KR20130135434A - Multi nfc label tag packet automatic inspection system and the method thereof - Google Patents

Abstract

Disclosed are an automatic packet inspection and cutting system of a multi NFC label tag and an automatic packet inspection and cutting method thereof. According to the present invention, the method and the system are constituted so that a near field communication (NFC) inlay is attached to a label and is recorded with information in one process and a roll type label recorded with information of different modes is separated and transported at the same time, and a label of a faulty mode is cut and discarded through inspection, and only normal labels are gathered and packaged. Thus, the system and the method of the present invention improve packaging speed as enabling mass production of labels due to a faulty tag. [Reference numerals] (112) Fabric material feeding part;(114) Separation part;(120) Attachment part;(130) Bonding processing part;(142) Inlay feeding part;(146) Inlay discrimination part;(148) Inlay cutting part;(150) Synthesizing part;(160) Processing part;(210) Sensor recognition part;(220) Writing part;(230) Completion display part;(240) NFC label output part;(300) Control part;(310) Release part;(320) Label transfer part;(330) Packet inspection part;(342) Faulty label transfer cutting part;(344) Packet label transfer cutting part;(350) Gathering/packaging part

Description

MULTI NFC LABEL TAG PACKET AUTOMATIC INSPECTION SYSTEM AND THE METHOD THEREOF}

The present invention relates to a device for inspecting and tearing multiple NFC (Near Field Communication) labels, and in particular, to process a function of inspecting and tearing encoded multiple NFC labels in one process, and thus, a defective label. A method and system for automatic packet inspection and tearing of multiple short range wireless communication labels that can easily remove and improve NFC label tearing and packaging speed.

In general, products stored in these containers, such as boxes, boxes, and wrapping paper, are identified by labels outside the container.

The identification information can also be printed directly on the container using ink jet or any other suitable printing technique. The label may include optically readable information, such as a UPC barcode. Such a label allows an optical reader using the laser beam to scan the information contained in the label, such as description, price, packaged date, or any other useful data. One disadvantage of optically readable labels is that the optical reader and the label must be in a specific spatial relationship with each other. That is, the line of sight is tomorrow, or perpendicular to the scanning direction, or within a limited range for the optical reader.

More recent types of labels store information using RFID, i.e. Radio Frequency Identification (RFID) tags. RFID uses radio frequency signals to obtain data from RFID tags within the area of the RFID reader. RFID transponders or tags, whether active or passive, are commonly used with RFID readers that read information from RFID tags embedded in the label.

RFID tags and labels can be obtained from ordinary suppliers. For a passive tag, a typical RFID reader / writer supplies energy to the transponder circuit in the tag by transmitting a power signal.

The power signal may carry data, the data may be stored in a transponder memory, and the transponder circuit may transmit a response signal that includes data previously stored in memory. When the transponder circuit transmits a response signal, the RFID reader / writer receives the response signal and interprets the stored data. The data is then transferred to the host computer for processing.

In this way, the wireless identification technology recognizes the information of the object and the surrounding environment from the tag attached to the object, and collects, stores, processes, and tracks the information of each object so that the positioning, remote processing, Information exchange and so on.

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.

In the conventional tag writing or encoding process, a tag is printed using a tag printer and then an operator attaches the tag to the article, or a tag printed on the tag printer is tagged with an automatic tag attaching device .

That is, the conventional wireless identification tag writing method is composed of a process of issuing a tag using a label or a tag printer and attaching the issued tag to an article or an automation equipment by an operator.

These RFID Labels are not only at the level of converting imported Inlay semi-finished products from abroad, but also separate from the encoding process of storing data in tags, which makes it difficult to produce labels quickly.

In addition, in order to encode an inlay-labeled label, it takes 20 to 40 seconds per unit in a separate device, so there is a problem that it takes a lot of time to mass produce.

On the other hand, labels may be supplied in packets (multiple labels) to increase production speed, and then different information may be written on each label.

In the case of producing, inspecting and packaging different information on these continuously supplied labels, if a problem occurs in any one of the supply labels, the process is stopped, the bad labels are sorted, cut off, and the multiple labels are supplied again. Since the process of re-inspecting and cutting again is repeated, a problem occurs in the production speed, and there is a problem in that the personnel have to be input due to the manual processing of the defective label.

An object of the present invention to solve this problem is to provide a system and method for automatic packet inspection and tearing multiple short-range wireless communication label that is automatically inspected and cut so that the short-range wireless communication label can be manufactured and packaged quickly. .

In addition, the present invention provides a short-range wireless communication label tag packet inspection system and method capable of automatically inspecting and truncating encoded multi-mode data while processing converting and encoding in one process during NFC label production. To provide for other purposes.

