KR100911198B1 - Method of manufacturing metallic resonator fiber for RFID and method of manufacturing RFID - Google Patents

Abstract

The present invention relates to a method for manufacturing a metallic resonator fiber for a radio frequency identification tag and a method for manufacturing a radio frequency identification tag, by forming a nano-sized metallic resonator fiber for a radio frequency identification tag by a stamping process This has the advantage of lowering the manufacturing cost.

In addition, the present invention by dispersing the metallic resonator fiber to the object to produce a radio frequency identification tag, it can be widely used in various fields, such as anti-counterfeiting of documents, certificates, brand protection of expensive products and item tracking (Tracking) items It works.

In addition, the present invention can be made durable by manufacturing a metal resonator fiber for a radio frequency identification tag having a curved surface, there is an advantage that can improve the antenna characteristics by improving the reflection efficiency of the microwave irradiated from the reader will be.

Tag, RFID, Stamp, Metal, Fiber

Description

Method for manufacturing metallic resonator fiber for radio frequency identification tag and method for manufacturing radio frequency identification tag {Method of manufacturing metallic resonator fiber for RFID and method of manufacturing RFID}

The present invention relates to a method of manufacturing a metallic resonator fiber for a radio frequency identification tag that can easily form a metallic resonator fiber by a stepping process, and a method of manufacturing a radio frequency identification tag.

Recently, the concept of ubiquitous networking has been a hot topic.

At its core is the concept of machine to machine (M2M), the concept of networking between machines and machines that are prevalent in our daily lives.

M2M communication connects everything from the computer's main body to everyday objects, enabling them to be used, and also uses this infrastructure to realize a new level of "smart services."

The core technology that realizes this concept is RFID (Radio Frequency IDentification) technology.

Currently, RFID is a contact-less, non-line-of-sight data acquisition technology that inputs identification information into a tiny IC chip and uses radio frequency to detect objects, animals, It is a key technology for ubiquitous networking because it can read information about people or track and manage location.

In recent years, the ubiquitous network identifier, which can exist anywhere and everywhere, has to be very inexpensive. Therefore, in order to realize such ultra-low cost, the unit price is reduced to about one cent instead of the conventional RFID. Various researches are being conducted on all items including one-off consumer goods such as bar codes. Some of them are technically proven, and are expected to be used as anti-counterfeiting means such as high-priced products. It is expected to be applied to various industrial fields as well as related technical fields.

On the other hand, the typical conventional technology is a bar code system, but counterfeit and forgery of public documents, various certificates, and expensive goods, etc. are rapidly increasing and the countermeasures against them are emerging as a very urgent social problem.

However, the current RFID system is relatively low in utilization of individual items due to the relatively expensive price, complicated system configuration, etc. compared to the barcode system.

Therefore, it is trying to develop an ultra-low-cost RF-based smart tag that can not be duplicated while maintaining the inherent utility of barcode technology, which can prevent forgery, forgery and theft, and even track individual items.

Ultra-low cost RF-based smart tag technology replaces RFID chips made of conventional silicon semiconductors, and uses organic conductive (OTFT) devices composed of polymer conductive ink or polymer / organic semiconductors, and does not use RFID chips at all. Microwave reflectors technology that uses structural resonance characteristics of the chip, Chipless SAW technology that combines wireless sensor and RFID by using surface acoustic waves, and remote magnetics that can read IDs in a non-contact manner using magnetic materials. Remote magnetics) technology.

The present invention can solve the problem of manufacturing a metallic resonator fiber in a simple process.

According to a first preferred embodiment of the present invention,

Sequentially forming an easy-to-remove thin film, a metallic thin film and a polymer thin film on the substrate;

Pressing an upper portion of the polymer thin film with a stamp in which stripe-shaped protrusions are formed periodically to form stripe-shaped protrusions on the polymer thin film;

Etching the metallic thin film in the region where the stripe-shaped protrusions are not formed to form stripe-shaped protrusions;

There is provided a method of manufacturing a metallic resonator fiber for a radio frequency identification tag, wherein the polymer thin film and the removing thin film are removed to separate a metallic resonator fiber composed of stripe-shaped protrusions of the metallic thin film. .

