KR101520063B1 - Rfid tag examination device and rfid incoding system including same - Google Patents

Abstract

The present invention relates to an RFID tag examination device and an RFID encoding system including the same. Specifically, the RFID tag examination device to detect if an RFID tag attached to a product is properly encoded according to an embodiment of the present invention comprises: an antenna unit to emit an RF signal and receive information encoded on the RFID tag; a reader to receive encoding information from the antenna unit and decode the encoding information; and a connection unit to support the antenna unit and connect the antenna unit and the reader. The antenna unit continuously emits an RF signal, and the emitted RF signal is diffracted through a slit formed on the antenna unit to form an electromagnetic field region.

Description

Technical Field [0001] The present invention relates to an RFID tag validation apparatus and an RFID encoding system including the RFID tag validation apparatus.

The present invention relates to an RFID tag validation apparatus and an RFID encoding system including the same.

Generally, in order to facilitate classification of products in packaging products such as medicines, bar codes or bar code stickers are attached, but the bar code system has limitations in obtaining contact information. In order to overcome the limitation of the barcode system, a product developed recently for replacing the RFID (Radio Frequency IDentification) tag with the barcode has been recently introduced.

An RFID tag is a tag that can recognize and identify information at a distance using radio waves. An RFID reader is needed to recognize and identify information using RFID tags. An RFID tag is composed of an antenna and an integrated circuit, which records information in an integrated circuit and transmits information to an RFID reader through an antenna.

RFID tags differ from bar code systems in that they use radio waves instead of reading them using light. Thus, it does not work on short distances like barcode readers, it can read tags from a long distance, and even receives information through objects between tags and readers.

RFID tags can be classified by the energy used. Passive RFID that reads and communicates information of chips with only the energy delivered from the reader uses the energy to read the chip information because the tag has built-in battery, and the energy Passive (RFID) type using RFID, and active RFID in which the energy stored in the tag is used for both reading information of the chip and communicating the information.

RFID technology recognizes information of objects by using radio waves from tags attached to objects, and collects, stores, processes, and tracks information of each object to provide various services such as positioning, remote processing, management and information exchange Can be provided. These technologies are expected to lead the innovations in security, safety and environmental management as well as distribution and commodity management by networking and intelligentizing the product management by replacing the existing barcode and expect to form a huge new market that did not exist before do.

Such an RFID tag can store product information that can identify the product. Recording such product information in a chip embedded in the RFID tag is referred to as encoding, and an apparatus for encoding product information in the RFID tag is referred to as an encoder . Reading the encoded information in the RFID tag is called decoding, and the device reading the encoded information in the RFID tag is called a decoder or reader.

On the other hand, as a system for encoding an RFID tag attached to a product, an encoding system such as that disclosed in Patent Document 1 can be used. A specific encoding process of the conventional system disclosed in Patent Document 1 will be described as follows.

First, when the product is conveyed through the conveyor, the first sensor recognizes the product, sends a signal, and then the first RFID reader encodes the ID information to the RFID tag attached to the product via the first antenna. Next, the second sensor recognizes the product and sends a signal to the control box while the product with encoded ID information is continuously conveyed through the conveyor. The second RFID reader reads the ID information of the RFID tag attached to the product through the second antenna.

The control box determines whether the ID information is normally encoded based on the read ID information, and performs the RFID tag write lock operation through the second antenna if it is normally encoded. The second RFID reader recognizes the product and sends a signal to the control box while the tag record locking operation is carried out continuously through the conveyor, and the second RFID reader transmits the RFID tag attached to the product (box) through the second antenna, Quot; ID "

The control box determines whether the ID information is normally encoded based on the read ID information. If the encoding information is normally encoded, the control box passes the encoded information. If an encoding error occurs, the automatic selector pushes the product out of the conveyor.

However, since the conventional encoding system shifts the product to encode ID information from the conveyor at a high speed (about 45 m / min or more), the time for which the tag is exposed to the recognition range of the RFID reader is very short, And a wall for shielding electromagnetic waves must be installed around the reader in order to prevent a recognition error, and there is a problem that the size of the reader device becomes large and the cost for the installation becomes expensive.

