KR101731730B1 - Label using electronic tag sheet - Google Patents

Abstract

The present invention relates to a label using an electronic tag sheet. According to an embodiment of the present invention, the label using the electronic sheet comprises: a synthetic resin sheet of which one surface includes at least one among a symbol, a character, a figure, a three-dimensional shape, and a combination thereof; a first adhesive sheet adhering to the other surface of the synthetic resin sheet; an electronic tag sheet having one surface coupled to the synthetic resin sheet by the first adhesive sheet; a second adhesive sheet adhering to the other surface of the electronic tag sheet; and a shielding sheet which is formed as a plurality of ferrite blocks are spaced apart from each other and are vertically stacked, and is coupled to the electronic tag sheet by the second adhesive sheet. As a result, the present invention can prevent diffused reflection by converting a radio wave generated form the electronic tag into thermal energy.

Description

Label using electronic tag sheet {LABEL USING ELECTRONIC TAG SHEET}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a label using an electronic tag sheet, and more particularly, to a labeling technique for preventing irregular reflection of radio waves.

Recently, various functions such as RFID, NFC, wireless charger and interactive pen tablet have been added to portable terminals including smart phones and tablet PCs. Near-field communication (NFC) is a non-contact type short-range wireless communication module that uses 13.56Mz frequency band as one of RFID tags and transmits data between terminals at a distance of 10cm. NFC is widely used not only for mobile payment, but also for transferring travel information for goods information and visitors in supermarkets and general stores, transportation, access control locks, business cards, and so on.

In addition, a magnetic field of 100 kHz to several tens MHz is generated in the secondary coil of the portable terminal when performing an NFC function with an RFID reader or an adjacent terminal. Therefore, in order to maximize the performance of the additional function by preventing the influence of the magnetic field on the components (particularly, the battery) of the portable terminal due to the magnetic field and focusing the magnetic field, the magnetic shielding sheet is essential .

Korean Patent Registration No. 10-1427704 (published on Aug. 07, 2014) discloses a built-in antenna and a method of manufacturing the same. The antenna includes an adhesive tape, a first antenna pattern transferred onto one surface of the adhesive tape, A second antenna pattern to be transferred to the other surface of the adhesive tape, and a ferrite film laminated on the first antenna pattern and the second antenna pattern.

However, the conventional technique is difficult to use in the form of a sticker label because of its thick thickness, and there is a limitation in that the shielding effect may vary depending on the permittivity of the ferrite film.

SUMMARY OF THE INVENTION The present invention provides a label using an electronic tag sheet capable of converting a radio wave generated from an electronic tag into thermal energy to prevent irregular reflection and minimizing heat generation while preventing diffused reflection of radio waves .

A label using an electronic tag sheet according to an embodiment of the present invention includes a synthetic resin sheet on one side of which at least one of symbols, characters, figures, three-dimensional shapes and combinations thereof is formed, An electronic tag sheet, comprising: an electronic tag sheet having one side joined to the synthetic resin sheet by the first adhesive sheet; a second adhesive sheet adhered to the other side of the electronic tag sheet; a plurality of ferrite blocks separated from each other, And a shielding sheet joined to the electronic tag sheet by the second adhesive sheet.

A label using an electronic tag sheet according to another embodiment of the present invention includes a metal sheet on one side of which at least one of symbols, characters, figures, three-dimensional shapes and combinations thereof are formed, A first adhesive sheet, a plurality of ferrite blocks spaced apart from each other and stacked on top of each other, wherein the shield sheet is bonded to the metal sheet by the first adhesive sheet, a second adhesive sheet bonded to the other surface of the shield sheet, And an electronic tag sheet whose one surface is engaged with the shielding sheet by the second adhesive sheet.

The shielding sheet may include a first ferrite sheet formed by spacing a plurality of first ferrite blocks having a first permittivity from each other and a plurality of second ferrite blocks having a second permittivity spaced from each other, And a second ferrite sheet laminated at a position corresponding to the spaced space of the first ferrite block.