According to a second preferred embodiment of the present invention,

Sequentially forming an easy-to-remove thin film, a metallic thin film and a polymer thin film on the substrate;

Pressing an upper portion of the polymer thin film with a stamp in which stripe-shaped protrusions are formed periodically to form stripe-shaped protrusions on the polymer thin film;

Etching the metallic thin film in the region where the stripe-shaped protrusions are not formed to form stripe-shaped protrusions;

Removing the polymer thin film and the removal thin film to separate metallic resonator fibers formed of stripe-shaped protrusions of the metallic thin film;

A method is provided for manufacturing a radio frequency identification tag, comprising dispersing the metallic resonator fibers on an object.

According to a third preferred embodiment of the present invention,

Forming an easy-to-remove thin film on the substrate, and forming grooves having a semicircular cross section in a plurality of stripe shapes on the removable thin film;

Sequentially forming a metallic thin film and a polymer thin film on the removal thin film;

Pressing an upper portion of the polymer thin film with a stamp in which grooves having a semi-circular cross section in a stripe shape are periodically formed, thereby forming protrusions having a semi-circular cross section in a stripe shape in the polymer thin film;

Etching the polymer thin film and the metallic thin film to form metallic resonator fibers having a circular cross section in a stripe shape;

Removing the removal thin film to separate the metallic resonator fibers;

A method of manufacturing a radio frequency identification tag is provided that consists of dispersing the metallic resonator fibers on an object.

According to a fourth preferred embodiment of the present invention,

Sequentially forming an adhesive thin film, a metallic thin film and a polymer thin film on the substrate;

Pressing the upper portion of the polymer thin film with a stamp in which fine grooves are dispersed and forming fine protrusions on the polymer thin film;

Etching the metallic thin film in a region where the fine protrusions are not formed to form a metallic resonator fiber including fine protrusions in the metallic thin film;

Removing the polymer thin film and adhering an adhesive sheet on the metallic thin film;

A method of manufacturing a radio frequency identification tag is provided, which comprises bonding the adhesive sheet to an object, leaving the adhesive thin film and the substrate to disperse the metallic resonator fiber in the object.

According to the present invention, a metal resonator fiber for a nano-frequency radio frequency identification tag is formed by a stamping process, thereby lowering the manufacturing cost of the tag compared to a method of manufacturing a radio frequency identification tag using a general silicon chip. There is.

In addition, the present invention by dispersing the metallic resonator fiber to the object to produce a radio frequency identification tag, it can be widely used in various fields, such as anti-counterfeiting of documents, certificates, brand protection of expensive products and item tracking (Tracking) items It works.

In addition, the present invention can be excellent in durability by manufacturing a metal resonator fiber for radio frequency identification tag having a curved surface, there is an effect that can improve the antenna characteristics by improving the reflection efficiency of the microwave irradiated from the reader. .

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1A to 1H are schematic cross-sectional views illustrating a method of manufacturing a metallic resonator fiber for a Radio Frequency IDentification tag according to a first embodiment of the present invention. An easy removal thin film 110 is formed (FIG. 1A).

Here, the substrate 100 is glass, quartz, polyethylenenaphthalate, polyethylene terephthalate, polycarbonate, polyacrylate, polyimide, polyether sulfone It is preferably one of Polyethersulfone and Stainless Steel.

However, in the present invention, the material of the substrate is not limited thereto.

In addition, the removal thin film 110 is preferably formed of wax or photosensitive resin.

Next, the metallic thin film 120 is formed on the removing thin film 110 (FIG. 1B).

The metallic thin film 120 is preferably formed of one of sputtering, electron beam deposition, pulse laser deposition, chemical vapor deposition, inkjet printing, screen printing, spin coating, dip coating, roll coating.

Subsequently, the polymer thin film 130 is formed on the metallic thin film 120 (FIG. 1C).

The metallic thin film 120 is preferably made of one of a metal, a metal oxide, and a conductive polymer, but is not limited thereto.

Instead of the metallic thin film 120, a carbon film may be used.

