KR101195396B1 - Rfid tag writing system and method of classifying products using an rfid tag writing system - Google Patents

Abstract

An RFID tag recording system is provided. The RFID tag recording system includes a transfer unit for transferring a product including an RFID tag, an encoder unit for converting the product information into a digital code, generating a plurality of RFID tag values and transmitting the same to a reading unit, and recording the RFID tag value in the RFID tag. And a reading unit which reads the RFID tag value recorded in the RFID tag and compares the RFID tag value received from the reading unit with the read RFID tag value. It is possible to check whether the correct information is input to the RFID tag at high speed.

Description

Product classification method using RDF tag recording system and RDF tag recording system {RFID TAG WRITING SYSTEM AND METHOD OF CLASSIFYING PRODUCTS USING AN RFID TAG WRITING SYSTEM}

The present invention relates to an RFID tag recording system and a product classification method using an RFID tag recording system. More particularly, the present invention relates to an RFID tag recording system and an RFID tag recording system that perform both RFID tag recording and RFID tag reading. It is about.

RFID (Radio Frequency Identification) refers to a system that recognizes or identifies an item by attaching an electronic device using a change in radio frequency or magnetic field to an item. For example, in an RFID system, a tag, which is an identification device, is attached to an item, and the item is recognized or identified using a reader that recognizes the RFID tag and reads information stored in the RFID tag. If the correct information is not entered in the RIFD tag or the RFID tag in which the information is input is not attached to the corresponding item, the manager or the consumer cannot recognize or identify the correct information about the item. Therefore, a process of inputting accurate information about an item into an RFID tag, attaching the RFID tag inputted with the information to the corresponding correct item, and checking whether the RFID with the correct information inputted is correctly attached to the corresponding item. .

An object of the present invention is to provide a system for checking whether correct information is input to an RIFD tag. In addition, another object of the present invention is to provide a method for confirming whether correct information is input to an RIFD tag.

An RFID tag recording system is provided. The RFID tag recording system includes a transfer unit for transferring a product including an RFID tag, an encoder unit for converting the product information into a digital code, generating a plurality of RFID tag values and transmitting the same to a reading unit, and recording the RFID tag value in the RFID tag. And a reading unit which reads the RFID tag value recorded in the RFID tag and compares the RFID tag value received from the reading unit with the read RFID tag value.

In one embodiment of the present invention, according to the RFID tag value compared in the reading unit, may further include an ejector for leaving the product.

In one embodiment of the present invention, the encoder may further include a database center for transmitting the product information.

In an embodiment of the present invention, the recording of the RFID tag value in the RFID tag and the reading of the RFID tag value recorded in the RFID tag may be performed together.

A product classification method is provided. Convert product information to RFID tag values. The converted RFID tag value is transmitted to a reading unit, and the RFID tag value is recorded in a tag included in a product. The RFID tag value recorded in the tag is read by the reading unit. The product is classified by comparing the read RFID tag value with the received RFID tag value.

In one embodiment of the present invention, the product information is transmitted from the edge program or the control program to the encoder unit, the step of converting the product information to the RFID tag value may be performed in the encoder unit. The converted RFID tag value includes information about a product and a serial number, and the converting of the product information into an RFID tag value generates a plurality of RFID tag values that maintain information about the product and increase serial numbers. It may include a step. The classifying the product by comparing the read RFID tag value with the received RFID tag value may include comparing a serial number of the read RFID tag value with a serial number of the received RFID tag value.

A product classification method is provided. The product classification method includes the steps of: (a) generating a first number of RFID tag values including a same RFID data structure and a serial number which is incremented by a predetermined unit for the same product; and (b) generating the first number of RFID tag values. (C) recording the first number of RFID tag values in each RFID tag, and recognizing the RFID tag value recorded in the RFID tag while the recording is performed; d) determining whether a serial number of the RFID tag value recognized by the reader exists between the minimum serial number and the maximum serial number of the tag values of the first number of RFIDs transmitted by the reader.