In addition, a third adhesive sheet adhered to the other surface of the shielding sheet and a release sheet detachably attached to the third adhesive sheet may be further included.

A method of manufacturing a label using an electronic tag sheet according to another embodiment of the present invention includes the steps of forming a synthetic resin sheet on at least one side of a synthetic resin sheet to form at least one of a symbol, a letter, a figure, a three- An electronic tag sheet joining step of joining an electronic tag sheet to the synthetic resin sheet to which the first adhesive sheet is adhered, a step of joining the electronic tag sheet to the other side of the electronic tag sheet, A plurality of ferrite blocks are stacked on top of each other to form a shielding sheet, and then the shielding sheet is bonded to the electronic tag sheet to which the second adhesive sheet is adhered And a shield sheet bonding step.

Thus, it is possible to convert the radio wave generated from the electronic tag into thermal energy, thereby preventing irregular reflection. In addition, it is possible to minimize heat generation while preventing irregular reflection of radio waves.

1 is an exploded perspective view of a label using an electronic tag sheet according to an embodiment of the present invention,
Fig. 2 is a sectional view of the label using the electronic tag sheet according to Fig. 1,
3 is an exemplary view for explaining an identification code formed on a synthetic resin sheet in a label using the electronic tag sheet according to the present invention;
FIG. 4 is an exemplary view for explaining a shielding sheet in a label using the electronic tag sheet according to FIG. 1;
FIG. 5 is an exploded perspective view of a label using an electronic tag sheet according to another embodiment of the present invention, FIG.
Fig. 6 is a sectional view of the label using the electronic tag sheet according to Fig. 5,
Fig. 7 is a perspective view of a metal sheet in a label using the electronic tag sheet according to Fig. 5,
8 is a flowchart of a method of manufacturing a label using an electronic tag sheet according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of the functions in the embodiments, and the meaning of the terms may vary depending on the user, the intention or the precedent of the operator, and the like. Therefore, the meaning of the terms used in the following embodiments is defined according to the definition when specifically defined in this specification, and unless otherwise defined, it should be interpreted in a sense generally recognized by those skilled in the art.

FIG. 1 is an exploded perspective view of a label using an electronic tag sheet according to an embodiment of the present invention. FIG. 2 is a sectional view of the label using the electronic tag sheet according to FIG. 1, Fig. 4 is an exemplary view for explaining a shielding sheet in a label using the electronic tag sheet shown in Fig. 1. Fig.

1 to 4, a label 100 using an electronic tag sheet according to an embodiment of the present invention includes a synthetic resin sheet 110, a first adhesive sheet 120, an electronic tag sheet 130, An adhesive sheet 140 and a shielding sheet 150.

The synthetic resin sheet 110 is formed of PVC, PET, PETG, PC, or carbon synthetic resin material, and at least one of symbols, characters, figures, three-dimensional shapes, and combinations thereof is formed on one surface. For example, at least one of card information of a credit card, a hologram, a signature plate, and a magnetic tape may be formed on the synthetic resin sheet 110. The thickness of the synthetic resin sheet 110 may vary depending on the user's setting. It is also possible to print at least one of symbols, characters, figures, three-dimensional shapes and combinations thereof on the synthetic resin sheet 110 before coating.

In addition, the first identification code 111 may be formed on the synthetic resin sheet 110. The first identification code 111 is used to encompass a code that displays first identification information of numbers, letters, and images, such as a bar code, a QR code, and an AR code. As shown in Fig. 3, the first identification code 111 is printed on the upper surface of the label. The first identification code 111 serves to generate a user ID and the like together with a second identification code for the second identification information input to the electronic tag 131 of the electronic tag sheet 130 to be described later.

For example, it is possible to acquire the first identification code 111 through the photographing means of the user terminal 10, and obtain the second identification code stored in the electronic tag 131 using the wireless communication function. In this case, the user terminal can check whether the user has a valid ID. For example, if the label is used as a proof of residence, it is possible to prevent a minor from falsifying the identification card. In this case, the first identification code 111 and the second identification code may be the same information, or the first identification code 111 and the second identification code may be combined to form one valid ID.