Further, when the conveyance speed of the conveyor is slowed to clearly recognize the RFID information, there is a problem that the process speed is slowed and the process efficiency is low.

In addition, there is a disadvantage in that it is not possible to flexibly change an arrangement position and recognition angle of the antenna according to the size of the product to which the RFID tag is attached.

Korean Patent Publication No. 10-2011-0016380

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-described problems of the prior art, and it is an object of the present invention to provide an antenna device that can miniaturize a device and reduce costs for equipment, And an RFID encoding system including the same.

According to an aspect of the present invention, there is provided an RFID tag inspection apparatus for verifying whether or not an RFID tag attached to a product is correctly encoded, the RFID tag inspection apparatus comprising: an antenna unit for emitting an RF signal to receive encoded information in the RFID tag; A reader for receiving and decoding the encoding information received by the antenna unit; And a connection unit for supporting the antenna unit and connecting the antenna unit and the reader, wherein an RF signal is continuously emitted from the antenna unit, an RF signal emitted through a slit formed in the antenna unit is diffracted, The RFID tag inspection apparatus may be provided.

The antenna unit may further include: a main body; And a signal transceiver provided in the main body and connected to the reader through a signal transfer line to emit an RF signal to receive a signal reflected from the RFID tag and transmit the signal to the reader, And a transmission / reception path through which a received signal passes are formed in the main body, and the transmission / reception path communicates with the outside through the slit.

Also, the RFID tag inspecting apparatus having a shape in which the cross-sectional area becomes narrower toward the slit from the inside of the main body can be provided.

In addition, the connection part may be made of a bellows capable of deforming the shape, and the position of the antenna part can be changed by deforming the shape of the connection part.

The RFID tag inspection apparatus may further include a sensor for recognizing the product that has passed through the antenna unit.

In addition, an RFID tag acceptance apparatus may be further provided, which further includes a monitor for displaying the acceptance result of the RFID tag.

A moving body including a wheel so as to be movable downward; And a support for connecting the connection unit, the antenna unit, and the reader to the mobile body.

A conveyor line on which the product to which the RFID tag is attached is conveyed; an encoder provided on the conveyor line and encoding the product information in the RFID tag; And an RFID tag validation apparatus according to any one of claims 1 to 7 for verifying whether or not the information encoded in the RFID tag is correct.

According to the embodiment of the present invention, it is possible to simplify the apparatus and reduce the equipment cost, and it is possible to obtain the fluidity in the arrangement of the antennas.

1 is a diagram illustrating an RFID encoding system including an RFID tag validation apparatus according to an embodiment of the present invention.
2 is a perspective view illustrating the antenna unit of FIG.
Fig. 3 is a cross-sectional view of the antenna unit of Fig. 2 taken along line AA.
4 is a view showing an angle change of the antenna part according to a modification of the bellows of FIG.
5 is a control hierarchical view of the RFID encoding system of FIG.
6 is a diagram illustrating an RFID encoding system including an RFID tag validation apparatus according to another embodiment of the present invention.

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

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In the present invention, the RFID tag to be encoded and verified does not have a separate battery and is a passive RFID tag that rectifies an electromagnetic wave sent from an RFID encoder or reader to obtain its operating power and uses it as its power source Active RFID tags with separate batteries are all possible.

The RFID tag includes an RFID tag having a WORM (Write Once Read Many) type memory, which is given a unique ID as RFID tag information and used for the life of the RFID tag when manufacturing an RFID tag (or attaching an RFID tag to a predetermined product) , An RFID tag capable of recording predetermined ID information in at least one writeable memory (WROM and / or WM (Write Many) type memory) as RFID tag information and reusing it.

More specifically, for example, the RFID tag includes a tag antenna formed by using a conductive material (Cu, Al, Ag paste or the like) on a thin film base made of a PET material or a polyimide material, An IC chip to which an IC electrode is connected, and a cover sheet bonded to the base covering the antenna and the IC chip with an adhesive.