In an embodiment of the present disclosure, the method may further include verifying whether the RFID tag value includes RFID configuration data after recognizing the RFID tag value.

In one embodiment of the present invention, the recording of each of the first number of RFID tag values in each of the RFID tags includes the step of sequentially recording in the order of the size of the serial number, and recognizing in the reading unit. If the difference between the serial number of one RFID tag value and the maximum serial number of the first number of tag values is smaller than the second value specified by the user, steps (a), (b), (c) and (d) are repeated. It may further comprise the step.

In one embodiment of the present invention, the method may further include determining whether the RFID tag value recorded in the RFID tag and the RFID tag value transmitted to the reading unit are matched.

According to the RFID tag recording apparatus and the control method according to the embodiment of the present invention as described above, since the product failed to record the information of the RFID tag can be filtered immediately after the information recording, there is an advantage that it is possible to quickly extract a defective tag in real time have.

In addition, since the recording of the information on the RFID tag and the inspection of the recorded information are continuously performed, there is an effect that the productivity of the product can be improved by shortening the process.

In addition, since the RFID tag information recording and the inspection of the recorded information can be reliably performed, there is an advantage that the success rate of the RFID tag information recording can be improved.

1 is a perspective view showing the appearance of an RFID tag information input apparatus according to an embodiment of the present invention.
FIG. 2 is a perspective view illustrating an information recording unit and its periphery of the RFID tag information input device shown in FIG. 1.
3 and 4 are exemplary diagrams for recording information on an RFID tag and inspecting the recorded information by using the RFID tag information input device according to an embodiment of the present invention.
5 is a flowchart illustrating a method of operating an RFID tag information input device according to an embodiment of the present invention.
6 is a flowchart illustrating a control method of an encoder unit of an RFID tag information input apparatus according to an embodiment of the present invention.
7 is a flowchart illustrating a control method of a reading unit of an RFID tag information input apparatus according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the accompanying drawings. In the following description, when a part is said to "include" a certain component, it means that it may further include other components, except to exclude other components unless specifically stated otherwise. In addition, the terms “… unit”, “… unit”, “module”, “block”, and the like described in the specification are units for processing at least one function or operation, and may be a unit implemented by hardware, software, or a combination thereof. it means. They do not need to be implemented as a single component but may be implemented by a combination of two or more components. In addition, they do not need to be separate components, for example, but it is also possible for one component to perform the functions of two or more modules.

1 is a perspective view showing the appearance of an RFID tag information input apparatus according to an embodiment of the present invention. FIG. 2 is a perspective view illustrating an information recording unit and its periphery of the RFID tag information input device shown in FIG. 1.

1 and 2, the RFID tag recording apparatus 10 according to an exemplary embodiment of the present invention includes a frame 110 and a transfer unit 120 for transferring a product 20 including an RFID tag 21 and a frame ( The cabinet 150 is formed on one side of the 110, the information provided in one side of the transfer unit 120, the information recording unit 200, RFID tag 21 is formed so as to pass through the product 20, the success or failure of the information recording Operation conditions of the ejector (ejector, 160) to selectively remove the product 20 from the conveying unit 120, the collection box 170 for collecting the product separated by the ejector 160, and the RFID tag recording apparatus 10 The displayed display unit 130 may be included.

The RFID tag 21 included in the product 20 may be provided inside / outside the package of the product 20. For example, product 20 may be any object that includes RFID tag 21 at any location. In this embodiment, the RFID tag 21 will be described as an example attached to the outside of the product 20.

The frame 110 forms the skeleton of the RFID tag recording device 10 and supports the respective components. The transfer unit 120 may be provided on the upper side of the frame 110 to transfer the product 20. For example, the transfer unit 120 transfers the product 20 to the information recording unit 200. The transfer unit 120 may include various types of conveyors. For example, the transfer unit 120 may include a belt conveyor. When the belt conveyor is provided to the transfer unit 120, since vibration during transportation of the product 20 can be minimized, information recording and reading to the RFID tag 21 can be stably performed.