The first adhesive sheet 120 is adhered to the other surface of the synthetic resin sheet 110 to maintain adhesion with the electronic tag sheet 130, which will be described later. The first adhesive sheet 120 may be formed to have a predetermined thickness so as to have a predetermined adhesive force. The first adhesive sheet 120 may be in the form of a film, but it may be formed in a coated form. The first adhesive sheet 120 can be fused by heat or adhered in a laminated manner.

The electronic tag sheet 130 is bonded to the synthetic resin sheet 110 by the first adhesive sheet 120 on one side. The electronic tag sheet 130 has an antenna 132 formed in a coil shape on a flat plate of a synthetic resin material, and an antenna 132 is connected to the electronic tag 131 to perform RF communication. In this case, the RFID tag sheet 130 is preferably capable of RF communication, NFC communication, and Bluetooth communication, but is not limited thereto. The electronic tag 131 may be an IC chip, and in this case, it may be exposed to an open surface of the synthetic resin sheet 110. The electronic tag sheet 130 is joined to the shielding sheet 150 by the second adhesive sheet 140 which will be described later.

The second adhesive sheet 140 is adhered to the other surface of the electronic tag sheet 130 to maintain adhesion with the shielding sheet 150, which will be described later. The second adhesive sheet 140 may be formed to have a predetermined thickness and have a predetermined adhesive force. The second adhesive sheet 140 may be in the form of a film, but it may be formed in a coated form. The second adhesive sheet 140 may be fused by heat or may be laminated. The second adhesive sheet 140 may be formed of the same component as the first adhesive sheet 120, but is not limited thereto.

The shielding sheet 150 is combined with the electronic tag sheet 130 by the second adhesive sheet 140 to prevent reflection of radio waves by the electronic tag sheet 130. [ The shielding sheet 150 is formed by vertically stacking a plurality of ferrite blocks spaced apart from each other, so that the wave is guided through the spaced space of the shielding sheet 150 to be converted into thermal energy. For example, the ferrite block can be formed by squeezing the ferrite powder through a polymer bond in the form of a coin.

More specifically, the shielding sheet 150 is composed of a first ferrite sheet 151 and a second ferrite sheet 152. The first ferrite sheet 151 is formed by spacing a plurality of first ferrite blocks having a first permittivity. For example, the first permittivity of the first ferrite may be formed with a permittivity capable of blocking the propagation of low-frequency waves. The second ferrite sheet 152 is formed by stacking a plurality of second ferrite blocks having a second permittivity spaced apart from each other at positions corresponding to the spaced apart spaces of the plurality of first ferrite blocks. For example, the second permittivity of the second ferrite may be formed to have a permittivity capable of blocking the propagation of high-frequency waves.

As shown in FIGS. 2 and 4, the first ferrite sheet 151 and the second ferrite sheet 152 are spaced apart from each other at the time of upper and lower engagement. The radio waves induced from the electronic tag sheet 130 travel around the spaced space between the first ferrite sheet 151 and the second ferrite sheet 152 and are converted into heat energy and are lost. Therefore, it is possible to minimize the communication trouble due to the diffuse reflection of the radio wave.

Meanwhile, the label 100 using the electronic tag sheet according to another embodiment of the present invention may further include the third adhesive sheet 160 and the release paper 170.

The third adhesive sheet 160 is bonded to the other surface of the shielding sheet 150. Specifically, the third adhesive sheet 160 may be formed with the same components as the first adhesive sheet 120 or the second adhesive sheet 140. [ The third adhesive sheet 160 is bonded to the shielding sheet 150 on one side and to the releasing paper 170 on the other side. The third adhesive sheet 160 allows the release paper 170 to be removed and attached to the surface of another object.

The releasing paper 170 is detachably attached to the third adhesive sheet 160 with predetermined adhesion force, and when the release paper 170 is removed, the third adhesive sheet 160 is exposed to the outside.