In addition, the metal is aluminum (Al), magnesium (Mg), copper (Copper), bronze (Bronze), brass (Brass).

That is, the metallic thin film 120 may be defined as a thin film containing metal.

Thereafter, the upper portion of the polymer thin film 130 is pressed by a stamp 150 in which stripe-shaped protrusions are periodically formed, thereby forming stripe-shaped protrusions 135 on the polymer thin film 130. 1d and 1e)

The stamp 150 may use an elastomer such as polydimethysiloxane (PDMS), polyimide, polyurethane, polyurethane, and cross-linked Novolac ^™ resins, but is not limited thereto.

Subsequently, the metallic thin film 130 in the region where the stripe-shaped protrusions 135 are not formed is etched to form stripe-shaped protrusions 125 (FIG. 1F).

Here, the stripe-shaped protrusions 135 made of a polymer thin film have a masking function.

Subsequently, the polymer thin film is removed (FIG. 1G), and the removal thin film 110 is removed to separate stripe-shaped protrusions formed of a metallic thin film, and a metallic resonator fiber for a radio frequency identification tag as illustrated in FIG. 1H. The fabrication of the fibers is complete.

That is, by removing the removal thin film 110, the strip-shaped protrusions 125 formed of the metallic thin film and the substrate 100 are separated.

The metallic resonator fibers for the radio frequency identification tag are formed of the stripe-shaped protrusions 125 remaining after the metallic thin film 130 is etched.

Therefore, as described above, a metallic resonator fiber having a nano size diameter of 100 nm to 10 um, which exhibits reflection resonance characteristics in a microwave of 24 to 25 Ghz or 60 to 66 Ghz, can be manufactured by a simple stepping process. It is.

FIG. 2 is a schematic perspective view illustrating a method of manufacturing a radio frequency identification tag according to a first embodiment of the present invention. As described above, FIG. Thereafter, when the metallic resonator fiber 125 is distributed to the object 200, the radio frequency identification tag is completed.

Here, the object 200 is preferably paper or plastic.

In addition, the metallic resonator fiber 125 is randomly dispersed in the object 200.

In addition, the metallic resonator fiber 125 preferably has a nano-size diameter of 100nm ~ 10um.

That is, according to the first embodiment of the present invention, a radio frequency identification tag may implement a smart tag using transmission and scattering of radio waves by dispersing a very fine nano resonator fiber in an object. Compared to the method of manufacturing the radio frequency identification tag, the manufacturing cost of the tag is advantageous.

3A and 3B are schematic conceptual views illustrating the operation of the radio frequency identification tag according to the first embodiment of the present invention, wherein the radio frequency identification tag 200 is mounted on the article 210 and used to identify the article.

Therefore, as shown in FIG. 3A, when microwaves are irradiated to the article 210 by the reader 250, the reflection resonant characteristics are caused by the metallic resonator fiber in the radio frequency identification tag 200 mounted on the article 210. 3B, a reflected wave of a specific waveform is generated, and the reader 250 detects the reflected wave.

Accordingly, the article 210 may be identified by the reflected wave detected by the reader 250.

FIG. 4 is a block diagram illustrating an apparatus for determining an ID based on a reflected wave detected from a radio frequency identification tag according to the present invention. In the above-described reader, a transmitter for transmitting microwaves and a wave reflected from a radio frequency identification tag are received. The receiver is present.

Of course, the reader has only a transmitter, and the receiver may be implemented as a separate device.

When the receiver 251 receives the wave reflected by the radio frequency identification tag, the coding unit 252 is digitally coded, and the ID determining unit 253 determines the ID by the signal coded by the coding unit 252. The ID discrimination signal is output.

Therefore, it is possible to know the authenticity of the article.

Here, the receiver 251, the coding unit 252, and the ID determining unit 253 are controlled by the controller 255.

5A through 5G are schematic views illustrating a method of manufacturing a metallic resonator fiber for a radio frequency identification tag according to a second embodiment of the present invention. ) And grooves having a semi-circular cross section in a plurality of stripe shapes on the removal thin film 310 (FIG. 5A).

