JP4581492B2 - RFID tag producing apparatus and control program for RFID label producing apparatus - Google Patents

Description

  The present invention relates to an RFID label producing apparatus for producing an RFID label capable of exchanging information with the outside by wireless communication, and more particularly, an RFID label having an arbitrary shape equipped with an RFID tag. The present invention relates to a creating apparatus and a control program for a RFID label producing apparatus.

  An RFID (Radio Frequency Identification) system that reads and writes information in a non-contact manner between a small wireless tag and a reader (reading device) or a writer (writing device) is known. For example, a wireless tag circuit element provided in a label-like wireless tag includes an IC circuit unit that stores predetermined information and an antenna unit that is connected to the IC circuit unit and transmits and receives information. Alternatively, information can be read from and written to the IC circuit section from the writer side, and practical use is expected in various fields such as product management and inspection processes.

  As such an RFID label producing apparatus, for example, an apparatus described in JP-A-2002-53116 (Patent Document 1) is known. In this prior art, it is possible to print on the label and attach the RFID tag to an arbitrary position in the longitudinal direction of the label.

Japanese Patent Application Laid-Open No. 8-30027 (Patent Document 2) discloses an image creation and clipping device that can print an image on a sheet based on image data and cut out the outline of the image.
JP 2002-53116 A Japanese Patent Laid-Open No. 8-3000297

  However, when an RFID tag label having an arbitrary shape is created using a conventional apparatus, for example, an image or text is printed on a sheet using an apparatus disclosed in Patent Document 2, and the sheet is predetermined. Next, it is necessary to manually attach the RFID label at a predetermined position, which is not only complicated, but also the attachment position is wrong, so that it corresponds to a sheet-shaped member of a predetermined shape. There was a problem that the wireless tag could not be securely attached.

  Further, when a wireless tag is mounted on a sheet and then the sheet is cut into a predetermined shape, there is a problem that the wireless tag may be accidentally cut and destroyed.

  An object of the present invention is to solve the above-described problems, and by attaching a wireless tag to a sheet-like member and cutting the sheet-like member into an arbitrary shape, an arbitrary-shaped wireless tag label can be easily obtained. An object of the present invention is to provide an RFID label producing apparatus and an RFID tag producing apparatus control program that can be produced.

In order to achieve the above object, a wireless tag label producing apparatus according to claim 1 of the present invention is a wireless tag attaching means for attaching a wireless tag to a sheet material, and the wireless tag is attached by the wireless tag attaching means. Cutting means for cutting the sheet material into a predetermined shape, a carriage on which the RFID tag attaching means and the cutting means are integrally mounted, one direction along the plane of the sheet material and the carriage or the sheet material, and crossing the direction Driving means for driving in a direction to be attached, attachment position information indicating a position where the wireless tag attaching means attaches the wireless tag to the sheet material, and cutting position information indicating a position where the cutting means cuts the sheet material. And controlling the drive means and the wireless tag attachment means based on storage means and attachment position information stored in the storage means. And control means for controlling said cutting means and said driving means on the basis of the cutting position information stored in said storage means, based on the stored mounting position information and the cutting position information in the storage means, the sheet material on Detecting means for detecting whether or not the position of the wireless tag to be attached to the cutting position for cutting the sheet material overlaps, and the wireless tag and the cutting position when the detecting means detects that the wireless tag and the cutting position overlap. Position information changing means for changing cutting position information or attachment position information so as not to overlap with the position is provided.
The RFID label producing apparatus according to claim 2 is the RFID label producing apparatus according to claim 1, wherein the cutting position information includes information indicating a cutting line for cutting a sheet material, and the position information changing unit includes: The cutting position information is changed by deleting the line where the wireless tag and the cutting line overlap from the line indicated by the cutting position information stored in the storage means.
The RFID label producing apparatus according to claim 3 is the RFID label producing apparatus according to claim 1, wherein the cutting position information includes information indicating a cutting line for cutting a sheet material, and the position information changing unit includes: The line indicated by the cutting position information stored in the storage means is changed to information indicating a line surrounding the position indicated by the mounting position information stored in the storage means without overlapping the wireless tag.
The RFID label producing apparatus according to claim 4, wherein the RFID tag attaching means for attaching the RFID tag to the sheet material, the cutting means for cutting the sheet material to which the RFID tag is attached by the RFID tag attaching means, into the predetermined shape, A carriage integrally mounting the wireless tag attaching means and the cutting means, a driving means for driving the carriage or the sheet material in one direction along the plane of the sheet material and a direction crossing the direction, and the wireless tag attaching means Includes storage position information indicating a position where the wireless tag is attached to the sheet material, storage position information indicating a position where the cutting means cuts the sheet material, and attachment position information stored in the storage means. Based on the cutting position information stored in the storage means. The position of the wireless tag to be mounted on the sheet material and the sheet material are cut based on the control means for controlling the driving means and the cutting means, and the mounting position information and the cutting position information stored in the storage means. Detection means for detecting whether or not the cutting position overlaps, and notification means for notifying that the wireless tag and the cutting position overlap when the detection means detects that the wireless tag and the cutting position overlap. And.

The RFID label producing apparatus according to claim 5 is the RFID label producing apparatus according to any one of claims 1 to 4 , wherein the driving means includes a carriage driving means for driving the carriage in one direction, and the sheet material. The sheet material driving means is configured to drive in a direction crossing the one direction.

The RFID label producing apparatus according to claim 6 is the RFID label producing apparatus according to any one of claims 1 to 5 , wherein the carriage is equipped with a printing unit, and the storage unit stores print information to be printed on a sheet material. The control means controls the driving means and the printing means based on the printing information.

RFID label producing device according to claim 7, in the RFID label producing apparatus according to claim 6, wherein the sheet reversing means for reversing the front and back of the sheet, the back surface of the sheet material the stored mounting position information in the storage means Position information conversion means for converting into position information corresponding to the position information conversion means, the control means attaches a wireless tag based on the attachment position information converted by the position information conversion means, and then by the sheet material reversing means The sheet material is inverted, printed on the sheet material based on the print information stored in the storage means, and controlled to cut the sheet material based on the cutting position information stored in the storage means.

The RFID label producing apparatus according to claim 8 is the RFID label producing apparatus according to claim 6 , wherein the sheet material reversing means for reversing the front and back of the sheet material, the attachment position information and the cutting position stored in the storage means Position information conversion means for converting the information into position information corresponding to the back surface of the sheet material, the control means performs printing based on the print information stored in the storage means, and then the sheet material reversing means The sheet material is reversed, the wireless tag is attached to the sheet material based on the attachment position information converted by the position information conversion means, and the sheet material is cut based on the cutting position information converted by the position information conversion means. Is to control.

The RFID label producing apparatus according to claim 9 is the RFID label producing apparatus according to claim 6 , wherein the sheet material reversing means for reversing the front and back of the sheet material, and the mounting position information stored in the storage means are used as the sheet material. Position information conversion means for converting into position information corresponding to the back surface of the sheet, and the control means performs printing based on the print information stored in the storage means, and then uses the sheet material reversing means to output the sheet material. The cutting position information stored in the storage means is reversed, the wireless tag is attached to the sheet material based on the attachment position information converted by the position information conversion means, and then the sheet material is inverted by the sheet material reversing means. Based on the above, the sheet material is controlled to be cut.