FIG. 5 is an exploded perspective view of a label using an electronic tag sheet according to another embodiment of the present invention, FIG. 6 is a sectional view of a label using the electronic tag sheet according to FIG. 5, In which a metal sheet is used.

5 to 7, a label 500 using an electronic tag sheet according to another embodiment of the present invention includes a metal sheet 510, a first adhesive sheet 520, a shielding sheet 530, An adhesive sheet 540, an electronic tag sheet 550, a third adhesive sheet 560, and a synthetic resin sheet 570.

The metal sheet 510 is formed at the top. In this case, the metal sheet 510 is formed with a heat dissipating groove 511 having a predetermined pattern on the surface facing the shielding sheet 530 described later. The metal sheet 510 serves to firmly support the shape of the label 500, and the other surface may be formed with printing or engraving composed of symbols, characters, and graphics. The metal sheet 510 serves to heat the heat generated from the electronic tag sheet 550, which will be described later, when the electromagnetic waves are converted into heat energy through the shielding sheet 530, to the outside. The shape of the heat dissipation groove 511 may be a straight line or a lattice pattern, but is not limited thereto. Accordingly, the heat generation due to the conversion of the radio wave into the thermal energy can be reduced.

The first adhesive sheet 520 is adhered to the other surface of the metal sheet 510 and serves to maintain adhesion with a later-described carbon sheet 530. The first adhesive sheet 520 may be formed to have a predetermined thickness and have a predetermined adhesive force. The first adhesive sheet 520 may be in the form of a film, but it may be formed in a coated form. The first adhesive sheet 520 may be fused by heat or adhered in a laminated manner.

The shielding sheet 530 is engaged with the electronic tag sheet 550 by the second adhesive sheet 540 to prevent reflection of radio waves by the electronic tag sheet 550. The shielding sheet 530 is formed by vertically stacking a plurality of ferrite blocks spaced apart from each other, so that the wave is guided through the spaced space of the shielding sheet 530 to be converted into thermal energy. For example, the ferrite block can be formed by squeezing the ferrite powder through a polymer bond in the form of a coin.

More specifically, the shielding sheet 530 is composed of a first ferrite sheet 531 and a second ferrite sheet 532. The first ferrite sheet 531 is formed such that a plurality of first ferrite blocks having a first permittivity are spaced apart from each other. For example, the first permittivity of the first ferrite block may be formed with a permittivity that can block the propagation of low-frequency waves. The second ferrite sheet 532 is formed by stacking a plurality of second ferrite blocks having a second permittivity spaced apart from each other at positions corresponding to the spaced apart spaces of the plurality of first ferrite blocks. For example, the second permittivity of the second ferrite block may be formed with a permittivity that can block radio waves.

As shown in FIG. 6, the first ferrite sheet 531 and the second ferrite sheet 532 are spaced apart from each other at the time of upper and lower engagement. The radio waves derived from the electronic tag sheet 550 travel around the spaced space between the first ferrite sheet 531 and the second ferrite sheet 532 and are converted into heat energy and are lost. Therefore, it is possible to minimize the communication trouble due to the diffuse reflection of the radio wave.

The second adhesive sheet 540 is adhered to the other surface of the electronic tag sheet 550 to maintain adhesion with the shield sheet 530 described later. The second adhesive sheet 540 may be formed to have a predetermined thickness and have a predetermined adhesive force. The second adhesive sheet 540 may be in the form of a film, but it may be formed in a coated form. The second adhesive sheet 540 can be fused by heat or adhered in a laminated manner. The second adhesive sheet 540 may be formed of the same component as the first adhesive sheet 520, but is not limited thereto.

The electronic tag sheet 550 is joined to the shielding sheet 530 by a second adhesive sheet 540 on one side. In the RFID tag sheet 550, an antenna 552 is formed in a coil shape on a flat plate of a synthetic resin material, and an antenna 552 is connected to the RFID tag 551 to perform RF communication. In this case, the electronic tag sheet 550 is preferably capable of RF communication, NFC communication, and Bluetooth communication, but is not limited thereto. The electronic tag 551 may be an IC chip, and in this case, it may be exposed on an open surface of the synthetic resin sheet 570. The electronic tag sheet 550 is bonded to the synthetic resin sheet 570 by the third adhesive sheet 560, which will be described later.