In one embodiment of the present invention, the transfer unit 120 is described with an example including a belt conveyor, the spirit of the present invention is not limited thereto. The transfer unit 120 may include various transfer means such as a roller conveyor and a bellows conveyor.

The information recording unit 200 may be formed to extend in the conveying direction of the product 20, and may cover a portion of the upper space of the conveying unit 120 for conveying the product 20. When the information recording unit 200 has a structure covering a portion of the upper space of the transfer unit, the encoder unit 410 and the reading unit 420 may be disposed above the information recording unit 200.

While the product 20 passes through the information recording unit 200, an encoder unit 410, which will be described later, encodes the product information and records the information on the RFID tag 21, and the reading unit 420 reads the RFID tag 21. Check that the correct information has been entered. Specific details related to this will be described later.

The product that has passed through the information recording unit 200 may be continuously transported by the transfer unit 120 or discharged to the collection unit 170 by the ejector 160 according to whether the correct information is input to the RFID tag 21. .

In one embodiment of the present invention, the ejector 160 and the collection box 170 is connected to the information recording unit 200. The ejector 160 and the collection box 170 may be disposed to face each other.

The display unit 130 may display at least one of a process in which the product 20 passes through the information recording unit 200, a process in which information is recorded and inspected on the RFID tag 21, and whether the information recording is successful. The overall operation of the RFID tag recording apparatus 10 may be displayed for the user to check.

Referring to FIG. 2, the product 20 is transferred from one side (left side in FIG. 2) of the transfer unit 120 toward the other side (right side in FIG. 2) of the transfer unit 120, and moves the information recording unit 200 during transfer. To pass.

The information recording unit 200 includes a shielding shell 210 for blocking radio waves, a door 220 for selectively opening and closing the entrance of the shielding shell 210, a door driving device 230 for driving the door 220, and an RFID tag. An encoder unit 410 for recording information at 21 and a reader unit 420 for recognizing information recorded at the RFID tag 21 may be included.

The shielding shell 210 may prevent interference by external radio waves when the encoder unit 410 and the reading unit 420 are operated, and may block radio waves generated inside the shielding shell 210. The shielding cell 210 may be formed of a conductive material such as aluminum.

The shielding shell 210 is formed long along the conveying direction of the product 20. For example, the shielding cell may be tunnel shaped. The shielding shell 210 includes openings at both sides thereof to allow the product 20 to pass therethrough. In this case, an opening through which the product 20 is introduced into the shielding shell 210 may be referred to as an inlet, and an opening through which the product 20 is drawn out of the shielding shell 210 may be referred to as an outlet.

The inlet of the shielding shell 210 is selectively opened and closed by the door 220. Specifically, the door 220 is movably mounted to the shielding shell 210 and selectively opens the inlet of the shielding shell 210 according to a signal of the controller (not shown). For example, a solenoid driving device 230 is provided at one side of the door 220, and the driving device 230 moves the door 220 in the vertical direction to open and close the inlet of the shielding shell 210. Can be.

Alternatively, the door 220 may be provided to be rotated by the movement of the product 20. For example, a predetermined elastic member is placed on one side of the door 220 such that the door 220 is opened by the product 20 pushing the door 220 and returned to the closed state when the product 20 passes. Can be provided. In this case, it is preferable that the elastic force of the elastic member is smaller than the friction force between the product 20 and the transfer part 120.

In addition, the door 220 may be formed of a conductive material to block radio waves with the shielding shell 210.

In the present exemplary embodiment, the door 220 is described as being provided only at the inlet of the shielding shell 210, but the door for selectively opening and closing the outlet may be further provided at the outlet of the shielding shell 210. The door may also be formed of a conductive material to block radio waves.

The encoder unit 410 and the reading unit 420 may be provided inside the shielding shell 210, for example, may be provided on an upper surface of the shielding shell 210.