However, the configuration of the RFID tag is merely an example, and the idea of the present invention is not limited by the type and structure of the RFID tag.

Hereinafter, an RFID tag validation apparatus and an RFID encoding system including the same will be described with reference to FIGS. 1 to 5, respectively, according to an embodiment of the present invention for encoding and verifying an RFID tag attached to the above- .

1 is a diagram illustrating an RFID encoding system including an RFID tag validation apparatus according to an embodiment of the present invention.

1, an RFID encoding system 1 according to an embodiment of the present invention includes a conveyor line 10 to which a product 20 to which an RFID tag 22 is attached is conveyed, And an encoder 12 for recording (encoding) the product information in the RFID tag 22 and a verification device 100 for verifying that the information encoded in the RFID tag 22 is correct.

The conveyor line 10 serves to feed the article 20 with the RFID tag 22 attached thereto while rotating at a constant speed using the rotational force of the motor. The conveyor line 10 is not limited to the type of the conveyor surface on which the article 20 to which the RFID tag 22 is attached or the box in which the article 20 is packed can be conveyed. For example, Conventional conveyors are also possible. In addition, the product 20 to be transferred may include a case for storing contents such as medicines, and an RFID tag 22 may be attached to the outer surface of the case.

The encoder 12 is an apparatus for recording information in the RFID. The encoder 12 may include a sensor for sensing the product 20 and an antenna for transmitting a signal to the RFID tag 22. In addition to the function of transmitting and encoding the product information to the RFID tag 22 attached to the product 20, it may also include a function of locking the information recorded in the RFID tag 22 so as not to be changed. In addition, the encoder 12 may be, for example, a device that performs bulk encoding. Bulk encoding refers to recording data in a bundle in a plurality of tags.

To briefly explain the operation principle of the encoder 12, the encoder 12 transmits an RF signal in a predetermined frequency band including a high frequency carrier signal and a predetermined question signal and an encoded signal to the RFID tag 22. When the RFID tag 22 is located in the electromagnetic field of the encoder 12 formed by the RF signal, the RFID tag 22 receives the operating power necessary for operating the IC chip from the high frequency carrier signal of the encoder 12. That is, the high frequency carrier signal transmitted from the encoder 12 generates an AC in the antenna of the tag, and the generated AC is used as electric energy for the IC chip after being rectified. When electric energy is transferred to the IC chip, information contained in the encoded signal transmitted from the encoder 12 is read and stored. The encoder 12 may also transmit a write lock signal together with the encoded signal so that the information encoded by the write lock signal after the product information is encoded on the IC chip is not overwritten or contaminated with other information Can be locked.

The acceptance device 100 confirms whether the encoded information is correct in the encoded RFID tag 22. The acceptance device 100 is supported by the connection part 110 and the connection part 110 and emits an RF signal, A monitor 130 for displaying the verification result and a reader 140 for receiving and decoding the encoded information received by the antenna unit 120. [

The connection unit 110 may connect the antenna unit 120 and the reader 140. For example, the connection unit 110 may include a bellows made of a metal material and capable of flexural deformation, . ≪ / RTI > The antenna unit 120 may be connected to both ends of the connection unit 110 and signal transmission lines may be provided inside the antenna unit 120 to transmit signals from the antenna unit 120 to the reader 140. The signal transmission line 128 may be connected to the antenna unit 120 and may extend through the connection part 110 and the support rod 104 and a part of the support 102 to be connected to the reader 140.

The antenna unit 120 continuously discharges the RF signal through the slit 125 and transmits the information recorded in the RFID tag 22 when the product 20 is positioned within the electromagnetic field formed by the RF signal of the antenna unit 120 Can be read. The specific configuration of the antenna unit 120 will be described with reference to Figs. 2 to 4. Fig.