Thereafter, a metallic thin film 320 is formed on the removal thin film 310 (FIG. 5B).

Subsequently, the polymer thin film 330 is formed on the metallic thin film 320 (FIG. 5C).

Next, the upper portion of the polymer thin film 330 is pressed by a stamp 340 in which grooves having a semi-circular cross section in a stripe shape are periodically formed, and protrusions having a semi-circular cross section in a stripe shape on the polymer thin film 330 ( 331. (FIGS. 5D and 5E).

Subsequently, the polymer thin film 330 and the metallic thin film 320 are etched to form metallic resonator fibers 370 for an RFID tag having a circular cross section in a stripe shape (FIG. 5F).

In this case, the protrusions 331 having a semi-circular cross section in a stripe shape formed on the polymer thin film 330 are intact on the metallic thin film 320 in the process of etching the polymer thin film 330 and the metallic thin film 320. It is possible to form metallic resonator fibers 370 that are transferred and spaced apart from each other.

This technique is the same as the technique in which the microlens-shaped photosensitive film and the lower layer are etched, and the microlens shape is transferred to the lower layer to form a microlens made of the lower layer.

Subsequently, the removal thin film 310 is removed to separate the substrate 100 and the metallic resonator fibers 370 (FIG. 5G).

The metallic resonator fiber for a radio frequency identification tag according to the second embodiment of the present invention manufactured by such a manufacturing process can have excellent durability since the surface is curved, and improves the reflection efficiency of the microwave irradiated from the reader to improve antenna characteristics. There is an advantage that can be excellent.

Subsequently, when the metallic resonator fiber for the radio frequency identification tag according to the second embodiment of the present invention is dispersed in the object, the radio frequency identification tag is manufactured.

6A to 6F are schematic cross-sectional views for describing a method of manufacturing a radio frequency identification tag according to a third embodiment of the present invention, in which an adhesive thin film 510 is formed on a substrate 100 (FIG. 6A). The metal thin film 520 and the polymer thin film 530 are formed on the adhesive thin film 510. (FIG. 6B)

Subsequently, the upper portions of the polymer thin film 530 are pressed by the stamp 540 in which the fine grooves are dispersed to form fine protrusions 531 on the polymer thin film 530.

Next, the metallic thin film 530 in the region where the fine protrusions 531 are not formed is etched to form a metallic resonator fiber made of the fine protrusions 531 in the metallic thin film 530. )

Here, the fine protrusions 531 are nano size.

Thereafter, the polymer thin film is removed, and the adhesive sheet 550 is adhered to the upper portion of the metallic thin film 530. (FIG. 6E)

Subsequently, the adhesive sheet 550 is adhered to the object 600, and the adhesive thin film 510 and the substrate 100 are separated to disperse the metallic resonator fiber in the object 600. And Figure 6g)

Here, when the adhesive force of the adhesive sheet 550 is greater than the adhesive force of the adhesive thin film 510, the adhesive thin film 510 may be easily separated from the metallic resonator fiber.

In addition, the adhesive thin film 510 is preferably a wax.

That is, the radio frequency identification tag according to the third embodiment of the present invention is formed by bonding a metallic resonator fiber to an object.

FIG. 7 is a schematic plan view illustrating a radio frequency identification tag according to a third embodiment of the present invention, wherein metallic resonator fibers adhered to an object 600 are randomly distributed, and the size or shape of the metallic resonator fibers May be the same and the size or shape of some of the metallic resonator fibers may be different.

Although the invention has been described in detail only with respect to specific examples, it will be apparent to those skilled in the art that various modifications and variations are possible within the spirit of the invention, and such modifications and variations belong to the appended claims.

1A to 1H are schematic cross-sectional views illustrating a method of manufacturing a metallic resonator fiber for a Radio Frequency IDentification tag according to a first embodiment of the present invention.

2 is a schematic perspective view for explaining a method of manufacturing a radio frequency identification tag according to a first embodiment of the present invention;

3A and 3B are schematic conceptual views illustrating the operation of a radio frequency identification tag according to a first embodiment of the present invention.

