A circuit board for an NFC antenna that also functions as a wireless charging device.
7. The method according to any one of claims 1 to 6,
Wherein the number of coil turns (the number of turns) of the wireless charging coil pattern is increased toward the outside.
7. The method according to any one of claims 1 to 6,
Wherein the coil for NFC is bypassed from the coil at the innermost periphery of the top NFC coil pattern.
7. The method according to any one of claims 1 to 6,
The bypass from the top NFC coil pattern to the bottom NFC coil is formed at one or more of the side edges of any one of the top, bottom, left, and right side of the substrate when viewed from the same plane of the substrate A circuit board for an NFC antenna that combines wireless charging.
10. The method of claim 9,
The coils forming both end portions of the wireless charging coil pattern are formed by extending a lead-out input coil for connection to the connection terminal,
Wherein the outgoing entry coil and the lower NFC coil adjacent to each other are positioned apart from each other.
10. The method of claim 9,
The length between the start and end points of the bypass of the coil that is bypassed from the upper surface NFC coil pattern to the lower surface of the substrate when the same plane of the substrate is referred to is the length of the region closest to the upper surface wireless charging coil pattern Wherein the antenna is electrically connected to the antenna.
10. The method of claim 9,
And an uppermost coil of the NFC coil pattern at the start and end points of the coil that is bypassed to the lower surface of the substrate in the upper NFC coil pattern, Wherein the spacing distance from the outer coil is equal to the distance between the innermost coil of the remaining upper NFC coil pattern and the outermost coil of the adjacent wireless charging coil pattern.

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