KR101283822B1 - Rf module for having tuning function - Google Patents

Abstract

PURPOSE: Tuning inlay is provided to increase inductance through a process of successively cutting patterns connected to an inductance increase pattern, thereby performing precise resonant frequency tuning with a simple process. CONSTITUTION: An upper side antenna (20) is formed corresponding to an upper side edge of a base substrate. A lower side antenna (30) is connected to one end of the upper side antenna through a first through hole (40). The lower side antenna is formed corresponding to a lower side edge of the base substrate. A radio frequency (RF) chip installation unit (60) is connected to the other end of the upper side antenna through a second through hole. The RF chip installation unit is connected to the lower side antenna and forms one closed loop. An inductance increase pattern (70) is composed of connected patterns and is connected to one side of the upper side antenna. A tuning function of increasing inductance and reducing a resonant frequency is executed by lengthening effective length of the upper side antenna when the patterns are successively cut.

Description

Tuning Inlay {RF MODULE FOR HAVING TUNING FUNCTION}

The present invention relates to a tuning inlay, and more particularly, it is applied to various smart cards, RFID, traffic cards, access cards, membership cards, etc. having a radio frequency (RF) interface function to precisely tune the resonance frequency. Relates to a tuning inlay.

'Inlay' refers to a part wound around the antenna coil inserted into the smart card for RF communication between the smart card and the terminal. The term 'tuning inlay' used in the following description refers to an inlay including a tuning function. it means.

In general, the contactless smart card is the same as the contact element and the memory element required for the information processing function, but the power supply for driving the smart card is provided through an RF (Radio Frequency) antenna and the electronic induction for wireless communication with the interface device. A card in the form of a method.

Early contactless smart cards were widely used as prepaid electronic money transportation cards. This prepaid transportation card is a plastic card with a smart card chip and an RF antenna.The card is charged at the charging station in advance and charged to the card, and the card is accessed from the reader whenever the vehicle is used. It is a way to reduce the transportation fee.

Since then, the contactless transportation card has been combined with a credit card so that it can be paid in post payment without charge. Such a credit card combined with a smart card chip and an RF antenna are combined in a plastic card of a credit card.

As the applications of mobile communication terminals (eg mobile phones) and smart card chips have been further expanded and mobile communication terminals have become a necessity of life, smart card chips are not mobile plastic terminals, rather than traditional plastic cards such as transportation cards and credit cards. It has evolved into a small size that is embedded in or mounted as an accessory on the outside.

The above-mentioned smart card chip-related card is used depending on whether the card terminal. That is, it is recognized by appropriate communication procedures between the RF antenna and the reader configured inside the card, and the result is recognized and settled.

However, the inlay used for the smart card, RFID, traffic card, access card, membership card, etc., as shown in Reference 1, in order to match the resonant frequency with the reader, using a coil or antenna only to attach a chip, Add a capacitor to the coil or antenna to attach the chip, in this case using a PCB or FPCB, PET, etc. as the base substrate, there is a manufacturing tolerance in the thickness of the material of the base substrate, such as PCB, FPCB, PET, plated There existed a problem that circuit pattern thickness, etching, and processing error, such as copper, generate | occur | produce.

In addition, the capacitor also has a problem in that the tolerance of the parts itself is more than ± 5% of commercial products.

Due to the complex cumulative deviation it is difficult to match the resonance frequency, there was a problem that put a lot of burden on the production process to maintain a constant quality.

Accordingly, when the reader is used at the site where various readers are used, there is a case in which the RFID card is not recognized or the recognition is insufficient, which may be a serious problem when a transportation card related to payment or identification is required.

의 식에 근거하는바, 기존의 제품은 제조 및 부품 자체의 오차에 따라 L(인덕턴스)과 C(캐패시턴스)가 특정 범위 내에서 편차를 갖게 되고, 이는 공진주파수의 오차를 갖게 하므로, 정밀하게 보정되지 않으면 현장에서 단말기에 대한 알에프 카드의 인식에 문제를 초래한다.
Thus, the resonance frequency f0 is typically

Based on consciousness, L (inductance) and C (capacitance) have deviation within a certain range according to manufacturing and component error, which makes precise correction because of error of resonance frequency. If not, it causes problems in the recognition of the RF card in the field.

(Reference 1) Republic of Korea Patent Publication No. 10-0809028

The present invention has been made to solve the problems of the prior art as described above, and its object is to provide a tuning inlay having an inductance increase pattern and an inductance decrease pattern to increase or decrease the effective length of the antenna to enable tuning of the resonant frequency. To provide.

Another object of the present invention is to provide a tuning inlay to facilitate the recognition of the terminal by connecting a plurality of capacitors in parallel to the RF chip mounting to facilitate the flow of high frequency.