4 is a block diagram illustrating the configuration of an apparatus for determining an ID based on a reflected wave detected from a radio frequency identification tag according to the present invention.

5A through 5G are schematic diagrams for explaining a method of manufacturing a metallic resonator fiber for a radio frequency identification tag according to a second embodiment of the present invention.

6A through 6F are schematic cross-sectional views illustrating a method of manufacturing a radio frequency identification tag according to a third embodiment of the present invention.

7 is a schematic plan view showing a radio frequency identification tag according to a third embodiment of the present invention.

Claims (12)

Sequentially forming an easy-to-remove thin film, a metallic thin film and a polymer thin film on the substrate; Pressing an upper portion of the polymer thin film with a stamp in which stripe-shaped protrusions are formed periodically to form stripe-shaped protrusions on the polymer thin film; Etching the metallic thin film in the region where the stripe-shaped protrusions are not formed to form stripe-shaped protrusions; And removing the polymer thin film and the removing thin film to separate a metallic resonator fiber composed of stripe-shaped protrusions of the metallic thin film. Sequentially forming an easy-to-remove thin film, a metallic thin film and a polymer thin film on the substrate; Pressing an upper portion of the polymer thin film with a stamp in which stripe-shaped protrusions are formed periodically to form stripe-shaped protrusions on the polymer thin film; Etching the metallic thin film in the region where the stripe-shaped protrusions are not formed to form stripe-shaped protrusions; Removing the polymer thin film and the removal thin film to separate metallic resonator fibers formed of stripe-shaped protrusions of the metallic thin film; Dispersing the metallic resonator fibers over an object. Forming an easy-to-remove thin film on the substrate, and forming grooves having a semicircular cross section in a plurality of stripe shapes on the removable thin film; Sequentially forming a metallic thin film and a polymer thin film on the removal thin film; Pressing an upper portion of the polymer thin film with a stamp in which grooves having a semi-circular cross section in a stripe shape are periodically formed, thereby forming protrusions having a semi-circular cross section in a stripe shape in the polymer thin film; Etching the polymer thin film and the metallic thin film to form metallic resonator fibers having a circular cross section in a stripe shape; Removing the removal thin film to separate the metallic resonator fibers; Dispersing the metallic resonator fibers over an object. Sequentially forming an adhesive thin film, a metallic thin film and a polymer thin film on the substrate; Pressing the upper portion of the polymer thin film with a stamp in which fine grooves are dispersed and forming fine protrusions on the polymer thin film; Etching the metallic thin film in a region where the fine protrusions are not formed to form a metallic resonator fiber including fine protrusions in the metallic thin film; Removing the polymer thin film and adhering an adhesive sheet on the metallic thin film; Adhering the adhesive sheet to an object, leaving the adhesive thin film and the substrate, and dispersing the metallic resonator fiber in the object. The method according to claim 4, A method of manufacturing a radio frequency identification tag, characterized in that the adhesion of the adhesive sheet is greater than the adhesive force of the adhesive thin film. The method according to claim 4, And the size or shape of some of the metallic resonator fibers are different. The method according to claim 2, wherein The object, A method of manufacturing a radio frequency identification tag, which is paper or plastic. The method according to claim 2, wherein And randomly dispersing the metallic resonator fiber in the object. The method according to claim 2, wherein The metallic thin film, Method of manufacturing a radio frequency identification tag, characterized in that made of one of a metal, a metal oxide, a conductive polymer, carbon (Carbon). The method according to claim 2, wherein The metallic thin film, A method of manufacturing a radio frequency identification tag, characterized in that it is formed by one of sputtering, electron beam deposition, pulse laser deposition, chemical vapor deposition, inkjet printing, screen printing, spin coating, dip coating and roll coating. The method according to claim 2, wherein The stamp is, A method of manufacturing a radio frequency identification tag, characterized in that it is formed of one of PDMS (polydimethysiloxane), polyimide, polyurethane (polyureth anes) and cross-linked Novolac ( ^TM ) resins. The method according to claim 2, wherein The diameter of the metallic resonator fiber, Method of manufacturing a radio frequency identification tag, characterized in that 100nm ~ 10um.

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