The encoder unit 410 wirelessly records information in the RFID tag 21. For example, information related to the product 20 may be recorded in the RFID tag 21 by designating a tag address and a storage address. Accordingly, the encoder unit 410 may be referred to as a recording unit. In more detail, the encoder unit 410 receives information about a product, encodes it, and records the encoded data in the RFID tag 21. The encoder unit 410 may include an antenna, a control controller, and a network interface as physical components.

Although the encoder unit 410 is included as one component in the drawing, the encoder unit 410 may include an encoding module for performing encoding and a recording module for performing data recording, which are different from external components. Can have a relationship. For example, the encoding module may be connected with the reading unit to transmit encoded data to the reading unit, while the recording module may not be connected with the reading unit. Even in such a case, it should be noted that in the present specification, the encoder unit 410 transmits data to the reading unit 420.

The reader 420 recognizes the RFID tag 21 and is also called a reader. The reading unit 420 may be attached to the upper inner surface of the shielding shell 210 as shown in FIG. 2, but in other embodiments may be provided inside the conveying unit 120, eg, at the lower end of the conveyor belt. It may be. In addition, a plurality of reading units 420 may be provided to increase reading accuracy.

The reader 420 may include an antenna, a control controller, and a network interface as physical components. The antenna receives tag information. The control controller controls the function of the reading unit and processes the information read from the tag. The network interface communicates with the network and other devices.

 The encoder unit 410 may be disposed to be spaced apart from the reading unit 420 by a predetermined distance, and communicate with the RFID tag 21 before the reading unit 420. Therefore, the encoder section 410 records the information in the RFID tag 21, and the reading section 420 performs the inspection of the recorded information.

The ejector 160 is provided at the rear of the shielding shell 210 and separates the product 20 from the transfer part 120. The ejector 160 separates the product 20 from the transfer unit 120 according to the test result of the reading unit 420. For example, the ejector 160 may include a pusher 162 for pushing the product 20 and a pusher driving device 161 for driving the pusher 162. The pusher drive device 161 may be a piston-cylinder device for linearly moving the pusher 162 to cross the conveying direction of the product 20.

For example, the ejector 160 may be operated by pushing the product 20 to the collection box 170, or may move the product 20 to the collection box 170 by hitting the product 20.

The configuration of the ejector 160 as described above is merely an example, and various types of ejector 160 may be used within the scope of the spirit of the present invention. For example, an air type ejector for pushing the product 20 with strong air pressure and an arm type ejector for rotating the bar to strike the product 20 may be used. Alternatively, provided with a plate that connects the storage box of the product 20 separately from the transfer unit 120, a tilting ejector may be used to collect the product by tilting the plate for information recording failed.

The collection box 170 may be provided at a position facing the ejector 160 so that the product 20 pushed by the pusher 162 may fall. The collection box 170 may be detachably mounted to the transfer unit 120 to conveniently collect the products sorted by the ejector 160.

Meanwhile, a first sensor 310 may be provided at the front of the inlet of the shielding shell 210 to inspect whether the product 20 enters the transfer part 120. For example, the first sensor 310 may be operated in a light sensitive manner, and may include a light emitter 311 and a light receiver 312 for this purpose.

In detail, the light emitter 311 and the light receiver 312 are disposed to face each other, and the light emitted from the light emitter 311 reaches the light receiver 312. When the light does not reach the light receiving unit 312, it may be determined that the product 20 passes between the light emitting unit 311 and the light receiving unit 312, thereby detecting the product 20. However, the first sensor 310 as described above is just an example, and various sensing devices such as an infrared sensor and a photo sensor may be used.

The first sensor 310 is shielded so that the door 220 can open the inlet of the shielding shell 210 while the product 20 moves from the first sensor 310 to the inlet of the shielding shell 210. It is preferable to be spaced a predetermined distance from the inlet of the shell 210. For example, when the first sensor 310 detects the product, the inlet of the shielding shell 210 may be opened. The first sensor 310 determines whether the product 20 enters the transfer part 120 and may be referred to as an entry sensor.