In addition, the present invention provides a system and method for automatic packet inspection and cutting of multiple short-range wireless communication labels capable of cutting only a corresponding defective label and continuously performing a multi-label inspection and cutting process when an error occurs in a multi-label inspection and cutting process. Another purpose is to provide.

In one process of the present invention to achieve this object, each field is attached to a near field communication (NFC) inlay on multiple labels, and each of the roll-type multiple labels on which different modes of information are written is inspected. The multi-range wireless communication label automatic packet inspection and tearing system provided to cut and pack separates and transfers the labels of each mode by one tag from the multiple labels provided in the roll type, and simultaneously transfers the transferred multi-mode tags. It can be achieved by including a control unit which controls to transfer multiple labels to each other and to cut at the same time only when it is determined to be normal by inspection.

When the control unit inspects the tag of the transferred multi-mode, if there is a label of a mode determined to be defective, the controller controls only the label of the defective mode to be transported and cut, and transfers and tears only the defective label. Only the labels in the existing mode can be moved individually and controlled to check multiple labels again.

In addition, the multi-field wireless communication label automatic packet inspection and tearing system of the present invention, the release unit for separating the multi-label of the roll type by one tag for each label of each mode, and each of the tags separated from the release portion predetermined A label transfer unit for distance transfer, a packet inspecting unit for reading NFC tag chip information written on labels of different modes transferred from the label transfer unit, and checking whether it matches with predetermined information, and in the packet inspecting unit The transfer cutting unit for transporting and cutting the inspected label, and if it is determined that the roll type tag is seated on the release portion, the label transfer unit transfers the separated tags, and the packet inspection of the different modes of the transferred label After the inspection, the packet inspection unit determines that the label of each mode is normal, and the multi-label is determined. It may be transferred to the transfer cutting unit be configured with a control unit for controlling so as to cut out at the same time.

Meanwhile, a multi-label provided to attach a near field communication (NFC) inlay to the multi-labels in one process and inspect, cut, and package the multi-labels of the roll type, each of which is pre-set with different modes of information, is provided. The method for automatically detecting and cutting a short-range wireless communication label may include (a) transferring the roll type multiple labels and separating each tag by one tag for each mode label, and (b) the packet inspecting unit may transfer the transferred data to each other. Reading each NFC tag chip information written in a label of a different mode and checking whether it matches the preset information; and (c) if the label of each mode is determined to be normal by the packet inspecting unit, transfers multiple labels, respectively. (B) If the label of the mode determined to be defective is present as a result of the step of cutting and simultaneously cutting to the cutting part and (d) Only the label of the defective mode can be made by including the step of transporting to the cutting cutting.

In addition, the step (d) after the step of cutting the label of the bad mode control only the label of the mode belonging to the bad label is transferred to the label transfer unit, and the control step to control the multi-label again in the packet inspection unit It is preferable to comprise it.

Therefore, according to the multi-field wireless communication label automatic packet inspection and tearing system and method of the present invention, since the packaging speed of the NFC tag can be fundamentally improved by inspecting and tearing the label supplied in the packet, mass production is possible. Therefore, the cost can be reduced.

In addition, according to the present invention, the multi-field wireless communication label automatic packet inspection and truncation system and method of the present invention are more effective in the cause of a defective label that can be isolated because multiple labels are supplied, encoded, inspected, and truncated in one process. It can be improved.

In addition, when a bad label is generated, only the corresponding bad label may be cut off, and the inspection and cutting process may be continuously performed, thereby making the packaging process of the multiple labels faster.

1 is a block diagram showing the main configuration of the multi-field wireless communication label automatic packet inspection and tearing system of the present invention;
2 is a flow for explaining a method for automatic packet inspection and tearing of multiple short-range wireless communication labels of the present invention;
3 is a block diagram showing the main configuration of a multi-field wireless communication label automatic packet inspection and tearing system according to another embodiment of the present invention;
And,
4 is a flowchart illustrating a method for automatically checking and cutting multiple short-range wireless communication labels according to another embodiment of the present invention.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, except to exclude other components unless otherwise stated. It should be noted that the terms such as " part, "" module, " .

First, terms used in the present invention are defined as follows.

"Multi-label" and "multi-mode" are systems that are built so that different information (modes) can be encoded on different labels in one process, simultaneously supplying one or more labels in parallel, and at the same time different modes for each label. Refers to labels and modes configured to record information.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

1 is a block diagram showing the main configuration of the multi-field wireless communication label automatic packet inspection and tearing system of the present invention, as shown in the multi-point wireless communication label automatic packet inspection and tearing system is to label the inlay attached; The label converting apparatus 100 for cutting and the label encoding apparatus 170 for storing information on the tag chip and the label inspecting unit 190 for inspecting the stored information are configured in one process.