The third adhesive sheet 560 is bonded to the other surface of the shielding sheet 550 and serves to maintain adhesion with a synthetic resin sheet 570 described later. The third adhesive sheet 560 may be formed to have a predetermined thickness and have a predetermined adhesive force. The third adhesive sheet 560 may be in the form of a film, but it may be formed in a coated form. The third adhesive sheet 560 may be fused by heat or may be laminated. The third adhesive sheet 560 may be formed of the same components as the first adhesive sheet 520 and the second adhesive sheet 540, but is not limited thereto.

The synthetic resin sheet 570 is formed of PVC, PET, PETG, PC, or carbon synthetic resin material, and at least one of symbols, characters, figures, three-dimensional shapes, and combinations thereof is formed on one surface. For example, at least one of card information of a credit card, a hologram, a signature plate, and a magnetic tape may be formed on the synthetic resin sheet 570. The thickness of the synthetic resin sheet 570 may vary depending on the user's setting, and it is also possible to print at least one of symbols, characters, figures, three-dimensional shapes, and combinations thereof on the synthetic resin sheet 570 before coating.

In addition, a first identification code (not shown) may be formed on the synthetic resin sheet 570. The first identification code is used to encompass a code that displays first identification information of numbers, letters, and images, such as a bar code, a QR code, and an AR code. A first identification code 111 as shown in Fig. 3 can be printed. The first identification code serves to generate a user ID and the like together with a second identification code for the second identification information input to the electronic tag 551 of the electronic tag sheet 550. [ In this case, the first identification code may be formed on the upper portion of the metal sheet 510.

In addition, the synthetic resin sheet 570 can be removed from the third adhesive sheet 560 to expose the adhesive surface of the third adhesive sheet 560. This is for the purpose of attaching the label 500 using the electronic tag sheet to other objects.

8 is a flowchart of a method of manufacturing a label using an electronic tag sheet according to another embodiment of the present invention.

Referring to FIG. 8, in a method of manufacturing a label using an electronic tag sheet according to another embodiment of the present invention, a synthetic resin sheet is formed by forming a synthetic resin sheet on one side with symbols, characters, figures, At least one is formed (S810). The synthetic resin sheet is formed of synthetic resin as a flat plate. In this case, the identification mark can be formed by printing on the surface of the synthetic resin sheet. The shape and thickness of the synthetic resin sheet may vary depending on user settings.

Next, in the first bonding step, the first adhesive sheet is bonded to the other surface of the synthetic resin sheet (S820). In this case, the first adhesive sheet may be in the form of a film or may form a layer through application. When one surface of the first adhesive sheet is adhered to one surface of the synthetic resin sheet, a thermal fusion or lamination technique can be used.

Next, the electronic tag sheet engaging step joins the electronic tag sheet to the synthetic resin sheet to which the first adhesive sheet is adhered (S830). The electronic tag sheet is a flat sheet having an electronic tag and an antenna formed thereon, and the synthetic resin sheet and the electronic tag sheet can be bonded to both sides using the first adhesive sheet. In this case, thermal fusion bonding or lamination can be used on both sides.

Next, in the second bonding step, the electronic tag sheet may be coupled to one side and the shielding sheet may be coupled to the other side (S840). In this case, the identification mark can be formed by printing on the surface of the synthetic resin sheet. The shape and thickness of the synthetic resin sheet may vary depending on user settings.

Next, in the step of joining the shielding sheets, a plurality of ferrite blocks are stacked on top of each other to form a shielding sheet, and then the shielding sheet is joined to a shielding sheet for joining the second adhesive sheet to the electronic tag sheet to which the second adhesive sheet is attached (S850 ). The shielding sheet is a maze-like structure used to convert radio waves into heat energy as described above, and uses a ferrite component. In this case, the first ferrite sheet and the second ferrite sheet, which are divided into the upper and lower layers, can be coupled to each other in correspondence with the spaced spaces.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, Therefore, the present invention should be construed as a description of the claims which are intended to cover obvious variations that can be derived from the described embodiments.