11. The wireless tag label producing apparatus control program according to claim 10, wherein the wireless tag attaching means for attaching the wireless tag to the sheet material, and the cutting means for cutting the sheet material attached with the wireless tag into a predetermined shape by the wireless tag attaching means. A carriage that integrally mounts the RFID tag attaching means and the cutting means, and a drive means that drives the carriage or the sheet material in one direction along the plane of the sheet material and in a direction intersecting the direction. In the control program for a RFID label producing apparatus for controlling the RFID label producing apparatus, the attachment position information indicating the position of the RFID tag attached on the sheet material by the RFID tag attaching means and the cutting position at which the cutting means cuts the sheet material are shown. Based on the cutting position information, the position and position of the wireless tag to be pasted on the sheet material A detection step for detecting whether or not the cutting position for cutting the workpiece overlaps, and the cutting position information so that the wireless tag and the cutting position do not overlap when the detection step detects that the wireless tag and the cutting position overlap. Alternatively, a position information change processing step for changing the attachment position information is provided.

11. RFID label producing device control program described in claim 10 RFID label producing device control program, wherein the cutting position information is composed of information indicating a line to cut the sheet material, the location information In the change processing step, the cutting position information is changed by deleting a line where the wireless tag and the cutting line overlap from a line indicated by the cutting position information.

The RFID label producing apparatus control program according to claim 12 is the RFID label producing apparatus control program according to claim 10 , wherein the cutting position information includes information indicating a line for cutting a sheet material, and the position information In the change processing step, the line indicated by the cutting position information is changed to a line surrounding the wireless tag without overlapping the wireless tag.

14. The wireless tag label producing apparatus control program according to claim 13, wherein the wireless tag attaching means for attaching the wireless tag to the sheet material, and the cutting means for cutting the sheet material to which the wireless tag is attached by the wireless tag attaching means into a predetermined shape. A carriage that integrally mounts the RFID tag attaching means and the cutting means, and a drive means that drives the carriage or the sheet material in one direction along the plane of the sheet material and in a direction intersecting the direction. A control program for a RFID label producing apparatus for controlling an RFID label producing apparatus, wherein the RFID tag attaching means indicates attachment position information indicating a position of an RFID tag attached on a sheet material, and a cutting position at which the cutting means cuts the sheet material. And the position of the wireless tag to be mounted on the sheet material and the sheet A detection step for detecting whether or not the cutting position for cutting the material overlaps, and a notification for notifying that the wireless tag and the cutting position overlap when it is detected that the wireless tag and the cutting position overlap by the detection step And steps.

According to the RFID label producing apparatus of claim 1, it is possible to easily produce an RFID tag of any shape by attaching the RFID tag to the sheet-like member and cutting the sheet-like member into an arbitrary shape. effective. Further, detection means for detecting whether the position of the wireless tag attached on the sheet material and the cutting position for cutting the sheet material overlap based on the attachment position information and the cutting position information stored in the storage means, and the detection If the wireless tag and the cutting position are detected to be overlapped by the means, the wireless tag is provided with position information changing means for changing the cutting position information or the mounting position information so that the cutting position does not overlap. There is an effect that it is possible to prevent the wireless tag from being disconnected.
According to the RFID label producing apparatus according to claim 2, in addition to the effect produced by the RFID label producing apparatus according to claim 1, the cutting position information is constituted by information indicating a cutting line for cutting the sheet material, and the position information change The means changes the cutting position information by deleting the line where the wireless tag and the cutting line overlap from the line indicated by the cutting position information stored in the storage means. There is an effect that cutting by mistake can be avoided.
According to the RFID label producing apparatus according to claim 3, in addition to the effect produced by the RFID label producing apparatus according to claim 1, the cutting position information is constituted by information indicating a cutting line for cutting the sheet material, and the position information change The means changes the line indicated by the cutting position information stored in the storage means to information indicating a line surrounding the position indicated by the attachment position information stored in the storage means without overlapping the wireless tag. There is an effect that the wireless tag can be cut along the periphery of the wireless tag without being cut.
According to the RFID label producing apparatus of claim 4, it is possible to easily produce an RFID tag of any shape by attaching the RFID tag to the sheet-like member and cutting the sheet-like member into an arbitrary shape. effective. Further, detection means for detecting whether the position of the wireless tag attached on the sheet material and the cutting position for cutting the sheet material overlap based on the attachment position information and the cutting position information stored in the storage means, and the detection When it is detected by the means that the wireless tag and the cutting position are overlapped, the wireless tag is provided with a notification means for notifying that the wireless tag and the cutting position are overlapped, so that the wireless tag is not cut to the user. There is an effect that it is possible to take measures to deal with.

According to the RFID label producing apparatus of claim 5 , in addition to the effect of the RFID label producing apparatus according to any one of claims 1 to 4, the carriage is driven in one direction by the carriage driving means, and the sheet material driving means Thus, the sheet material is driven in a direction crossing one direction. Therefore, there is an effect that the relative positional relationship between the sheet material and the wireless tag attaching means can be changed with a compact and simple device configuration.

According to the RFID label producing apparatus of the sixth aspect , in addition to the effects produced by the RFID label producing apparatus according to any one of the first to fifth aspects , the carriage is equipped with printing means, and the storage means is printed on the sheet material. The printing information to be stored is stored, and the control means controls the driving means and the printing means based on the printing information. Therefore, printing, attachment of the wireless tag, and cutting can be performed by a single device, so that printing, attachment of the wireless tag, and cutting can be performed efficiently. Furthermore, since printing, wireless tag attachment, and cutting are driven by the same driving means and positioning is performed, it is possible to improve the relative accuracy of the printing position, wireless tag attachment position, and cutting position. effective.

According to the RFID label producing apparatus according to claim 7, in addition to the effects of the RFID label producing device according to claim 6, wherein the sheet reversing means for reversing the front and back of the sheet, the mounting position information stored in the storage means Position information conversion means for converting the position information into position information corresponding to the back surface of the sheet material, and the control means attaches the wireless tag based on the attachment position information converted by the position information conversion means, and then the sheet material The sheet material is reversed by the reversing means, printed on the sheet material based on the print information stored in the storage means, and controlled to cut the sheet material based on the cutting position information stored in the storage means. A wireless tag can be attached to one side of the material and printed on the opposite side. For this reason, there is an effect that the aesthetics and design of the printed surface are not lowered by the attachment of the wireless tag. In addition, since printing is performed after the wireless tag is attached, when the sheet material is reversed, the sheet material is not printed, and the printing surface is rubbed against the sheet material reversing means and the image quality of the printing surface is deteriorated. And the sheet material reversing means is not contaminated.

According to the RFID label producing apparatus according to claim 8 , in addition to the effect produced by the RFID label producing apparatus according to claim 6, sheet material reversing means for reversing the front and back of the sheet material, and the mounting position stored in the storage means Position information conversion means for converting the information and the cutting position information into position information corresponding to the back surface of the sheet material, the control means performs printing based on the print information stored in the storage means, and then reverses the sheet material The sheet material is reversed by the means, the wireless tag is attached to the sheet material based on the attachment position information converted by the position information conversion means, and the sheet material is cut based on the cutting position information converted by the position information conversion means. Therefore, printing is performed on one surface of the sheet material, and the wireless tag can be attached to the side opposite to the printing surface. For this reason, there is an effect that the aesthetics and design of the printed surface are not lowered by the attachment of the wireless tag. Also, since printing is performed before the wireless tag is attached, when the sheet material is reversed, the wireless tag is not attached to the sheet material, and the wireless tag is scraped off by the sheet material reversing means. There is an effect that can be avoided.