The label converting apparatus 100 is configured to separate a plurality of supplied labels, attach a Near Field Communication (NFC) inlay bonded with a tag chip and an antenna to each label, and cut the sheet to a predetermined size.

To this end, the label converting apparatus 100 is a label fabric supply unit 110 for separating and supplying the label paper to be fed to the front and rear, and the short-range wireless bonding the tag chip and antenna on the front surface separated from the label fabric supply unit 110 An inlay attachment unit 120 for supplying a Near Field Communication (NFC) inlay, a lamination unit 150 and a lamination unit laminating the rear surface separated from the label fabric supply unit 110 and the front surface to which the inlay is attached (NFC). It comprises a processing unit 160 for cutting and processing the label output from the 150.

The label fabric supply unit 110 is configured to receive a roll-type label paper applied to a general label such as PP paper, PET paper, art paper, etc., and separate and supply it to the front and the rear.

Therefore, the label fabric supply unit 110 is composed of a fabric feed section 112 for feeding the label fabric and the separating section 114 for separating the label fabric fed from the fabric feed section 112 to the front and rear, separated front label The fabric is transferred to the inlay supply unit 140 so that the NFC inlay is attached, and the separated back label fabric is transferred to the adhesive adhesive process.

The label fabric supply unit 110 includes a supply shaft on which a roll R wound around the label fabric is wound, and a motor may be connected to the supply shaft, and the motor rotates the supply shaft as desired.

In addition, it may include a tension roll for intermittently rotating or continuously rotating the roll as desired and maintaining a constant tension of the label fabric.

Hereinafter, the inlay attachment portion 120, the lamination portion 150, the processing portion 160, and the label encoding apparatus 170 to be described will all be similar to the roll configuration of the label fabric supply portion 110. It will be omitted.

The inlay attachment unit 120 is operated to attach the inlay supplied from the inlay supply unit 140 to the front label fabric separated from the separation unit 114 of the label fabric supply unit 110.

The inlay supply unit 140 is configured to cut and supply only the inlays selected from the NFC inlays to be attached to the inlay attachment unit 120.

To this end, the inlay supply unit 140 is an inlay sorting unit for selecting only the inlays that meet the standard from the paper feed unit 142 and the inlay fed from the feeder 142, the tag chip and the antenna supply the inlay bonded to the tag chip and antenna ( 146) and the inlay cutting unit 148 for cutting and supplying the upper, lower, left, and right sides according to a standard capable of attaching the selected inlay.

NFC tag chip does not have a separate battery (battery), active wireless identification tag having a passive wireless identification tag and a separate battery to rectify the electromagnetic waves transmitted from the reader / writer to obtain their own operating power as their power source All tags are possible.

Active passive identification tags, unlike passive wireless identification tags, are internal RF batteries and transmitters that can transmit themselves. Active RFID reader and tag of UHF (433MHz) band uses single frequency band frequency shift keying (FSK) signal, can communicate with each other by halfduplexing method, and has relatively long recognition distance so that it can manage pallets and containers of airport or port. For example, it can be used for asset tracking management systems such as plant parts management.

On the other hand, the back of the label fabric separated from the separating portion 114 of the label fabric supply unit 110 is transferred to the adhesive processing unit 130 is configured to adhere the adhesive.

The adhesive process is hot melt (Hot Melt) adhesive processing is transferred to the lamination unit 150.

The hot melt adhesive is made of thermoplastic resin (20-50%) as a base polymer without using water or a solvent at all, and a wax that improves applicability by lowering the viscosity at the time of melting and tackifer (30-50%) and melting. Pollution-free hot melt which is mixed with antioxidant and filler in the main three components (10 ~ 30%), applied and adhered to the surface of the adherend in the heat-melting state and then solidified by cooling. Mold adhesive.

Typical hot melts include EVA (Ethylene Vinyl Acetate), Rubber, Polyamide, and Polyurethane.However, due to the characteristics of the tag, it does not fall back when reacted with moisture after being melted and bonded. It is preferable to use Polyurethane, which is a moisture-curable hot melt that is used in various ways.

The lamination unit 150 is operated to bond the label front with the NFC inlay attached to the conveyed label from the inlay attachment unit 120 and the adhesive backed label at the adhesive processing unit 130.

That is, in the lamination unit 150, an adhesive is attached to the back of the roll-shaped label paper, and then the NFC chip is manufactured by laminating the front surface of the label paper with the inlay bonded to the tag chip and the antenna.

On the other hand, the back of the label with the adhesive can be further added to the release paper for adhesion, such release paper can be laminated, the base film, such as PET, PP, PVC, PE.