100: Label
110: synthetic resin sheet
111: first identification code
120: first adhesive sheet
130: Electronic tag sheet
131: Electronic tag
132: antenna
140: second adhesive sheet
150: Shielding sheet
151: first ferrite sheet
152: second ferrite sheet
160: third adhesive sheet
170: release paper
500: Label
510: metal sheet
511: Heat dissipation groove
520: first adhesive sheet
530: Shielding sheet
531: first ferrite sheet
532: second ferrite sheet
540: second adhesive sheet
550: Electronic tag sheet
551: Electronic tag
552: Antenna
560: third adhesive sheet
570: synthetic resin sheet

Claims (5)

A synthetic resin sheet in which at least one of symbols, characters, figures, three-dimensional shapes and combinations thereof is formed on one surface;
A first adhesive sheet adhered to the other surface of the synthetic resin sheet;
An electronic tag sheet having one surface joined to the synthetic resin sheet by the first adhesive sheet;
A second adhesive sheet adhered to the other surface of the electronic tag sheet; And
A plurality of ferrite blocks formed by compressing ferrite powder in the form of a coin through a polymer bond, the plurality of ferrite blocks being stacked on top of each other, and the shielding sheet being joined to the electronic tag sheet by the second adhesive sheet,
The shielding sheet
A first ferrite sheet formed with a plurality of first ferrite blocks having a first permittivity spaced apart from each other; And
And a second ferrite sheet formed by stacking a plurality of second ferrite blocks having a second permittivity spaced apart from each other at positions corresponding to the spaced apart spaces of the plurality of first ferrite blocks label. A metal sheet on which at least one of a symbol, a letter, a figure, a three-dimensional shape and a combination thereof is formed on one surface and a heat dissipation groove of a predetermined pattern is formed on the other surface;
A first adhesive sheet adhered to the other surface of the metal sheet;
A plurality of ferrite blocks formed by compressing ferrite powder in the form of a coin through a polymer bond, the plurality of ferrite blocks being stacked on top of each other and being bonded to the metal sheet by the first adhesive sheet;
A second adhesive sheet adhered to the other surface of the shielding sheet; And
And an electronic tag sheet having one surface joined with the shielding sheet by the second adhesive sheet,
The shielding sheet
A first ferrite sheet formed with a plurality of first ferrite blocks having a first permittivity spaced apart from each other; And
And a second ferrite sheet formed by stacking a plurality of second ferrite blocks having a second permittivity spaced apart from each other at positions corresponding to the spaced apart spaces of the plurality of first ferrite blocks label. delete The method according to claim 1,
A third adhesive sheet adhered to the other surface of the shielding sheet; And
And a release sheet detachably attached to the third adhesive sheet. A synthetic resin sheet forming step of forming at least one of symbols, characters, figures, three-dimensional shapes and combinations thereof on one surface of the synthetic resin sheet;
A first bonding step of bonding a first adhesive sheet to the other surface of the synthetic resin sheet;
An electronic tag sheet engaging step of engaging the electronic tag sheet with the synthetic resin sheet to which the first adhesive sheet is adhered;
A second bonding step of bonding a second adhesive sheet to the other surface of the electronic tag sheet; And
A plurality of ferrite blocks formed by compressing ferrite powder in the form of a coin through a polymer bond are stacked on top of each other to form a shielding sheet and then the shielding sheet is laminated on the electronic tag sheet to which the second adhesive sheet is adhered The method of claim 1,
The shielding sheet
A first ferrite sheet formed with a plurality of first ferrite blocks having a first permittivity spaced apart from each other; And
And a second ferrite sheet formed by stacking a plurality of second ferrite blocks having a second permittivity spaced apart from each other at positions corresponding to the spaced apart spaces of the plurality of first ferrite blocks ≪ / RTI >

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