According to the RFID label producing apparatus of claim 9 , in addition to the effect produced by the RFID label producing apparatus of claim 6, sheet material reversing means for reversing the front and back of the sheet material, and the mounting position stored in the storage means Position information conversion means for converting the information into position information corresponding to the back surface of the sheet material, and the control means performs printing based on the print information stored in the storage means, and then the sheet material reversing means performs sheet printing. The wireless tag is attached to the sheet material on the basis of the attachment position information converted by the position information conversion means, then the sheet material is inverted by the sheet material inversion means, and the cutting position information stored in the storage means is obtained. Since the sheet material is controlled to be cut based on this, printing can be performed on one surface of the sheet material, and the wireless tag can be attached to the surface opposite to the printed surface. For this reason, there is an effect that the aesthetics and design of the printed surface are not lowered by the attachment of the wireless tag.

According to the control program for the RFID label producing apparatus according to claim 10, the attachment position information indicating the position of the wireless tag attached to the sheet material by the RFID tag attaching means and the cutting position indicating the cutting position where the cutting means cuts the sheet material. Based on the information, a detection step for detecting whether the position of the wireless tag to be pasted on the sheet material and the cutting position for cutting the sheet material overlap, and the detection step detects that the wireless tag and the cutting position overlap. In order to prevent the wireless tag and the cutting position from overlapping, the position information change processing step for changing the cutting position information or the mounting position information is provided, so the wireless tag mounting position information and the cutting position information information are created. Prevents the attached RFID tag from being accidentally disconnected when it is used or when the RFID label producing device inputs this information. There is an effect that it is possible to change the position information so that.

According to claim 11 the RFID label producing apparatus control program according, in addition to the effects of claim 10 RFID label producing device control program according, the cutting position information is composed of information indicating a line to cut the sheet material The position information change processing step changes the cutting position information by deleting the line where the wireless tag and the cutting line overlap from the line indicated by the cutting position information. There is an effect that cutting by mistake can be avoided.

According to the RFID label producing apparatus control program of claim 12, in the RFID label producing apparatus control program according to claim 10 , the cutting position information is constituted by information indicating a line for cutting a sheet material, and the position In the information change processing step, the line indicated by the cutting position information is not overlapped with the wireless tag but is changed to a line surrounding the wireless tag, so that the wireless tag is cut along the periphery of the wireless tag without being cut. There is an effect that can be.

The wireless tag label producing apparatus control program according to claim 13 includes attachment position information indicating a position of the wireless tag attached to the sheet material by the wireless tag attachment means, and cutting position information indicating a cutting position where the cutting means cuts the sheet material. Based on the detection step of detecting whether the position of the wireless tag to be mounted on the sheet material and the cutting position for cutting the sheet material overlap, and when the detection step detects that the wireless tag and the cutting position overlap Since the display step for displaying that the wireless tag and the cutting position overlap with each other is provided, there is an effect that the user can take measures to prevent the wireless tag from being cut.

  Hereinafter, a first preferred embodiment of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a perspective view showing an overview of a wireless tag mounting apparatus 1 according to an embodiment of the present invention. The wireless tag attaching device 1 is configured to perform printing on the printing paper P, attach (attach) the RFID tag T to the printing paper P, and further cut the printing paper P into a desired shape. Has been. As shown in FIG. 1, the wireless tag attaching device 1 includes a device main body 2 formed of a substantially box-shaped plastic. A printer operation button 6 for a user to give a print instruction and the operation panel display unit 5 for displaying an operation state and an operation procedure are provided on the upper right side of the apparatus main body 2 in front view. An insertion port 2a that is recessed toward the back is provided at the lower front side of the apparatus main body 2, and a paper feed tray 8 that stores printing paper P is inserted into the insertion port 2a. Yes.

  Both side walls 2c are erected from both ends in the width direction of the upper surface 2b of the insertion port 2a, and a rear wall 2d is connected to the rear ends of the both side walls 2c. The rear wall 2d is disposed on the front side of the back end of the insertion port 2a, and a gap is formed between the lower end of the rear wall 2d and the upper surface 2b of the insertion port 2a. Yes. The gap serves as a discharge port 10 through which the printing paper P is discharged from the inside of the apparatus main body 2. In the vicinity of the discharge port 10 and on the back surface side of the rear wall 2 d, paper feed rollers 9 for conveying the printing paper P are disposed at a plurality of locations along the discharge port 10.

  Inside the apparatus main body 2, there is a paper feeding device 11 (see FIG. 5) that drives the paper feeding roller 9 and the like to convey the printing paper P from the inside of the paper feed tray 8 to the upper surface 2b of the insertion port 2a. Built in. When the paper feeding roller 9 is driven in the forward direction by the paper feeding device 11, the printing paper P is fed toward the front side while being sandwiched between the paper feeding roller 9 and the upper surface 2b of the insertion port 2a. It is discharged from the discharge port 10. On the other hand, when the paper feed roller 9 is driven in the reverse direction, the printing paper P set on the upper surface 2 b of the insertion port 2 a is drawn into the apparatus main body 2 from the discharge port 10. Note that the printing paper P is conveyed in a direction orthogonal to the width direction of the apparatus main body by the operation of the paper feed roller 9 and the paper feed device 11.

  As will be described later, the wireless tag attaching apparatus 1 is provided with a mechanism for reversing the front and back sides of the printing paper P, and performs printing and attaching the RFID tag T on the front surface, back surface, or both surfaces of the printing paper P. Can do.

  In addition, the wireless tag attaching device 1 includes a guide rod 7 which is installed on the front side of the rear wall 2d and above the upper surface 2b of the insertion port 2a along the width direction of the device body 2, and a guide rod 7 includes a head unit 3 detachably mounted, a carriage 15 on which the head unit 3 is mounted, an RFID adding device 4 and a cutting device 20 mounted on the carriage 15 together with the print head 3a.

  The carriage 15 is known in the width direction of the apparatus body 2 along the guide rod 7 by a belt 13 driven via a pulley by a head moving device 12 (see FIG. 5) having a carriage motor (CR motor). It is possible to move to A).

  The lower surface of the head unit 3 is disposed at a height facing the printing paper P sent out on the upper surface 2b of the insertion port 2a with a gap. A print head 3 a having a plurality of nozzles that discharge ink downward is formed on the lower surface of the head unit 3. The head unit 3 includes four detachable ink cartridges 3b (3b1 to 3b4) that store cyan, magenta, yellow, and black inks supplied to the print head 3a. Full color printing is executed by ejecting the cyan, magenta, yellow, and black inks from the print head 3a onto the printing paper P.

  The RFID adding device 4 is a device that attaches the RFID tag T to the printing paper P, writes information to the attached RFID tag T, and reads information from the attached RFID tag T. The cutting device 20 is a device capable of cutting a sheet material into a desired shape, and as disclosed in Patent Document 2, by moving the cutter 71 in a state where the cutter 71 is lowered on the sheet material, When the moved portion is cut and moved with the cutter 71 raised, the sheet material is configured not to be cut.