The wireless identification tag chip receives unique ID information as the wireless identification tag information during the production of the wireless identification tag (or attaches the wireless identification tag to a predetermined product) and uses it during its lifespan. Wireless identification tag having a memory of type Many and predetermined ID information in at least one or more writable memories (WROM and / or write many (WM) type memory) can be recorded and reused as wireless identification tag information. A radio identification tag is possible.

Specifically, for example, the wireless identification tag is a tag antenna formed using a conductive material (Cu, Al, Ag paste, etc.) on a thin film-shaped base made of polyethylene terephthalate (PET) material or polyimide material, and the like; An IC chip to which an IC electrode is connected via a bump to the antenna, and a cover sheet adhered by an adhesive to a base covering these antennas and the IC chip can be formed.

The IC chip constituting this radio identification tag can exchange information by performing radio communication with an external device through a tag antenna.

On the other hand, the label attached to the NFC tag in the lamination unit 150 is transferred to the processing unit 160 is processed to a predetermined size to work in a roll form or to be automatically transferred directly to a label encoding apparatus that is a subsequent process in one process It may be.

The label converting apparatus 100 is transferred to the label encoding apparatus 200 in order to record information on the label wound in the form of a roll or NFC tag transferred in a continuous process.

To this end, the label encoding apparatus 200 is configured such that a plurality of rolls may be supplied in a packet form or may write information of different modes, that is, multi-mode information, on a plurality of labels transferred from the plurality of label converting apparatus 100. do.

That is, the label encoding apparatus 200 may be configured to write the information in different modes to each label by supplying the roll-shaped labels supplied from the label converting apparatus 100 in parallel, or at least one label converting apparatus 100. ) To write the information of different modes to the label transferred.

For example, information such as a car mode, an office mode, and a sleep mode may be respectively written, and they may be written in a required combination. That is, the car mode and the office mode may be simultaneously encoded, or the car mode, the office mode, and the standby mode may be simultaneously encoded.

Each of the label encoding apparatus 200 is operable to write the ID information to the NFC tag in the antenna when generating the NFC signal to the antenna installed on the antenna installed under the label of the NFC tag to be transferred in each roll.

In this case, a radio wave shield may be used for each antenna adjacent to the NFC tag to be written, and the size of the electronic shield may be changed to include only one NFC tag. to be.

To this end, each label encoding apparatus 200 and the sensor recognition unit 210 for detecting the mark for encoding in the tag chip of the inlay processed by the processing unit 160 to write (Writing) information to the NFC tag chip to be transported; It may be configured to include a writing unit 220 for recording information on the tag chip of the inlay on the basis of the mark detected by the sensor recognition unit 210.

In the exemplary embodiment of the present invention, the sensor recognition unit 210 has been described as checking and marking the encoding mark, but this is not limited thereto.

For example, a controller having a programmable logic controller (PLC) function sequentially moves the NFC tag chip to a predetermined position according to the contents programmed, and then writes the lighting. When the writing is finished, the next NFC tag chip is moved and written again. Likewise, encoding may be automatically performed sequentially.

Further encoding and / or printing may be performed based on information stored in the NFC tag chip or optically readable information. This is because it has advantages such as flexibility of the manufacturer and effective control of the manufacturing process to customize the label in producing a more universal label.

In addition, if it is determined that the recording of the information is completed in the writing unit 220 may further include a complete display unit 230 for displaying a completion message so that the inspector can check the completed NFC tag chip.

Since the label / tag encoding device is configured to operate in conjunction with the control unit 300 of the device, that is, when encoding after the label / tag processing in the device, if an error occurs, the control unit displays an error and simultaneously displays the control unit. When the error data is transmitted to the 300, the control unit 300 may perform a function of stopping the operation of the label converting apparatus 100 and the label encoding apparatus 200.

More preferably, the inspector counts the NFC label and the defective label in which encoding is normally completed, so that in the event of a serious defect, the short-range wireless communication label tag processing system of the present invention can be automatically stopped and an error can be solved.

When writing of the information necessary for the NFC tag chip transferred as described above (Writing) is completed, the NFC label output through the NFC label output unit 240 is output in the form of a roll.

The roll form at this time is output in roll form for each mode.

The roll-shaped labels of different modes output from the NFC label output unit 240 are transferred to the packaging process in order to package in bundles at the request of the consumer.

As described above, the packaging process attaches a near field communication (NFC) inlay to multiple labels in one process and inspects and cuts the roll-type multiple labels, each of which is filled with information of different preset modes. Is operated to wrap.

To this end, the label of the mode required as a bundle among the multiple labels of the roll type output from the NFC label output unit 240 is mounted on the release unit 310 and separated by one tag for each label of each mode.

At least one release part 310 may be installed to load labels of different modes, and may be operated to separate one by one tag from the mounted roll type label.