FIG. 2 is a perspective view illustrating the antenna unit of FIG. 1, FIG. 3 is a cross-sectional view of the antenna unit taken along line A-A of FIG. 2, and FIG. 4 is a view illustrating an angle change of the antenna unit of FIG.

2 to 4, the antenna unit 120 may include a main body 122 and a signal transceiver 126 provided inside the main body 122, and the main body 122 may include a signal transceiver 126 A transmission and reception path 124 through which an RF signal is generated can be formed.

The operation of the antenna unit 120 will be briefly described. The antenna unit 120 transmits an RF signal having a predetermined frequency band including a high-frequency carrier signal and a predetermined interrogation signal to the RFID tag 22. When the RFID tag 22 is located in the electromagnetic field of the antenna unit 120 formed by the RF signal, the RFID tag 22 supplies the operation power necessary for operating the IC chip from the high frequency carrier signal of the antenna unit 120 Receive. That is, the high-frequency carrier signal transmitted from the antenna unit 120 generates AC in the antenna of the tag, and the generated AC is used as electric energy for the IC chip after being rectified. The RFID tag 22 modulates the received RF signal, and based on the information, reflects and modulates the information stored in the RFID tag 22 and transmits it as a response signal to the antenna unit 120. Thus, the encoding information of the RFID tag 22 can be transmitted to the antenna unit 120.

The signal transceiver 126 may be coupled to the reader 140 through a signal transfer line 128 and may be coupled to the reader 140 via an antenna such as an antenna for transmitting an RF signal and receiving a signal reflected from the RFID tag 22, Function.

The transmission / reception path 124 may be formed in such a shape that the cross-sectional area gradually decreases from the signal transceiver 126 to the slit 125. Due to the shape of the transmission and reception path 124, an RF signal passing through the slit 125 can cause diffraction in the slit 125 to propagate an RF signal to a wide area, and an electromagnetic field area E can be formed. When the RFID tag 22 enters the electromagnetic field area E due to the RF signal, the encoded information of the RFID tag 22 can be transmitted to the antenna unit 120 through the above-described process. As the electromagnetic field area E by the RF signal is widened, the encoded information recognition rate of the RFID tag 22 can be maintained at a high level even if the conveying speed of the conveyor line 10 is fast.

Since the connecting portion 110 can be flexibly deformed, the antenna portion 120 provided at both ends of the connecting portion 110 can be freely deformed in the position as shown in FIG. 4. For example, Deformation occurs between the first position 120a where the slits 125 of the unit 120 face each other and the second position 120b where the slit 125 faces downward than the first position 120a It is possible. The position of the RFID tag 22 can be detected by the position of the RFID tag 22 according to the size of the product 20 and the position of the RFID tag 22 attached to the product 20. Thus, The position of the portion 120 can be easily adjusted.

The monitor 130 may be provided to display the result of reading the encoded information recognized by the RFID tag 22 to the operator, and may receive the recognition result from the reader 140 and display the recognition result. It may also indicate whether the encoding information is correctly recorded or not.

The reader 140 receives the encoding information received from the antenna unit 120, decodes the encoded information, extracts the product information, and transmits the extracted product information to the controller 150. The control unit 150 compares the decoding information received from the reader 140 with the encoding information received from the encoder 12 to determine whether the two match. The specific configuration and operation of the control unit 150 will be described later.

The connection unit 110, the antenna unit 120, the monitor 130 and the reader 140 can be supported on the conveyor line 10 by the support member 102, A support rod 104 connecting the connection part 110 and sensors 142 and 144 for recognizing the product 20. [

The sensors 142 and 144 may be photo sensors having a light emitting portion and a light receiving portion, or a sensor in which a light emitting portion and a light receiving portion are integrally formed or a sensor in which a light emitting portion and a light receiving portion are separated. The sensors 142 and 144 can recognize the presence of the product 20 when the product 20 passes the sensing position of the sensors 142 and 144 and can detect the product 20 when it recognizes the product 20 150).

Hereinafter, a specific operation of the control unit 150 will be described with reference to FIG. 5 is a control hierarchy diagram of the RFID encoding system of FIG. 1, in which the controller 150 can be configured to send and receive signals with the reader 140, the encoder 12, and the sensors 142 and 144.