  The RFID adding device 4 and the cutting device 20 are mounted on the carriage 15 together with the head unit 3, so that they can move in the width direction of the device main body 2. Thus, the RFID tag attaching apparatus 1 can move the RFID attaching apparatus 4 in the width direction of the apparatus main body 2 without providing the driving apparatus for driving the RFID attaching apparatus 4 and the cutting apparatus 20 separately. It has become. Therefore, the RFID tag attaching apparatus 1 can attach the RFID tag T to an arbitrary position of the printing paper P, and can cut the printing paper P into an arbitrary shape. Therefore, compared with a case where attachment and cutting of the wireless tag to the sheet material are performed by separate apparatuses, the printed matter to which the wireless tag is attached can be cut efficiently. Furthermore, compared with the case where attachment and cutting of a wireless tag are performed by separate devices, it is possible to reduce the risk of mistaken combination of the wireless tag to be attached and the cutting shape. In particular, when performing cutting in association with the position where the wireless tag is attached, it is easier to align the wireless tag to the target mounting position than when attaching and cutting the wireless tag with separate devices. As a result, the mounting accuracy and cutting accuracy can be improved.

  FIG. 2 is a diagram showing the internal structure of the RFID adding device 4. The RFID attachment device 4 includes a label tape 50, an RFID sticking device 40 for attaching the RFID tag T held by the label tape 50 to the printing paper P, and a label feeding device for transporting the label tape 50 inside the case body 4a. 43 (see FIG. 5), an RFID reader / writer 45 for reading information written to the RFID tag T and writing information to the RFID tag T, a winding roll 47 driven by the label feeding device 43, An unwinding roll 48 and a label feeding roll 49 are provided. The case body 4a is a replaceable cartridge. When the label tape 50 is consumed, the case body 4a can be replaced with a new one, and can be replaced with a different type of label tape 50.

  The RFID tag T is a wireless IC tag (Radio Frequency Idetification, RFID), and includes an IC chip of 1 square millimeter or less and a built-in antenna. The IC chip is equipped with a ROM that is a nonvolatile memory, a RAM that is a memory for temporarily storing information, and a rewritable nonvolatile memory that holds information in a nonvolatile manner. be able to.

  Information stored in the memory of the RFID tag T can be output to the RFID reader / writer 45 via a built-in antenna. Furthermore, the information stored in the memory can be rewritten by the information received by the built-in antenna. Further, the RFID tag T is configured to generate a current by a mechanism such as electromagnetic induction when receiving a radio wave from the RFID reader / writer 45, and operates with the generated current as driving power, thus eliminating the need for a battery. .

  Further, the RFID tag T is configured such that the stored information is read out by a reader for a wireless tag other than the RFID reader / writer 45, and a reader of the printing paper P can read the reader for the wireless tag. Thus, information can be acquired from the RFID tag T attached to the printing paper P.

  Also in the wireless tag attaching apparatus 1, the information stored in the RFID tag T can be read by the RFID reader / writer 45, and the information of the RFID tag T read by the RFID reader / writer 45 is manipulated. It is displayed on the panel display unit 5.

  A drilling port 4a1 that communicates the inside and the outside of the case body 4a is formed at a substantially central portion of the bottom surface of the case body 4a. The RFID sticking device 40 is arranged at a position facing the drilling port 4a1. It is installed. The perforation port 4a1 is formed on the transport path of the label tape 50, and the RFID sticking device 40 places the RFID tag T of the label tape 50 transported on the perforation port 4a1 from the perforation port 4a1 into the case. Extrude outside the body 4a.

  The label tape 50 is obtained by fixing a plurality of RFID tags T to a belt-like base material at predetermined intervals, and is attached to the unwinding roll 48 in a state of being wound around a roll core with the RFID tag T inside. . The unwinding roll 48 is a roll for unwinding (sending out) the label tape 50. A take-up roll 47 for taking up the label tape 50 is provided downstream of the unwind roll 48 in the conveying direction indicated by an arrow A in the drawing. The take-up roll 47 is provided with a detachable roll core to which the leading end of the label tape 50 is fixed. The take-up roll 47 is rotated in the forward direction (clockwise in FIG. 2) by the label feeding device 43. As a result, the label tape 50 is wound around the roll core. Since the RFID tag T is attached to the printing paper P at the perforation opening 4a1 by the RFID sticking device 40, the label tape 50 without the RFID tag T is wound around the winding roll 47.

  The label feed roll 49 is formed of a rubber roll whose outer peripheral surface is in contact with the bottom surface of the case body 4a, and in the vicinity of the drilling port 4a1, a first roll 49a disposed upstream of the drilling port 4a1, And a second roll 49b disposed on the downstream side of the opening 4a1. By the first roll 49a and the second roll 49b, the label tape 50 is regulated in a state in which the label tape 50 is prevented from being lifted in the vicinity of the perforation opening 4a1, and is conveyed on the bottom surface of the case body 4a. Note that the tension applied to the label tape 50 is adjusted by the take-up roll 47, the unwind roll 48, and the label feed roll 49, and the label tape 50 is conveyed in the vicinity of the perforation port 4a1 without being slackened. . Further, the unwinding roll 48 and the label feeding roll 49 may be configured to rotate following the driving of the winding roll 47, and each is configured to be driven by the label feeding device 43. May be.

  The RFID reader / writer 45 is provided adjacent to the rear side of the RFID sticking device 40 (upstream side with respect to the transport direction of the label tape 50) and incorporates an antenna 46. The RFID reader / writer 45 generally transmits / receives information to / from the RFID tag T via the antenna 46, reads information stored in the RFID tag T, and writes information to the RFID tag T. Device. A shield plate 44 that shields radio waves from the RFID reader / writer 45 is provided in the case body 40 in the vicinity of the RFID reader / writer 45. Inside the case body 40, a radio wave receiving area capable of receiving radio waves from the RFID reader / writer 45 is formed on the downstream side of the position where the shield plate 44 is disposed, and on the upstream side of the position where the shield plate 44 is disposed. A non-reception area in which radio waves from the RFID reader / writer 45 are not received is formed. Further, only one RFID tag T to be attached next is arranged on the downstream side (radio wave receiving area) from the position where the shield plate 44 is arranged.

  The writing of information to the RFID tag T by the RFID reader / writer 45 continues after the RFID tag T is attached to the printing paper P and the rolls 47 to 49 are stopped when there is an attachment operation. Executed. For this reason, the information (radio wave) transmitted from the RFID reader / writer 45 is received by one RFID tag T attached to the printing paper P and received by another RFID tag T inside the case body 40. There is no.

  FIG. 3 is a diagram showing the configuration of the label tape 50 in detail. 3A is a top view of the label tape 50, and FIG. 3B is a cross-sectional view. In both FIG. 3A and FIG. 3B, the label tape 50 is shown in an unfolded state. As shown in FIGS. 3A and 3B, the label tape 50 is formed by periodically arranging RFID tags T formed in a square shape in a top view on a band-shaped base material. Are arranged in a line along the longitudinal direction of the label tape 50. The band-shaped substrate has a three-layer structure formed by bonding separators 51 (inner separator 51 and outer separator 52) on both surfaces of an adhesive tape 52 having adhesiveness on both surfaces.