One tag separated from the unwinding part 310 is transported by a label transfer part 320 for a predetermined distance, respectively, for inspection.

The labels of different modes transferred by the label transfer unit 320 read NFC tag chip information written by the packet inspector 330 and check whether the labels match the predetermined information recorded by the encoder 200. .

To this end, the packet inspecting unit 330 may detect an encoding mark in the tag chip of the inlay processed by the processing unit 160, and may read information from the tag chip of the inlay based on the detected mark.

Alternatively, without checking the above-described encoding mark, for example, the control unit having a programmable logic controller (PLC) function may sequentially move the NFC tag chip to a predetermined position and then read the information according to the programmed content. to be.

The label inspected by the packet inspecting unit 330 is transferred to the transport cutting unit 340 and cut into one label unit.

When the roll type tag is mounted on the unwinding unit 310 and the individual tags are separated from the roll type labels of the different modes, the control unit 300 controls the label transfer unit 320 to transfer the separated tags. In addition, the transferred label tags of different modes are controlled to be inspected by the packet inspecting unit 330.

In this case, when the inspection result is determined by the packet inspecting unit 330 to determine that the label of each mode is normal, the control unit 300 controls the multiple labels to be simultaneously transported to the transport cutting unit 340, and the packet inspecting unit 330 transports them. As a result of inspecting the tag of the multi-mode, as a result, if there is a label of the mode determined to be defective, only the label of the defective mode is transferred to the transfer cutting unit 340 and controlled to be cut.

To this end, the transfer cutting unit 340, for example, by driving a motor to slide each label inserted between the lower driving roller and the upper idle roller to the upper surface of the support plate when the optical sensor sequentially detects the mark displayed on the label and the optical As the distance between the sensor and the cutting blade applies a signal to the controller that is input in advance, the rotation of the motor is properly controlled so that the mark of the label always stops directly under the cutting blade, and the cutting operation by the cutting blade is continuously performed. To be repeated.

The transfer cutting unit 340 may include a bad label transfer cutting unit 342 for cutting only a defective label to be transferred and a packet label cutting unit 344 for cutting a normal label to be transferred in a multi-mode.

The bad label transfer cutting unit 342 and the packet label cutting unit 344 may be configured in a process for each roll type provided in different modes, but only the packet label cutting unit 344 is installed on each label process. And, it may be configured to cut the conveyed label by the control of the control unit 300, the conveying only the defective label or the normal label.

As a result, the defective label cut by the control of the control unit 300 may be cut off, and the labels cut normally are collected in the collecting / packaging unit 350 and packaged in one packaging container and commercialized.

In addition, the controller 300 transfers the label of the mode determined to be defective to the transfer cutting unit 340 and then cuts the label of the mode to which the defective label belongs in order to continue inspection. To control and continue to control to inspect the multi-label in the packet inspection unit 330 can be to quickly remove the defective label and move to the packaging process.

Hereinafter, an automatic packet inspection and truncation method for multiple short range wireless communication labels according to an embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 3 is a flowchart illustrating a system and method for automatic packet inspection and tearing of multiple short range wireless communication labels according to an embodiment of the present invention, and will be described based on the use of roll type labels having different encoding modes. .

That is, the roll type label output from the label encoding apparatus 200 for storing information in the tag chip supplied from the label converting apparatus 100 for cutting and processing the label with the inlay is mounted on the release part 310. (S410).

The label mounted on the release part 310 is separated for each tag and transferred to the label transfer part 320 (S420).

The label transferred from the label transfer unit 320 reads the NFC tag chip information written by the packet inspecting unit 330 and checks whether the label is identical to the preset information recorded by the encoding unit 200 (S430).

As a result of the inspection in the packet inspecting unit 330 of step S430, when it is determined that the label of each mode is normal (S440), the control unit 300 controls to simultaneously cut and transport the multiple labels to the transfer cutting unit 340 (S450). As a result of inspecting the tag of the transferred multi-mode in step S440, if there is a label of the mode determined to be defective, only the label of the corresponding defective mode is transferred to the transfer cutting unit 340 to cut it (S460).

If it is determined in step S460 that the transfer and cutting of the defective label are completed, the control unit 300 transfers only the label of the mode determined as defective to the transfer cutting unit 340, and then cuts the mode in which the defective label belongs to continue the inspection. Only the label of the label transfer unit 320 can be individually transported and then control the multi-label inspection in the packet inspection unit 330 with the existing normal label to quickly remove the defective label and can be shifted to the packaging process. (S470).

As described above, the multi-range wireless communication label automatic packet inspection and tearing system and method of the present invention simultaneously write a plurality of information on a multi-mode NFC tag in one process and simultaneously check a multi-mode tag at the same time so that a bad label can be quickly. The ability to remove and collect / package only completed labels has the effect of producing multi-mode labels quickly.