The control unit 150 may instruct the encoder 12 to perform encoding when the product 20 enters the encoder 12 and transmit the encoded product from the encoder 12 to the RFID tag 22 Information can be received. In addition, decoding information is received from the reader 140 and is compared with the encoding information to determine whether the encoding is correctly performed. In addition, recognition signals of the products 20 can be received from the sensors 142 and 144. [

The control unit 150 can continue the product 20 without stopping the conveyance of the conveyor line 10 when it is determined that the encoding is performed correctly. In addition, the reader 140 may display via the monitor 130 that the encoding is correct. If the controller 150 determines that the encoding has not been performed correctly, the conveyor line 10 may be stopped and an error message may be displayed on the monitor 130. Alternatively, the wrongly encoded product 20 can be released from the conveyor line 10 through a separator (not shown) provided on the conveyor line 10 without stopping the conveyor line 10.

When receiving the recognition signal from the sensors 142 and 144, the control unit 150 determines that the decoding information received from the reader 140 is the information read from the RFID tag 22 attached to the product 20, It can be judged whether or not it is done correctly.

If the reader 140 does not receive the recognition signal from the sensors 142 and 144 even though the reader 140 receives the signal from the antenna 120 and decodes the received signal, the RFID tag attached to the product 20 22, it can be judged that it is noise information. If it is determined that the decoded information is noise information, the reader 140 may skip the determination as to whether or not the encoding is correctly performed.

Thus, the noise information and the RFID encoding information coming in through the antenna unit 120 can be selected and judged by an external environment or the like, thereby reducing reading errors.

Hereinafter, specific effects and effects of the RFID tag validation apparatus and the RFID encoding system including the RFID tag validation apparatus of the present embodiment having the above-described configuration will be described.

The product 20 to which the RFID tag 22 is attached can be transferred to the encoder 12 by the conveyor line 10 and the encoder 12 recognizes the product 20 and transmits the encoded signal So that the RFID tag 22 can be encoded. At this time, the information to be encoded may include information on the ID of the product 20 and the property of the content of the product 20. [ In addition, the encoding operation can be performed while the product 20 is being continuously conveyed by the conveyor line 10. [

The encoded product 20 can pass between the two antenna units 120 of the acceptance apparatus 100. [ At this time, the RF signal may be continuously emitted from the antenna unit 120. When the product 20 enters the electromagnetic field area E generated by the RF signal emitted from the antenna unit 120, the product 20 The information encoded in the attached RFID tag 22 is transmitted to the antenna unit 120 as a reflected signal and a signal including the encoding information is transmitted to the reader 140 and decoded.

The product 20 that has passed through the electromagnetic field area E of the antenna unit 120 passes through the sensors 142 and 144 and the sensors 142 and 144 recognize the product 20 when the product 20 passes, (150).

The control unit 150 can receive the decoded information from the reader 140 and can receive the encoding information from the encoder 12 and the reader 20 when the recognition signal of the product 20 is received from the sensors 142 and 144. [ 140 and compare the analyzed decoding information with each other to determine whether the encoding is correctly performed. As a result of the determination, if the encoding is correctly performed, the monitor 130 can display this effect. If the encoding information and the decoding information do not match, it is determined that the encoding is not correctly performed. Can be displayed. In addition, the conveyor line 10 can be stopped to stop the conveyance of the misaligned product 20, or to release the misaligned product 20 from the conveyor line 10 through the not shown separator.

If the control unit 150 does not receive the recognition information of the product 20 from the sensors 142 and 144 despite receiving the decoding signal from the reader 140, the control unit 150 converts the signal received from the reader 140 into a noise signal And judge whether the encoding is correct or not.

According to this embodiment as described above, since the antenna 120 has a simple structure and the electromagnetic waves are diffracted by the slit 125 to form a wide electromagnetic field area E, It is possible to inspect without delay.