  The inner separator 51a is a separator disposed on the inner peripheral side when the label tape 50 is wound in a roll shape, and prevents the label tape 50 wound in a roll shape from blocking each other. Is. In the inner separator 51a, a substantially square punching window 54a is formed in advance at a predetermined interval by punching, and the adhesive tape 52 is exposed from the punching window 54a. Each punching window 54a is formed with the same size, and is formed to be larger than the outer dimension of the RFID tag T both vertically and horizontally with reference to the size of the RFID tag T. The RFID tag T is disposed in a punching window 54 a provided in the inner separator 51 a and is fixed by the adhesive force of the adhesive tape 52.

  The outer separator 51b is a separator provided to prevent the label tape 50 from adhering to the bottom surface of the case body 40 when the label tape 50 is conveyed. A punching window 54b similar to the punching window 54a provided in the inner separator 51a is also formed on the outer separator 51b, and the adhesive tape 52 is exposed from the punching window 54b. Each punching window 54b is formed at the same position in the cross-sectional direction as the punching window 54a. The adhesive tape 52 has a perforation 53 for drawing the same shape as the punching window 54a (punching window 54b) at the same position in the cross-sectional direction as the punching window 54a (punching window 54b).

  In this embodiment, when the RFID tag T is attached, a cut portion for separating the RFID tag T from the label tape 50 is formed at the perforation 53, but the cut portion is formed by a half cut. Also good. Further, although the perforation 53 is formed in a substantially square shape, R may be provided at four corners in order to improve punchability. Further, when the RFID sticking device 40 is provided with a Thomson blade or the like for punching the label tape 50 into a predetermined shape, the perforation 53 may not be formed.

  In addition, as the label tape, an RFID tag T in which an adhesive layer is formed on both sides may be temporarily fixed to a tape base material (separator) with one adhesive layer. According to the label tape having such a configuration, after attaching the RFID tag T to the printing paper P with the adhesive layer formed on the side opposite to the separator side by pressing the RFID tag T to the printing paper P from the back side of the separator, The RFID tag T can be attached by peeling the RFID tag T from the separator by winding the separator. When the adhesive force of the RFID tag T to the separator is relatively stronger than the adhesive force to the printing paper P, it is difficult to peel off the RFID tag T from the separator. It is more preferable to separate the RFID tag T from the label tape 50.

  FIG. 4 is a diagram showing an operation of attaching the RFID tag T by the RFID attaching device 40. The RFID sticking device 40 includes a casing 40a that forms the outer shape of the RFID sticking device 40, and an extruding portion 40b that is formed in a cylindrical shape. The extruding portion 40b is held inside the casing 40a so as to be slidable in the axial direction of the cylinder, while the axial direction of the cylinder coincides with the vertical direction (the cross-sectional direction of the label tape 50). The extruded portion 40b is housed in the casing 40a in a state where one end portion along the axial direction of the cylinder protrudes from the bottom surface side of the casing 40a, and the end surface on the side protruding from the casing 40a has a case It faces the drilling port 4a1 of the body 4a.

  When the RFID tag T is pasted, the RFID tag T is set on the upper surface of the piercing port 4a1 provided in the case body 4a by driving the label feeding device 43 described above. Accordingly, the pushing portion 40b (the end face thereof) facing the perforation opening 4a1 and the RFID tag T are in a positional relationship facing each other (FIG. 4 (a)).

  In a state where the RFID tag T is positioned on the upper surface of the opening 4a1, the pushing portion 40b slides downward from the solenoid, which is not shown and described, that is, toward the label tape 50. Here, the label tape 50 is disposed in a state where the outer separator 51b is the case body 4a side, the adhesive tape 52 is disposed above the outer separator 51b, and the RFID tag T is laminated above the adhesive tape 52. The diameter of the extruding portion 40b is formed smaller than the inner dimension of the punching window 54a (punching window 54b), and the drilling port 4a1 of the case body 4a is formed larger than the punching window 54a (punching window 54b). Yes. For this reason, the pushing portion 40b slides downward while abutting on the upper surface of the RFID tag T by sliding operation (FIG. 4B), passing through the punching window 54a, and pushing the RFID tag T. . By pressing the RFID tag T, the adhesive tape 52 is torn at the perforation 53, and one RFID tag T is separated from the label tape 50. The RFID tag T separated from the label tape 50 is pressure-bonded to the printing paper P set on the upper surface 2b of the insertion port 2a by the extruding portion 40b for a predetermined time, and is fixed to the printing paper P by the adhesive force of the adhesive tape 52. (FIG. 4C). Thereafter, the extruding portion 40b is slid in the anti-extrusion direction and stored in the casing 40a (FIG. 4D). Thereby, the operation of attaching the RFID tag T is completed.

  After the pasting operation is completed, information is written by the RFID reader / writer 45, and then the printing paper P and the label tape 50 are transported. As a result, a new RFID tag T is set on the upper surface of the opening 4a1 of the case body 4a.

  FIG. 5 is a block diagram showing an outline of an electric circuit configuration of the wireless tag attaching device 1. As shown in FIG. 5, the control device for controlling the wireless tag attaching device 1 is a non-rewritable nonvolatile memory that stores a CPU 32 that is an arithmetic device and various control programs executed by the CPU 32 and fixed value data. A ROM 33 that is a memory of the above, and a RAM 34 that is a memory for temporarily storing various data and the like. A flowchart program to be described later is stored in the ROM 33 as a part of the control program.

  The CPU 32 generates a print timing signal and a reset signal, and transfers each signal to the inkjet head device 36 described later. The CPU 32 is connected to the RFID adding device 4, the operation panel display unit 5, the printer operation button 6, the paper feeding device 11, the head moving device 12, the cutting device 20, the input interface 35, and the like. Transmits and receives control data and the like. Further, the wireless tag attaching apparatus 1 is provided with sensors (not shown) such as a paper sensor for detecting the leading edge of the printing paper P and an origin sensor for detecting the origin position of the carriage, and these sensors are also connected to the CPU 32. Has been.

  The RAM 34 includes an RFID information memory 34a, a print information memory 34b, a cut information memory 34c, and a cut flag 34d. The RFID information memory 34a, the print information memory 34b, and the cut information memory 34c are memories that store the RFID information 60a, the print information 60b, and the cut information 60c received from the personal computer PC 100 via the interface 35, respectively.

  The RFID information memory 34 a stores RFID information 60 a that is information related to the RFID tag T attached to the printing paper P by the wireless tag attaching device 1. The RFID information 60a is information prepared for each RFID tag T to be attached, and is composed of two types of information, write information written to the RFID tag T and attachment position information indicating the attachment position of the RFID tag T. (See FIG. 6).

  The write information is information that is written (stored) in the RFID tag T by the RFID reader / writer 45. The write information written in the RFID tag T is stored in a rewritable nonvolatile memory in the RFID tag T and held as information that can be read from the RFID tag T. In the present embodiment, the object to which the RFID tag T is attached is the printing paper P, and the RFID tag T stores information related to the print display printed on the printing paper P. The write information has information related to the print display. When the write information is written by the RFID reader / writer 45, the RFID tag T holds information related to the print display. .