Hereinafter, a multi-field wireless communication label automatic packet inspection and tearing system and method according to another embodiment of the present invention will be described with reference to the accompanying drawings.

In addition, the same configuration and function as the above-described embodiment will be omitted using the same reference numerals.

FIG. 3 is a block diagram illustrating a main configuration of a system for automatically inspecting and cutting a packet of multiple short range wireless communications according to another embodiment of the present invention, and FIG. It is a flowchart for explaining a packet inspection and truncation method.

Multi-field wireless communication label automatic packet inspection and tearing system of the present invention according to the embodiment described above is a label converting device 100 for cutting the label with the inlay and label encoding device 170 for storing information in the tag chip ) Is configured to be inspected by the label inspection unit 190 for continuously processing in one process and then inspect the stored information, but according to another embodiment of the present invention, the multi-field wireless communication label automatic packet inspection and tearing system of the present invention is label converting. It is a device for processing the encoding process and the inspection process at the same time at the inspection unit for the label with an inlay provided from the device 100.

Such a device performs an encoding process and an inspection process simultaneously in order to easily tear off a label of a roll type label supplied separately in an inspection process.

To this end, the multi-field wireless communication label automatic packet inspection and tearing system according to another embodiment transfers one or more labels provided in a roll type separately for each tag, encodes them in multiple modes, and then transfers the multi-mode tags. Are controlled to feed and cut multiple labels at the same time only when they are checked at the same time and determined to be normal.

In detail, the label converting apparatus 100 performs a label unwinding unit 310 that separates one tag for each label of each mode to which one or more roll-type labels with an inlay provided from the NFC label output unit 240a are attached. ) And a label transfer unit 320 for transferring a predetermined distance to each tag separated from the release unit 310, and an encoding unit for encoding information of different modes to each tag transferred from the label transfer unit 320. A packet inspecting unit 330 which reads the NFC tag chip information written on the label on which the information of the different modes transferred from the encoding unit 200a is recorded, and checks whether the information matches the predetermined information, and Transfer cutting unit 344 for transporting and cutting the label inspected by the packet inspection unit 330 and, if it is determined that the roll type tag is seated on the release unit 310, the label transfer unit 320 transfers the separated tags Make it work, The coding unit 200a encodes the information of each different mode, and the packet inspecting unit 330 inspects the transferred labels of the different modes, and then the packet inspecting unit 330 inspects each mode. If it is determined that the label is normal, it is configured to include a control unit (300a) for controlling to cut at the same time by transporting the multiple labels to the transfer cutting unit 344, respectively.

The encoding unit 200a generates an NFC signal on the antenna installed under the label of the NFC tag transferred from the label transfer unit 320 and transmits ID information. The encoding unit 200a operates to write ID information on the NFC tag.

In this case, a radio wave shield may be used for each antenna adjacent to the NFC tag to be written, and the size of the electronic shield may be changed to include only one NFC tag. to be.

To this end, each encoding unit 200a detects the sensor recognition unit 210a and the sensor recognition unit 210a for detecting the encoding mark in the tag chip of the inlay in order to write information on the transferred NFC tag chip. It may be configured to include a writing unit 220a for recording information on the tag chip of the inlay on the basis of the mark.

In another exemplary embodiment of the present invention, the sensor recognition unit 210a has been described as checking and marking the encoding mark, but the present invention is not limited thereto.

For example, a controller having a programmable logic controller (PLC) function sequentially moves the NFC tag chip to a predetermined position according to the contents programmed, and then writes the lighting. When the writing is finished, the next NFC tag chip is moved and written again. Likewise, encoding may be automatically performed sequentially.

Further encoding and / or printing may be performed based on information stored in the NFC tag chip or optically readable information. This is because it has advantages such as flexibility of the manufacturer and effective control of the manufacturing process to customize the label in producing a more universal label.

In addition, the writing unit 220a may further include a completion display unit 230a for displaying a completion message so that the inspector can check the completed NFC tag chip when it is determined that the recording of the information is completed.

As a result of inspecting the tag of the multi-mode transferred by the packet inspecting unit 330, the control unit 300a encodes only the label to which the corresponding bad mode belongs and transfers one label. The bad label conveyed to 340 is controlled to be cut off.

In detail, when the control unit 300a inspects the tag of the multi-mode transferred by the packet inspecting unit 330, if there is a label of a mode determined as bad, only the label to which the corresponding bad mode belongs is encoded by the encoding unit 200a. One label is transported and the bad label transferred to the transport cutting unit 340 is controlled to be cut.