In addition, a second sensor 320 may be disposed between the inlet of the shielding shell 310 and the encoder unit 410 to detect the product 20. Similar to the first sensor 310, the second sensor 320 may include a light emitting part 321 and a light receiving part 322, and the light emitting part 321 and the light receiving part 322 are inner walls of the shielding shell 310. Can be arranged to face each other. The driving of the encoder 410 may be controlled according to the detection result of the second sensor 320. For example, when the second sensor 320 detects the product 20, the encoder unit 410 starts recording information on the RFID tag 21. The information recorded in the RFID tag 21 may be information of the product 20 previously stored in the controller of the encoder unit.

In addition, a third sensor 330 may be disposed between the encoder 410 and the reader 420 to detect the product 20. Similar to the first sensor 310, the third sensor 330 may include a light emitting part 331 and a light receiving part 332, and the light emitting part 331 and the light receiving part 332 are inner walls of the shielding shell 210. Can be arranged to face each other. The driving of the encoder 410 and / or the reader 420 may be controlled according to the detection result of the third sensor 340. For example, when the third sensor 340 detects a product, control may be performed such that the recording operation by the encoder unit 410 is stopped and / or the reading operation by the reading unit 420 is started.

In addition, a fourth sensor 340 may be disposed between the encoder 410 and the ejector 160 to detect the product 20. Like the first sensor 310, the fourth sensor 340 may include a light emitting part 341 and a light receiving part 342, and the light emitting part 341 and the light receiving part 342 are inner walls of the shielding shell 310. The fourth sensor 340 may control the operation of the reading unit 420 and / or the exit door. That is, the reading operation of the reading unit 420 may be stopped according to the detection of the product of the fourth sensor 340, and the exit door may be opened.

Hereinafter, a process of recording information on the RFID tag 21 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following embodiment, a process of recording and reading information for products of the same kind will be described, but the present invention is not limited thereto, and the present invention can be applied even when different kinds of products are transported.

3 and 4 are exemplary diagrams for recording information on an RFID tag and inspecting the recorded information by using the RFID tag information input device according to an embodiment of the present invention.

3 and 4, a plurality of products 20a, 20b and 20c are continuously brought into the shielding cell 210. Alternatively, even if the product 20 is continuously introduced into the transfer part 120, the transfer speed and / or shielding of the transfer part 120 such that only one product exists inside the shielding shell 210 to improve the information recording success rate. The length of the shell 210 can be set.

When a plurality of products 20a, 20b, 20c are continuously brought into the shielding cell 210, the plurality of products 20a, 20b, 20c are each conveyed by a conveying unit and attached to the respective products. The fields 21a, 21b, 21c sequentially communicate with the encoder unit 410 and the reading unit 420. In other words, while the product to which the tags 21a, 21b, and 21c are attached is transported, the encoder unit 410 sequentially processes the first tag 21a, the second tag 21b, and the third tag 21c. The product information is recorded, and the reading unit 420 sequentially reads the information of the product recorded in the first tag 21a, the second tag 21b, and the third tag 21c. At this time, as shown in FIG. 4, the reading unit 420 reads the information recorded in the first tag 21a and the encoder unit 410 writes the information in the second tag 21b at the same time. Can be performed. In this case, it is preferable that the antennas installed in the encoder unit 410 and the reading unit 420 do not overlap the coverage with each other, thereby avoiding simultaneous writing and reading to the same tag. Alternatively, the reading of the information recorded in the first tag 21a and recording the information in the second tag 21b may be performed with a slight time difference. In this case, the coverages of the antennas of the encoder section 410 and the reading section 420 need not be determined differently. The method of recording information in the tags 21a, 21b, 21c and reading the recorded information will be described later.