Still another object of the present invention is to provide a tuning inlay that can be applied to various smart cards, RFID, traffic cards, access cards, membership cards, etc. having an RF interface function by allowing fine tuning of resonant frequencies.

According to a feature of the present invention for achieving the above object,

An upper antenna formed along an upper edge of the base substrate;

A lower surface antenna connected to one end of the upper surface antenna through a first through hole and formed along an edge of the lower surface of the base substrate;

An RF chip mounting part connected to the other end of the upper antenna through a second through hole and simultaneously connected to the lower antenna to form a closed loop;

An inductance increase pattern formed of a plurality of connected patterns and connected to one side of the top antenna, and having an effective length of the top antenna when the patterns are sequentially cut to increase the inductance and lower the resonance frequency;

An inductance reduction pattern which is formed of a plurality of broken patterns and is connected to one side of the bottom antenna, and when the patterns are connected, an effective length of the bottom antenna is reduced to reduce inductance and increase a resonance frequency;

It is connected to the RF chip mounting unit in parallel, and provides a tuning inlay comprising a plurality of capacitors to facilitate the flow of high frequency.

At this time, according to an additional feature of the present invention, the top and bottom antenna is formed of 1 to 3 turns to have a line width (w) of 0.8mm to 1mm and a line spacing (d) of 0.4mm to 0.6mm, respectively Become; It is preferable that at least three capacitors are connected.

Applying the tuning inlay of the present invention, by increasing the inductance by sequentially cutting a plurality of connected patterns in the inductance increase pattern, by reducing the inductance by the process of soldering a plurality of broken patterns sequentially in the inductance reduction pattern The process has the effect of performing fast and precise resonant frequency tuning.

In addition, the inductance increasing pattern and the inductance decreasing pattern are provided to increase and decrease the effective length of the antenna to enable tuning of the resonant frequency, so that it is smooth when applied to various smart cards, RFID, traffic cards, access cards, membership cards, etc. having an RF interface function. It is possible to recognize the card has the effect of providing the user's convenience.

In addition, by connecting three to six capacitors in parallel to the RF chip mounting portion to facilitate the flow of high frequency, there is an effect to make the recognition in the terminal more easily.

1 to 3 are diagrams illustrating the top and bottom surfaces of an inlay having a tuning function according to a preferred embodiment of the present invention.
1 is a view formed of a top antenna 1 turn and a bottom antenna 3 turns,
2 is a diagram in which the top and bottom antennas are formed of two turns, respectively.
3 is a view formed of three top antennas and one bottom antenna.
4 and 5 are diagrams showing modifications of the appearance,
6 is a view illustrating a state in which an RF chip and a capacitor are mounted.
7 is a view showing the shape of the pattern broken in the inductance reduction pattern and the state connected by soldering.

Hereinafter, exemplary embodiments of an inlay having a tuning function according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 3 are diagrams showing the top and bottom surfaces of an inlay with a tuning function according to a preferred embodiment of the present invention.

The present invention can be applied to various smart cards, RFID, traffic card, access card, membership card and the like.

In the accompanying drawings, reference numeral 10 is a base board, 20 is a top antenna, 30 is a bottom antenna, 40 is a first through hole, 50 is a second through hole, 60 is an RF chip mounting part, 70 is an inductance increase pattern, and 80 is an inductance decrease. Pattern 90 indicates capacitor mounting.

In order to manufacture the various cards, a base substrate 10 is provided. The base substrate 10 is an insulator member made of a dielectric material having a predetermined dielectric constant, and is preferably made of a film having a thickness of 0.1 mm or more, such as a PET film, paper, or polyimide film, in consideration of the manufacturing process and manufacturing cost. And, as shown in Figures 1 to 5 as a whole may be variously configured in the form of a square, round, oval or a combination of square and round.

An upper surface antenna 20 is formed along the edge of the upper surface of the base substrate 10, and a lower surface antenna 30 is formed along the edge of the lower surface of the base substrate 10. The top antenna 20 and the bottom antenna 30 are connected to each other through a first through hole 40.

The upper and lower antennas 20 and 30 are formed as conductors on the base substrate 10 using etching or printing techniques. In this case, the top antenna 20 and the bottom antenna 30 may be formed to have a plurality of turns, as shown in Figures 1 to 3 preferably have one to three turns, each 0.8mm It is preferred to have a line width w of 1 to 1 mm and a line spacing d of 0.4 mm to 0.6 mm.

As shown in FIGS. 1 to 3, the total number of turns of the top antenna 20 and the bottom antenna 30 is preferably 4 turns, and in the case of the top antenna 20 being one turn, When the antenna 30 is formed of three turns, and the top antenna 20 is two turns, the bottom surface antenna 30 is formed in two turns, and when the top antenna 20 is three turns, the bottom antenna 30 is one turn. It is formed by turns.