A multi-field wireless communication label automatic packet inspection and tearing method of the present invention according to another embodiment of such a configuration will be described with reference to FIG. 4.

The control unit 300a unwinds the roll type label in which information is not recorded in the tag chip supplied from the NFC label output unit 240a provided in the roll type in the label converting apparatus 100 for cutting and processing the label with the inlay. It is mounted on the 310 (S510).

The label mounted on the release part 310 is separated for each tag and transferred to the label transfer part 320 (S520).

In step S530 of writing information of different modes for each tag transferred by the label transfer unit 320 in the encoding unit 200a and the labels of the different modes encoded and transferred in the encoding unit 200a, the packet inspecting unit In step 540, the controller 330 reads each of the predetermined information and checks whether the label of the respective modes is normal. It consists of a step (S560).

That is, the encoding unit 200a encodes information of different modes for each tag transferred from the label transfer unit 320, and proceeds to write information of different modes on the conveyed label.

More specifically, the encoding unit 200a detects an encoding mark in the tag chip of the processed inlay for writing information on the transferred NFC tag chip (S531) and the sensor recognition unit 210a. In the writing step (S532) and the writing step (S532) for recording the information on the tag chip of the inlay based on the mark detected in the (S532), if it is determined that the recording of the information is completed, the completion message so that the inspector can check the completed NFC tag chip The display may further include a completion display step (S533).

The sensing incing step S531 may be omitted by using the PLC control, and the completion display step S533 may also be omitted.

If there is a label of the mode determined to be defective in the inspection result in step S540, only one label of the mode to which the label of the bad mode belongs is transferred and the information of the mode is written by the encoding unit 200a, and only the label of the bad mode is transferred. Transfer to the cutting unit to cut (S570 ~ S580) and the packet inspection unit 330 to repeat the control to inspect the multiple labels again.

After all, the present invention is to inspect the roll-type label of the encoding is completed in the inspection device to quickly remove the defective label to improve the mass production speed, and at the same time, only the label of the roll borrowing the inlay supplied from the label converting device By supplying to the inspecting device to encode at the same time as the multi-mode encoding, it is possible to quickly remove the bad label in the encoding and multi-mode easily.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: label converting device 110: fabric supply unit
120: attachment portion 130: adhesive processing portion
140: inlay feeder 142: inlay feeder
146: inlay selection unit 148: inlay cutting unit
150: lamination unit 160: processing unit
200: label encoding apparatus 200a: encoding unit
210,210a: Sensor recognition part 220,220a: Lighting part
230,230a: completion indicator
240, 240a: label output unit 300: control unit
310: unwinding unit 320: label transfer unit
330: packet inspection unit 340: transport cutting unit
350: collecting packing

Claims (13)