5 is a flowchart illustrating a method of operating an RFID tag recording apparatus according to an embodiment of the present invention. The readout unit 420 may include an antenna, a control controller, and a network interface as physical components, and may include a reader application programming interface (API), communication, event management, and antenna subsystems as logical components. Can be. Each component reads a tag value, stores or analyzes information, and performs event filtering. Referring to FIG. 5, the RFID tag recording apparatus converts the product information into a code (RFID tag value) that can be read by a machine (for example, a reader or a reader) to generate a plurality of RFID tag values (S510). ). The plurality of RFID tag values may be RFID tag values having the same data configuration for the same plurality of products and increasing serial numbers. For example, if there are 100 products of the same type, they will have the same product information but have serial numbers 1, 2, 3…. 100 RFID tag values assigned differently to 100 are generated. The plurality of RFID tag values are transmitted to the reading unit 420 that reads information on the RFID tag (step S520). For example, the plurality of RFID tag values may be generated by the encoder unit 410. In this case, the encoder unit 410 generates the plurality of RFID tag values and then transmits the plurality of RFID tag values to the reading unit. Alternatively, the encoder 410 and the reader 420 may simultaneously receive the plurality of RFID tag values from a database center (eg, an edge program or a control program). Accordingly, the reading unit 420 stores a plurality of RFID tag values having different serial numbers and having the same data configuration. The encoder unit 410 sequentially inputs the plurality of RFID tag values one by one to the product tag, and simultaneously or successively, the reading unit 420 sequentially reads the RFID tag values input to the product tag one by one. For example, if there are 100 products, the serial numbers are 1, 2,…. The RFID tag value of 100 is sequentially input to the tags attached to each product, and the reading unit 420 reads the RFID tag value. The reading unit 420 compares or analyzes the read RFID tag value and the RFID tag value received and stored in operation S520 to determine whether correct information is input to the tag. For example, only the serial number is extracted from the RFID tag value input by the encoder unit 410, and the serial number is compared with the serial number of the RFID tag value received and stored in step S520. Alternatively, the entire RFID tag value may be compared.

Hereinafter, operations of the encoder unit 410 and the reading unit 420 according to the exemplary embodiment will be described with reference to the drawings.

6 is a flowchart illustrating an encoding and recording method of an encoder unit of an RFID tag information input apparatus according to an embodiment of the present invention.

Referring to FIG. 6, the encoder unit 410 encodes information about a product, which has been received in advance, by converting the information into a digital code, transmits the information to the reading unit 420, and records the converted code in the RFID tag. At this time, the encoder unit 410 may receive information about the product in advance before encoding and writing of the encoder unit 410. Alternatively, the encoder unit 410 receives necessary information from components of an RFID system such as a data center, a database (for example, an edge program or a control program), middleware, firmware, and then encodes and records the data. It can also be done.

The encoder unit 410 configures the information about the stored or received product as RFID data to be encoded including a serial number (step S610). For example, the encoded RFID data to be entered into one tag includes a header, a filter, a partition, a product number, a manufacturing number, and a serial number. The configuration of the above RFID data is exemplary and can be arbitrarily changed by the user.

The encoder unit 410 sequentially increases the serial number from the first reference value and generates a first number of RFID tag values having the same RFID data configuration except for the serial number (step S620). That is, the first number of RFID tag values having the same RFID data configuration for one piece of information of the same product and whose serial number increases from the first reference value by a predetermined unit are generated. For example, when the first reference value is 1, the predetermined unit is 1, and the first number is 100, 100 RFID tag values having the same data RFID configuration and serial numbers 1 to 100 are generated. The first reference value, the increment unit, and the first number are exemplary and may be arbitrarily changed by the user.

Steps S610 and S620 include converting information about the product into codes that can be read and written by a machine (for example, a reader or a reading unit).

The encoder 610 transmits the generated first number of RFID tag values to the reading unit 420 (step S630). Accordingly, the reader 420 may have the first number of RFID tag values in the controller prior to reading the RFID tag values.

The encoder 410 records the generated RFID tag value in the tag attached to the transferred product (step S640). One RFID tag value is recorded in one tag.