  The attachment position information is coordinate data indicating a point on the paper surface of the print paper P, and X coordinate data indicating a position in the width direction of the print paper P, and a direction (conveying direction) orthogonal to the width direction of the print paper P. Y coordinate data indicating the position of When attaching the RFID tag T, the wireless tag attaching device 1 moves the RFID attaching device 4 in the width direction of the printing paper P based on the X coordinate data stored in the RFID information memory 34a (by the carriage 15). The positioning of the RFID tag T is performed in the width direction on the paper surface of the printing paper P. Further, by positioning the printing paper P in the direction perpendicular to the width direction based on the Y coordinate data stored in the RFID information memory 34a, the positioning of the RFID tag T on the paper surface of the printing paper P is determined. It is carried out. Since the CPU 32 controls the attachment so that the RFID tag T is attached to the printing paper P based on the attachment position information, the RFID tag T is attached to the printing paper P of one page by the number of the attachment position information. Is done.

  The print information memory 34b is a memory for storing the print information 60b transmitted from the PC 100. The print information 60b is composed of image information (print data) representing graphics and characters to be printed on the print paper P, and various information necessary for execution of printing. This print information memory is used for print processing to be described later. The print information 60b stored in 34b is transmitted to the inkjet head device 36.

  The cut information memory 34c is a memory for storing the cut information 60c transmitted from the PC 100. The cut information 60c is information for controlling the cutting device 20, and the data type includes data indicating the coordinates (X, Y) of the movement destination of the cutter 71, data for instructing to lower the cutter 71, And data for instructing to raise the cutter 71.

  Data indicating the coordinates of the movement destination of the cutter 71 is data for instructing to move the cutter 71 to the coordinates on the paper surface of the printing paper P, and X-coordinate data indicating the position in the width direction of the printing paper P; Y coordinate data indicating a position in the direction (conveyance direction) orthogonal to the width direction on the printing paper P. The CPU 32 moves the cutter 71 in the width direction of the printing paper P based on the X coordinate data (by the carriage 15), thereby positioning the cutter 71 in the width direction on the paper surface of the printing paper P. Further, the cutter 71 is positioned with respect to the conveyance direction on the paper surface of the printing paper P by conveying the printing paper P in the direction orthogonal to the width direction based on the Y coordinate data. When the printing paper P or the carriage 15 is moved with the cutter 71 lowered, the locus is cut, and the cut line segment is called a cut line (cut line).

  When the wireless tag attaching apparatus 1 receives control data 60 from the PC 100 via the input interface 35, the wireless tag attaching apparatus 1 receives information by interrupt processing, and temporarily stores the received information in a reception buffer area (not shown) of the RAM 34. Is configured to do. When the CPU 32 recognizes that reception information is stored in the reception buffer area of the RAM 34, the RFID information 60a, the print information 60b, and the cut information 60c for one page are converted into the RFID information at a predetermined timing. The data is written in the memory 34a, the print information memory 34b, and the cut information memory 34c, respectively.

  The cut flag 34d is a flag used when detecting whether or not the attached RFID tag T and the cut line overlap. This cut flag is turned on when a command for lowering the cutter 71 is read, and this cut flag is set off when a command for raising the cutter 71 is read. When the cutter 71 is moved while the cutter 71 is lowered, the printing paper P is cut. Therefore, when the cut flag indicating the state where the cutter 71 is lowered is on, the locus to which the cutter 71 is moved and the attached RFID The coordinates of the tag T are referred to, and it is determined whether there is a fear that the cutter 71 cuts the RFID tag T.

  The interface 35 is an interface that receives control data transmitted from a personal computer PC100 or the like connected to the outside, and uses standards such as USB (Universal Serial Bus) and Centronics.

  The paper feeding device 11 includes a conveyance motor (LF motor) that drives each roller such as the paper feeding roller 9 to convey the printing paper P, and an LF motor driving circuit for operating the LF motor. Is a device that carries the printing paper P based on the instruction.

  The head moving device 12 includes a CR motor for operating the carriage 15 and a CR motor driving circuit for driving the CR motor. Based on an instruction from the CPU 32, the head moving device 12 is connected to the printing paper P It is a device for moving to a predetermined point.

  The head unit 3 is a device that ejects ink for forming characters and images on the printing paper P based on an instruction from the CPU 32. The head unit 3 includes a control circuit (not shown) and is synchronized with the movement timing of the head moving device 12. Then, ink is ejected from a head that ejects ink of each color.

  The RFID sticking device 40 provided in the RFID adding device 4 is controlled by the CPU 32 according to the operation timing of the paper feeding device 11 and the head moving device 12. Specifically, in order to attach the RFID tag T, when a predetermined point of the printing paper P to which the RFID tag T is attached is set at a position facing the RFID sticking device 40, that is, the paper feeding device 11 and the head moving device 12. The attachment operation by the RFID sticking device 40 is instructed at the timing when the conveyance of the printing paper P is completed. When the RFID tag T sticking operation is finished, the CPU 32 instructs the RFID reader / writer 45 to send the write information to the RFID tag T. Upon completion of the sending operation, the label feeding device 43 is notified of the label tape. 50 winding operations are instructed.

  The cutting device 20 is a device that is controlled by the CPU 32 based on the cut information 60c stored in the cut information memory 34c of the RAM 34 and cuts the printing paper P into a predetermined shape. The cutter 71 is raised and lowered with respect to the printing paper P. An actuator is provided.

  FIG. 16 is a cross-sectional view of the tip of a cutter member driven by an actuator. The cutter member has a cutter 71 having a cutting edge 71a for cutting the printing paper P, and a rod-shaped cutter mounting portion 74 for mounting the cutter 71. And a cutter holder 73 that holds the cutter mounting portion 74. The cutter 71 is attached to one end of the cutter attachment portion 74 with a screw 75. The other end of the cutter mounting portion 74 is inserted into an inner ring of a bearing 76 that forms a shaft and is mounted in an opening of a recess 77 provided at the lower end of the cutter holder 73, and the upper end is formed in a conical shape. The tip is in contact with the bottom surface of the recess 77 so as to freely rotate.

  Since the cutting edge 71a of the cutter 71 has an offset a with respect to the rotating shaft 72 of the cutter mounting portion 74, when the cutter holder 73 moves, the cutter 71 receives resistance from the printing paper P and always has the least resistance. Thus, torque acts on the cutter 71 so that the cutter 71 is rotated in a direction parallel to the traveling direction of the cutter holder 73 and can cut the sheet material.

  When control data “raise the cutter” or “lower the cutter” is input from the CPU 32, the actuator operates to move the cutter 71 up and down. When the cutter 71 or the printing paper P is moved with the cutter 71 lowered, the printed paper P of the moved line segment is cut. Even if the cutter 71 or the printing paper P is moved with the cutter 71 raised, The printing paper P is not cut.

  When the RFID tag T is attached to the printing paper P based on the RFID information 60a and then the printing paper P is cut based on the cut information 60c, there is a fear that the RFID tag T is cut by mistake. Therefore, in order to avoid cutting the attached RFID tag T, when the RFID information 60a and the cut information 60c are received from the PC 100, the cutting is performed based on the RFID tag T attached based on the RFID information 60a and the cut information 60c. Detect whether the cut line overlaps. When the RFID tag T and the cut line overlap with each other, the attachment position information of the RFID information 60a or the cut information 60c is changed to display on the display means that the RFID tag T may be cut. Details will be described later.

  The operation panel display unit 5 displays various parameters. In particular, when the RFID information 60a and the cut information 60c are input, if the RFID tag T attached based on the RFID information 60a is likely to be cut by the cutting device 20 based on the cut information 60c, the CPU 32 Thus, a warning is displayed on the operation panel display unit 5 to notify the user.