Multiple near field radios provided for attaching Near Field Communication (NFC) inlays to multiple labels in one process and inspecting, tearing and wrapping multiple labels of roll type, each of which is pre-set with different modes of information. In the communication label automatic packet inspection and truncation system,
The control unit controls to separate and transfer the labels of each mode by one tag in the multi-label provided in the roll type, and to simultaneously transport and cut the multiple labels only when it is determined to be normal by inspecting the transferred multi-mode tags simultaneously. ;
Multiple short range wireless communication label automatic packet inspection and tearing system comprising a.
The method of claim 1,
The control unit
A multi-range wireless communication label automatic packet inspection and truncation system that controls to transfer and tear only a label of a defective mode when a label of a mode determined to be defective exists as a result of inspecting a tag of a transferred multimode.
3. The method of claim 2,
The control unit
Multi-short wireless communication label automatic packet inspection and tearing system for controlling to inspect the multi-label again by moving only the label of the mode belonging to the bad label after the tearing only the bad label.
The method of claim 1,
A release unit for separating the roll type multiple labels by one tag for each label of each mode;
A label transfer unit for transferring a predetermined distance from each tag separated from the release unit;
A packet inspecting unit which reads NFC tag chip information written on labels of different modes transferred from the label conveying unit and checks whether it matches with predetermined information;
A transport cutting unit for transporting and cutting the label inspected by the packet inspecting unit;
When it is determined that the roll type tag is seated on the release part, the label transfer unit transfers the separated tags, and the packet inspecting unit inspects the transferred labels of different modes, and then, in the packet inspecting unit, A control unit for controlling multiple labels to be simultaneously cut by transferring the multiple labels to the transfer cutting unit when it is determined that the labels of the respective modes are normal;
Multiple short range wireless communication label automatic packet inspection and tearing system comprising a.
5. The method of claim 4,
The control unit
As a result of inspecting the tag of the multi-mode transferred by the packet inspecting unit, if a label of a mode determined to be defective exists, only the label of the corresponding defective mode is controlled to be cut and transported to the feed cutting unit, and then the label of the mode to which the bad label belongs. Multi-field wireless communication label automatic packet inspection and tearing control system to control only the label transfer unit to be transferred separately and the packet inspection unit to check again multiple labels.
Multiple near field radios provided for attaching Near Field Communication (NFC) inlays to multiple labels in one process and inspecting, tearing and wrapping multiple labels of roll type, each of which is pre-set with different modes of information. In the communication label automatic packet inspection and cutting method,
(a) transporting the roll-type multiple labels to separate the tags by one tag for each mode label;
(b) in the packet inspecting unit, reading NFC tag chip information written on the transferred labels of different modes and checking whether the packet matching unit matches the preset information;
(c) when the packet inspection unit determines that the label of each mode is normal, transferring the multiple labels to the transfer cutting unit and cutting them simultaneously; and
(d) if the label of the defective mode is found as a result of the inspection in the step (b), transferring only the label of the defective mode to the transfer cutting unit and cutting it;
Multi-field wireless communication label automatic packet inspection and tearing method comprising a.
The method according to claim 6,
The step (d)
Controlling the multi-labels to be re-inspected, including a label of the bad mode that is cut out and transferred to the packet inspection unit at the same time as the label of the bad mode transferred from the label transfer unit;
Multi-field wireless communication label automatic packet inspection and tearing method comprising a.
Near Field Communication (NFC) Provides one or more roll type labels with inlays and writes different modes of information on each label, simultaneously inspecting, tearing and packing Label automatic packet inspection and tearing system,
One or more labels provided in the roll type are separated and transported for each tag, encoded in a multi mode, and the tags of the transferred multi mode are simultaneously inspected and controlled to simultaneously transport and cut multiple labels only when it is determined to be normal. A control unit;
Multiple short range wireless communication label automatic packet inspection and tearing system comprising a.
The method of claim 8,
The control unit
As a result of inspecting the tag of the transferred multi-mode, if there is a label of the mode determined as defective, only the label belonging to the defective mode is encoded so that one label is transferred, and the defective label transferred to the transfer cutting part is cut off. Automated packet inspection and tearing system for wireless communication labels.
The method of claim 8,
An unwinding unit for separating one or more roll type labels by one tag for each label of each mode to be written;
A label transfer unit for transferring a predetermined distance from each tag separated from the release unit;
Encoding information of different modes in an encoding unit to each tag transferred from the label transfer unit;
A packet inspecting unit which reads the NFC tag chip information written on the recorded labels of different modes of information transferred from the encoding unit and checks whether the information matches the predetermined information;
A transport cutting unit for transporting and cutting the label inspected by the packet inspecting unit;
When it is determined that the roll type tag is seated on the release part, the label transfer part transfers the separated tags, the encoding part encodes information of each different mode, and the label of the transferred different mode. A control unit for inspecting the packet inspecting unit, and then, if the label inspecting unit determines that the label of each mode is normal, controls the multi-label to be transported to the transport cutting unit at the same time.
Multiple short range wireless communication label automatic packet inspection and tearing system comprising a.
The method of claim 10,
The control unit
As a result of inspecting the tag of the multi mode transferred by the packet inspecting unit, if there is a label of the mode determined as defective, only the label belonging to the defective mode is encoded so that one label is transferred and the defective label transferred to the transfer cutting unit is cut off. Multiple short range wireless communication label automatic packet inspection and tearing system to control.
Multiple near field communication label automatic packets provided to supply one or more roll type labels with Near Field Communication (NFC) inlays, to write different modes of information, to inspect, to cut and package them, respectively. In the inspection and cutting method,
(a) mounting the at least one roll type label in the unwinding unit and separating and transferring the roll type label into one tag for each roll type label;
(b) writing information of different modes for each tag transferred from the release unit in the encoding unit;
(c) reading labels of different modes encoded and transported by the encoding unit in a packet inspecting unit, respectively, and checking whether the labels match the predetermined information;
(d) if it is determined that the label of each mode is normal in the packet inspecting unit, transferring the multiple labels to the transport cutting unit and cutting them simultaneously; and
(e) if the label of the defective mode is found as a result of the inspection in step (c), transferring only the label of the defective mode to the transfer cutting unit and cutting it;
Multi-field wireless communication label automatic packet inspection and tearing method comprising a.
13. The method of claim 12,
The step (e)
(e-1) writing only the label of the mode to which the label of the defective mode belongs, and writing information of the corresponding mode in the encoding unit;
(e-2) cutting and cutting only the label of the defective mode to the transfer cutting unit; and
(e-3) controlling the packet inspecting unit to check multiple labels again;
Multi-field wireless communication label automatic packet inspection and tearing method comprising a.

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