It is determined whether to terminate the operation of the encoder unit 410 to determine the next step (S650). When the operation of the encoder unit 410 ends, the last serial number of the RFID tag value recorded in the tag is stored (step S670). After storing the last serial number, the operation of the encoder unit is terminated. On the basis of the stored serial number, it is possible to operate the continuous encoder part when starting work.

If the operation of the encoder unit 410 is not terminated, the difference between the serial number of the recorded tag value and the first number is calculated (S660). When the difference between the serial number of the recorded tag value and the first number is compared with the second value determined by the user, the RFID tag value is continuously recorded in the product tag when the difference is greater than or equal to the second value. That is, only the serial number is increased and RFID tag values having the same RFID data configuration are sequentially recorded in the tags. For example, an RFID tag value having the same RFID data configuration by increasing the serial number from 1 to 1 may be sequentially recorded one by one on n products. If the difference between the serial number of the recorded tag value and the first number is compared with the second value determined by the user, step S620 is performed again when the difference is smaller than the second value. That is, a new RFID tag value having an increased serial number and having the same RFID data configuration is generated again by a number determined by a user, transmitted to the reading unit 420, and the RFID tag value is recorded in the tag of the product. In this case, the serial number may be generated after the first number of serial numbers. For example, when the first number is 100, the serial number of the newly generated RFID tag value may start at 101.

For example, the steps S650 and S660 will be described. When the first number is 100, the second value is 30, and the serial number is increased by one, the encoder unit has 70 serial numbers of 1, 2, 3... Each RFID tag value that is 70 and has the same RFID data configuration is successively recorded. When the serial number is 71, since the difference between the first number and the serial number is 29 and the second value is 30, the difference between the serial number of the recorded RFID tag value and the first number is smaller than the second value. The number is increased and a new RFID tag value having the same RFID data configuration is generated again by the number determined by the user. For example, when the first number is 100, the serial numbers of newly generated RFID tag values are 101, 102,... May be 200. The first number and the second value are exemplary and may be arbitrarily changed by the user.

In addition, when the product to be recorded by the encoder unit includes two or more different kinds of products, the encoder unit may further generate a product code in addition to the above-described serial number and include it in the RFID tag value to be recorded. By simultaneously considering the serial number and the product code described above, the above-described process can be performed in the same manner even when two or more kinds of products are mixed.

7 is a flowchart illustrating a control method of a reading unit of an RFID tag information input apparatus according to an embodiment of the present invention. The readout unit 420 may include an antenna, a control controller, and a network interface as physical components, and may include a reader application programming interface (API), communication, event management, and antenna subsystems as logical components. Can be. Each component reads a tag value, stores or analyzes information, and performs event filtering.

The reading unit 420 reads the RFID tag value recorded in the RFID tag by communicating with the RFID tag attached to the product (S710).

The RFID tag value read by the reading unit 420 is analyzed to check the RFID data configuration (step S720). If the RFID data configuration does not match the data configuration defined by the user, the RFID tag is attached to the product detached (step 725). For example, the RFID data configuration may be an RFID data configuration performed in step S610 of FIG. 6.

If the RFID data configuration matches the data configuration defined by the user, a serial number is extracted from the RFID tag value (step S730). Various information is recorded in the RFID tag value, of which only the serial number is extracted.

The extracted serial number is compared with the serial number of the RFID tag value received from the encoder 410 (step S740). If the extracted serial number is between the minimum value and the maximum value of the serial number of the RFID tag value received from the encoder unit 410, the process proceeds to the next step. If the extracted serial number is not between the minimum value and the maximum value of the serial number of the RFID tag value received from the encoder unit 410, the product is separated. For example, in step S630 of FIG. 6, when 100 RFID tag values having serial numbers from 1 to 100 are received from the encoder unit, if the serial number extracted in step S730 is 60, the next step for duplicate check Proceed to However, if the serial number extracted in step S 730 is greater than 100, the product is released. For example, in step S630 of FIG. 6, if 100 RFID tag values having serial numbers 101 to 200 are received from the encoder unit, the serial number extracted in step S730 is 60 or 210, However, if the serial number extracted in step S730 is greater than 100 and less than 200, a duplicate check is performed.