  The printer operation button 6 is operated by the user, and as described above, on which side of the printing paper P the processing such as printing is set, or the printing paper P is discharged manually. It is operated when instructing, and the operated state is detected by the CPU 32.

  FIG. 6 is a diagram showing a table 60 that schematically displays the contents transmitted from the PC 100 and stored in the RFID information memory 34a, the print information memory 34b, and the cut information memory 34c of the RAM 34. A data group corresponding to one print sheet P is transmitted as one unit from the PC 100, and the CPU 32 transmits the RFID information memory 34a, the print information memory 34b, and the cut information of the RAM 34 for each unit of data group. Information is written to the memory 34c.

  The table 60 includes RFID information 60a written in the RFID information memory 34a, print information 60b written in the print information memory 34b, and cut information 60c written in the cut information memory 34c. It is shown.

  The RFID information 60a is composed of two types of data, that is, attachment position information and writing information. In each RFID information 60a, one attachment position information and one writing information are associated with each other. The attachment position information is coordinate data composed of X coordinate data and Y coordinate data, and is represented by coordinates (X, Y) with respect to the printing paper P. The table 60 displays three coordinate data, pasted coordinates (X1, Y1), pasted coordinates (X2, Y2), pasted coordinates (X3, Y3), and three RFID tags T corresponding to each coordinate data. Attaching is specified. Each coordinate data is associated with write information 1, write information 2, and write information 3, respectively. For this reason, the corresponding write information is written in the RFID tag T attached to the point indicated by each coordinate data.

  The writing information is information related to the print display. In the PC 100, the attachment position information is determined so that the RFID tag T is attached to the display position (near) of the print display corresponding to the write information. The writing information and the attachment position information are registered in association with each other. Thereby, consistency is given to the print display, the attachment position of the RFID tag T, and the information held by the RFID tag T.

  When the information related to the print display held in the RFID tag T corresponds to a part of the print display printed on the printing paper P, it indicates which part of the print display corresponds to the information. Although necessary, the content of the stored information cannot be determined from the appearance of the RFID tag T. For this reason, in this embodiment, by attaching the RFID tag T to the print display portion corresponding to the information held by the RFID tag T, the print display portion (print contents), the attachment position of the RFID tag T, Since the information stored in the RFID tag T is consistent, information related to the print display displayed in the vicinity of the RFID tag T can be acquired from the RFID tag T attached to the printing paper P. is there. In other words, the user can sensuously grasp which part of the printed display corresponds to the information stored in the attached RFID tag T (content of information stored in the RFID tag T). It is like that.

  The print information 60b is composed of two types of data, header information and image information. The header information is data indicating various settings necessary for printing, and includes “print data height” and “print data”. , “Print data resolution (X direction)”, “print data resolution (Y direction)”, “number of print passes”, and “print direction”. The CPU 32 executes the printing of the image information (print data) stored in the print information memory 34b based on the header information stored in the print information memory 34b (instructs the inkjet head device 36).

  Further, the image information of one page of the print information 60b is formed by a line print data group divided for each print line of the first to nth rows, and each line print data indicates a print size. Print size data and print data corresponding to an image to be printed are provided. The print size data is composed of four types of data: cyan data size, magenta data size, yellow data size, and black data size. The print data is also composed of four types of data, cyan data, magenta data, yellow data, and black data, and is data corresponding to full color printing.

  As described above, the cut information 60c includes data indicating the coordinates of the movement destination of the cutter 71, a command for instructing to raise the cutter 71, and a command for instructing to lower the cutter 71. The CPU 32 sequentially reads out these data and performs processing to cut the printing paper P into a desired shape. In the case of a “raise cutter” or “lower cutter” command, control data is sent to the cutting device 20 to raise or lower the cutter 71, and data indicating the coordinates (X, Y) of the movement destination of the cutter 71 In this case, the upper and lower states of the cutter 71 are left as they are, and the head moving device 12 is controlled according to the X coordinate, and the paper feeding device 11 is controlled according to the Y coordinate.

  Note that the PC 100 does not necessarily transmit the RFID information 60a, the print information 60b, and the cut information 60c as a data group corresponding to one print sheet P, and the data group corresponding to a desired process. Information is sent. For example, when it is desired that the RFID tag attaching apparatus 1 execute only the application of the RFID tag T and the cutting of a desired shape, only the RFID information 60a and the cut information 60c are transmitted. Further, in the wireless tag attaching apparatus 1, when it is desired to execute only writing information to the RFID tag T, prohibition data instructing prohibition of printing and attachment is transmitted from the PC together with the RFID information 60a, The prohibition data is written in the RFID information memory 34a together with the RFID information 60a. In such a case, the coordinate data (mounting position information) becomes writing position information indicating the writing position of the information.

  FIG. 7 shows a sample created by using the wireless tag attaching apparatus 1. FIG. 7A shows a case in which two stars are printed, the periphery is cut out in a rectangle, and the RFID tag T is placed in the left corner of the rectangle. It is attached. In (b), a star-shaped figure is printed, an RFID tag T is attached to the center of the figure, and the star-shaped figure is cut out along the outer periphery of the printed star-shaped figure. (C) prints a map (showing Aichi Prefecture in this figure), an RFID tag T is attached to a predetermined location of the map, and is cut out along the outline of the map. For example, an RFID tag T is attached to a place that hits a landmark, the guidance of the spot is stored in the RFID tag T by letters or voice, and a guidance corresponding to the position is displayed by holding a reader over the position, Can be reproduced. As shown in these samples, by using the wireless tag attaching apparatus 1, printing is performed on the printing paper P, the RFID tag T is attached at a location corresponding to the position of the printing content, and the printing paper P is further printed. It can be cut into a shape according to.

  Next, the printing process executed in the wireless tag attaching apparatus 1 configured as described above will be described with reference to the flowcharts shown in FIGS. FIG. 8 is a flowchart of the printing process executed by the CPU 32. This printing process is a process executed when the RFID information 60a, the printing information 60b, or the cut information 60c is received.

  First, RFID information 60a, print information 60b, and cut information 60c for one page to be processed are stored in the RFID information memory 34a, the print information memory 34b, and the cut information memory 34c, which are areas allocated to the RAM 34 (S1). ). Next, it is checked whether or not the RFID tag T to be attached and the cut line overlap based on the stored RFID information 60a and cut information 60c. If they overlap, an overlapping process is performed (S2). That is, it is a process for determining whether the cutting device is likely to be damaged by cutting the RFID tag T to be attached, and details will be described later.

  Next, it is confirmed whether or not the print information 60b is stored in the print information memory 34b (S3). If the print information 60b is stored in the print information memory 34b (S3: Yes), the print information is displayed. The printing process is executed based on 60b (S4). In this process, data for each color for each line of print data is transmitted to the print head unit, and the paper feed device 11 is controlled to sequentially convey the print paper P, and the head moving device is controlled to move the print head. This is a process for executing printing.

  When printing for one page is completed, it is next determined whether or not the RFID information 60a is stored in the RFID information memory 34a of the RAM 34 (S5). When the RFID information 60a is stored (S5: Yes), the RFID tag pasting process which is a subroutine described later is performed (S6). When the RFID information 60a is not stored (S5: No), the RFID tag T When the pasting process is completed, it is determined whether or not the cut information 60c is stored in the cut information memory 34c of the RAM 34 (S7). When 60c is stored (S7: Yes), a cutting process, which is a subroutine described later, is performed (S8). When 60c is not stored (S7: No) and when the cutting process is completed, printing is performed. The paper P is discharged (S9), and this routine ends.