In addition, since the plurality of inspection apparatuses 100 can be installed along the conveyor line 10 as needed, there is an effect that the reliability of inspection work can be enhanced.

In addition, since the mounting position of the antenna unit 120 can be arbitrarily adjusted, it is possible to flexibly cope with the size of the product 20 and the mounting position of the RFID tag 22. [

Hereinafter, an RFID tag validation apparatus and an RFID encoding system including the RFID tag validation apparatus according to another embodiment of the present invention will be described with reference to FIG. 6 is a diagram illustrating an RFID encoding system including an RFID tag validation apparatus according to another embodiment of the present invention.

The present embodiment differs from the above embodiment in that the inspection apparatus 100 is provided so as to be movable relative to the conveyor line 10. Therefore, differences will be mainly described, I will take an example.

6, the inspection apparatus 100 includes a moving body 106 connected to a lower side of a support 102, a plurality of wheels 108 provided on a lower surface of the moving body 106 and two sensors 142 and 144, And a connecting rod 148 connecting the connecting rod 148 and the connecting rod 148 to each other.

The present embodiment is configured such that the moving body 106 can be moved by the wheels 108 and all the other components of the inspection apparatus 100 can move when the moving body 106 moves, There is an advantage that the inspection apparatus 100 can be arranged in a flexible manner.

Although the RFID tag validation apparatus and the RFID encoding system including the RFID tag validation apparatus according to the embodiment of the present invention have been described above as specific embodiments, the present invention is not limited thereto, and the present invention is not limited thereto. And should be interpreted as having the maximum range. Skilled artisans may implement a pattern of features that are not described in a combinatorial and / or permutational manner with the disclosed embodiments, but this is not to depart from the scope of the present invention. It will be apparent to those skilled in the art that various changes and modifications may be readily made without departing from the spirit and scope of the invention as defined by the appended claims.

1: RFID encoding system 10: conveyor line
12: Encoder 20: Product
22: RFID tag 100: inspection device
102: support 104: support rod
106: moving body 108: wheel
110: connection part 120: antenna part
122: main body 124: transmission / reception path
125: Slit 126: Signal transceiver
128: signal transfer line 130: monitor
140: Reader 142, 144: Sensor
148: connecting rod 150:

Claims (8)

An RFID tag inspection apparatus for verifying whether or not an RFID tag attached to a product is correctly encoded,
An antenna unit emitting an RF signal to receive information encoded in the RFID tag;
A reader for receiving and decoding the encoding information received by the antenna unit; And
And a connection unit for supporting the antenna unit and connecting the antenna unit and the reader,
An RF signal is continuously emitted from the antenna unit, an RF signal emitted through a slit formed in the antenna unit is diffracted to form an electromagnetic field region,
Wherein the connection part is made of a bellows capable of deforming the shape and the position of the antenna part can be changed by deforming the shape of the connection part. The method according to claim 1,
The antenna unit includes:
main body; And
And a signal transceiver provided in the main body and connected to the reader through a signal transfer line for receiving an RF signal and receiving a signal reflected from the RFID tag and transmitting the signal to the reader,
A transmission and reception path through which signals emitted and received by the signal transceiver pass is formed in the main body,
And the transmission / reception path communicates with the outside via the slit. 3. The method of claim 2,
Wherein the transmission / reception path has a shape in which the cross-sectional area becomes narrower toward the slit from the inside of the main body. delete The method according to claim 1,
And a sensor for recognizing the product that has passed through the antenna unit. The method according to claim 1,
And a monitor for displaying a result of inspection of the RFID tag. The method according to claim 1,
A moving body including a wheel so as to be movable downward; And
And a support for connecting the connection unit, the antenna unit, and the reader to the mobile body. A conveyor line through which a product with an RFID tag is transported;
An encoder provided on the conveyor line for encoding product information in the RFID tag; And
The RFID encoding system according to any one of claims 1 to 3, and the RFID tag validation device according to any one of claims 5 to 7, which checks whether or not the information encoded in the RFID tag is correct.

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