The RFID tag value having the extracted serial number is compared with the RFID tag value accumulated and stored in the reading unit 410, and it is determined whether or not it overlaps (step S750). The number of accumulated RFID tag values may be arbitrarily determined by a user. For example, 1000 RFID tag values, that is, RFID tag values having a data structure of the same product having serial numbers of 1 to 1000, are stored in the reading unit 420, and the RFID tag values read by the reading unit and the 1000 RFID tag values are read. If the tag value is compared and the same, the product is separated and if it is not the same, data is transmitted (step S760).

When the encoder section 410 finishes recording, the reading section 420 reads the last RFID tag value recorded by the encoder section and ends the system.

The reader 420 repeats the above process to check the information of the tag and classify the product.

Meanwhile, the reader 420 may additionally read a product code in addition to the serial number and compare it with the stored information, thereby performing the same operation even when various kinds of products are mixed.

According to the present invention, since the product which failed to record the information to the RFID tag 21 can be filtered immediately after the information recording in one process, the defective rate of the product shipped can be reduced.

In addition, since the recording of the information on the RFID tag 21 and the inspection of the recorded information are performed by different encoder units and reading units, it is possible to check whether the correct information is input to the tag at high speed, thereby improving production efficiency. Can be.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

110 frame 120 transfer unit
130: display 160: ejector
170: collection box 210: shielding shell
220: door 410: encoder
420: reading unit 310, 320, 330, 340: sensor

Claims (13)

A transfer unit for transferring a product including an RFID tag;
An encoder unit for recording the RFID tag value generated based on the information on the product, to the RFID tag; And
A reading unit for reading an RFID tag value recorded in the RFID tag and analyzing a pre-stored RFID tag value and the read RFID tag value;
The encoder unit generates the RFID tag value and transmits it to the reading unit,
And the pre-stored RFID tag value is an RFID tag value transmitted from the encoder unit. The method of claim 1,
And an ejector for leaving the product according to the analysis result performed in the reading unit. delete The method of claim 1,
And recording the RFID tag value in the RFID tag and reading the RFID tag value recorded in the RFID tag. Generating, by the encoder, a plurality of RFID tag values including information about a product and a serial number, the serial number of which is increased;
Transmitting the RFID tag value generated by the encoder unit to a reading unit;
Recording the RFID tag value generated in the encoder unit in a tag included in a product;
Reading an RFID tag value recorded in the tag;
And classifying products by comparing the read RFID tag value with the received RFID tag value.
How to classify your product. delete delete The method of claim 5, wherein
The classifying the product by comparing the read RFID tag value with the received RFID tag value includes comparing a serial number of the read RFID tag value with a serial number of the received RFID tag value. Way. (a) generating a first number of RFID tag values including a same product information and a serial number increasing in a predetermined unit, for a plurality of identical products;
(b) transmitting the first number of RFID tag values to a reading unit;
(c) respectively recording the first number of RFID tag values in each RFID tag included in the product;
(d) recognizing, by the reading unit, an RFID tag value recorded on the RFID tag; And
(e) determining whether a serial number of the RFID tag value recognized by the reading unit exists between the minimum serial number and the maximum serial number of the tag numbers of the first number of RFID received by the reading unit. Way. The method of claim 9,
Recognizing the RFID tag value, and then verifying whether the RFID tag value includes the product information. The method of claim 9,
Recording each of the first number of RFID tag values into each RFID tag comprises sequentially recording the serial number in order of size;
(A), (b), (c), (d) when the difference between the serial number of the RFID tag value recognized by the reading unit and the maximum serial number of the first number of tag values is smaller than the second value designated by the user And repeating steps (e) and (e). The method of claim 9,
And determining whether the RFID tag value recorded in the RFID tag is identical to the RFID tag value transmitted to the reading unit. The method of claim 9,
And (c) and (d) are performed to overlap.

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