As a result of experiments by the inventors of the present invention, the top antenna 20 has three turns, and the bottom antenna 30 has one turn.

In addition, the bottom surface of the base substrate 10, the RF chip mounting portion which is connected through the top antenna 20 and the second through hole 50 and at the same time connected to the bottom antenna 40 to form a closed loop 60 is formed.

In addition, the upper surface of the base substrate 10, made of a plurality of connected patterns and is connected to one side of the upper antenna 20, when the effective length of the upper antenna 20 when cutting the connected pattern sequentially An inductance increase pattern 70 having a tuning function for increasing the inductance and lowering the resonance frequency is formed.

In addition, the bottom surface of the base substrate 10 is made of a plurality of broken patterns and connected to one side of the bottom antenna 30, the effective length of the bottom antenna 30 when selectively soldering the broken pattern is The inductance reduction pattern 80 is formed to reduce the inductance and reduce the inductance and increase the resonance frequency.

A plurality of connected patterns of the inductance increase pattern 70 and a plurality of broken patterns of the inductance decrease pattern 80 are finely adjusted for resonant frequency adjustment, and the division intervals of the tuning patterns are 0.1 to 10 mm apart depending on the required frequency increment. It is desirable to have.

In addition, a lower surface of the base substrate 10, the capacitor mounting portion 90 is connected to the RF chip mounting portion 60 in parallel, the plurality of capacitors coupled to facilitate the flow of high frequency is formed. In this case, it is preferable that three or six capacitors may be connected to the capacitor mounting unit 90.

Referring to the tuning operation in the tuning inlay according to the present invention having the configuration as described above are as follows.

6, an RF chip 65 is mounted on the RF chip mounting unit 60, and three capacitors 91, 92 and 93 are connected to the capacitor mounting unit 90. As shown in FIG.

In the inductance increase pattern 70 formed on the upper surface of the base substrate 10, as shown in FIG. 1, first, second, and third patterns (refer to reference numerals 71, 72, and 73) among a plurality of connected patterns are used. When the sequential cutting is performed, the effective length of the top antenna 20 is increased by dL1 to increase the inductance and lower the resonance frequency.

In addition, in the inductance reduction pattern 80 formed on the bottom surface of the base substrate 10, when the third pattern (see reference numeral 83) among the plurality of broken patterns is soldered and connected as shown in FIG. The effective length of) is reduced by dL2, which reduces the inductance and increases the resonance frequency. In this case, the broken pattern preferably has a shape that can be easily connected by soldering, as shown in FIG. 7, and selectively soldering the third pattern (see reference numeral 83) of the plurality of broken patterns in FIG. 2. The soldering connection of the first pattern (see reference numeral 81), the second pattern (see reference numeral 82), and the third pattern (see reference numeral 83) in sequence has the same effect.

For the same reason as above, it is possible to tune while soldering the broken patterns sequentially or selectively by soldering one broken pattern.

As a result, in the present invention, the inductance increasing pattern 70 and the inductance decreasing pattern 80 are composed of a plurality of patterns, so that fine frequency adjustment is possible by increasing or decreasing the effective length of the antenna, and a plurality of capacitors 91, 92, and 93. Error can be minimized and final resonant frequency adjustment including the error by capacitor can be done together.

The present invention can be applied to various smart cards, RFID, traffic cards, access cards, membership cards, etc. having an RF interface function, so that the precise resonant frequency tuning is possible, the invention is highly applicable to the industry.

10: base substrate 20: top antenna
30: bottom antenna 40: first through hole
50: second through hole 60: RF chip mounting portion
70: inductance increase pattern 80: inductance decrease pattern
90: capacitor mounting portion

Claims (2)

An upper antenna formed along an upper edge of the base substrate;
A lower surface antenna connected to one end of the upper surface antenna through a first through hole and formed along an edge of the lower surface of the base substrate;
An RF chip mounting part connected to the other end of the upper antenna through a second through hole and simultaneously connected to the lower antenna to form a closed loop;
An inductance increase pattern formed of a plurality of connected patterns and connected to one side of the top antenna, and having an effective length of the top antenna when the patterns are sequentially cut to increase the inductance and lower the resonance frequency;
An inductance reduction pattern which is formed of a plurality of broken patterns and is connected to one side of the bottom surface antenna, and the effective length of the bottom surface antenna is reduced when the patterns are sequentially connected to reduce the inductance and increase the resonance frequency;
And a plurality of capacitors connected in parallel to the RF chip mounting part and configured to include a plurality of capacitors that facilitate high-frequency flow. The method of claim 1,
The top and bottom antennas are formed in 1 to 3 turns so as to have a line width w of 0.8 mm to 1 mm and a line spacing d of 0.4 mm to 0.6 mm, respectively;
Tuning inlay, characterized in that more than three capacitors are connected.

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