  FIG. 9 is a flowchart showing RFID tag attachment processing which is a subroutine. In this process, first, the pointer is set to the smallest address in the RFID information memory 34a (S11). Next, the Y coordinate of the attachment position information stored at the address indicated by the pointer is read (S12), and the paper feeding device 11 is driven so that the Y coordinate of the attachment position of the printing paper P is located at the Y coordinate of the attachment position information. (S13).

  Next, the X coordinate of the mounting position information stored at the address indicated by the pointer is read (S14), the head moving device 12 is driven, and the X coordinate of the RFID sticking device 40 is located at the X coordinate of the mounting position information. (S15). When the position setting of the X coordinate and the Y coordinate is completed, the RFID sticking device 40 is driven at that position, and control is performed to attach the RFID tag T (S16).

  Next, it moves to the position of the RFID tag T to which the RFID reader / writer is affixed, and is stored in the address indicated by the pointer, and the writing information corresponding to this attachment position is output from the RFID reader / writer (S17). . When this writing process is completed, the pointer is advanced to the next data (S18), and it is determined whether unprocessed RFID information 60a is stored at the address indicated by the pointer (S19). When the unprocessed RFID information 60a exists (S19: Yes), the process returns to S12, and when the unprocessed RFID information 60a does not exist (S19: No), this process ends.

  FIG. 10 is a flowchart showing a cutting process which is a subroutine. In this process, first, the pointer is set to the smallest address in the cut information memory 34c (S21). Next, the type of the cut information 60c stored at the address indicated by the pointer is determined (S22). If the type of the cut information 60c is a “raise cutter” command, control data for instructing to raise the cutter is transmitted to the cutting device 20 (S23), and if it is a “lower cutter” command, Control data instructing to raise 71 is transmitted to the cutting device 20 (S24).

  When the type of the cut information 60c is data instructing the movement of the cutter 71, the paper feeding device 11 and the head moving device 12 are controlled according to the coordinates (X, Y) indicating the movement destination (S25). When the movement process of the cutter 71 (S25), the process of raising the cutter 71 (S23), or the process of lowering the cutter 71 (S24) is completed, the pointer is advanced to the address of the next cut information 60c (S26), and the unprocessed It is determined whether or not the cut information 60c exists (S27). If there is unprocessed cut information 60c (S27: Yes), the process returns to S22. If there is no unprocessed cut information 60c (S27: No), this process ends.

  As described above, according to the wireless tag attaching apparatus 1 of the present embodiment, printing and attaching and cutting of the RFID tag T can be executed by one apparatus, and the RFID tag T is arranged in the width direction of the printing paper P. Can also be attached at any position in the direction (conveying direction) perpendicular to the width direction. Therefore, it is possible to easily create a printed matter having a shape in which the print display, the information held by the RFID tag T, the attachment position of the RFID tag T, and the cutting information are associated with each other. In addition, since it is not necessary to execute printing and attaching and cutting of the RFID tag T in separate apparatuses, it is possible to efficiently produce a printed matter having a desired shape to which the RFID tag T is attached, as well as printing display and the RFID tag. An error in combination with T can be reduced, and the RFID tag T can be accurately attached to a predetermined mounting position for print display.

  In the above embodiment, the RFID tag T is attached after the printing process is executed. However, the RFID tag T may be attached before printing. According to this, printing is performed on the RFID tag T, and the printed display is not covered by the RFID tag T.

  Next, an overlapping process between the RFID tag T and the cut line will be described. When the RFID tag T is attached to an arbitrary position of the printing paper P and then the printing paper P is cut into an arbitrary shape, there is a fear that the RFID tag T is cut by mistake.

  FIG. 11 is a diagram schematically illustrating a processing method when the RFID tag T to be attached and the cut line overlap. Here, a case where the printing paper P to which the RFID tag T is attached is cut by a rectangular cut line indicated by a broken line. (A) shows a state where the upper side of the rectangular cut line and the RFID tag T overlap each other, and (b) shows a process of avoiding the overlap by moving the position of the RFID tag T. Here, a state in which the position of the RFID tag T is moved by Δ with respect to the coordinates of the center G of the rectangle (for example, the center of gravity of the figure to be cut) is shown. FIG. A mode that the outer periphery of the tag T moved to the position which corresponds with a cut line is shown.

  On the other hand, (c) and (d) show processing for avoiding the overlap between the RFID tag T and the cut line by changing the cut line, and (c) shows that the cut line is initially a line segment A. -B is a process in which the part to which the RFID tag T is attached is omitted, the line segment is changed to the line segment AC and the line segment DB, and the RFID tag T part is not cut. Yes. According to this process, the printing paper P is not continuously cut into a predetermined shape, but the RFID tag T is prevented from being cut.

  (D) shows that the cut line is initially a line segment A-B, a line segment A-C and lines that surround the outer shape of the RFID tag T, and C-E, EF, FD, and a line segment. This is a process of changing to DB. According to this process, the RFID tag T is not cut, and cut lines can be continuously formed.

  FIG. 12 is a flowchart for explaining processing for detecting whether or not the RFID tag T and the cutting position overlap. This process is executed when the wireless tag attaching apparatus 1 completes reception of control data for one page via the input interface 35.

  First, it is confirmed whether or not the RFID tag T information 60a and the cut information 60c exist in the received data (S31). If any of these data is not stored, there is no fear of cutting the RFID tag T, so this process ends (S31: No).

  If RFID information 60a and cut information 60c are present in the received data (S31: Yes), a pointer is set at the address of the first cut information 60c stored in the cut information memory 34c (S32). Next, it is confirmed whether the cut information 60c at the address indicated by the pointer is any of the data "raise the cutter", "lower the cutter", or "move the cutter" (S33).

  In the case of data “raise the cutter”, the cut flag 34d is turned off (S34), and in the case of data “lower the cutter”, the cut flag 34d is turned on (S35) and the process proceeds to S41. The cut flag 34d is a 1-bit memory provided at a predetermined address in the RAM, and is set to “1” when turned on and set to “0” when turned off.

  In the confirmation process of S33, if the data is “move the cutter”, it is confirmed whether or not the cut flag 34d at that time is ON (S36). When the cut flag 34d is off (S36: No), the process proceeds to S41. When the cut flag 34d is on (S36: Yes), the RFID information 60a is acquired from the RAM, the coordinates indicating the position of the RFID tag T to be attached are acquired based on the data, and the cut line indicated by the cut information 60c It is confirmed whether or not the RFID tag T overlaps (S38). In this confirmation process, for example, a mathematical expression representing the outline of the RFID tag T is stored in the ROM 33, and when the position to which the RFID tag T is attached is specified, the mathematical expression is converted into coordinates on the printing paper P and cut. This can be done by determining whether the mathematical expression representing the line has an intersection.

  If the cut line and the RFID tag T overlap (S38: Yes), an overlapping process such as changing the cutting position information or the mounting position information so as not to overlap is performed (S39). This overlapping process will be described later.

  Next, it is confirmed whether there is unprocessed RFID information 60a (S40). If there is unprocessed RFID information 60a (S40: Yes), the process returns to S38. The process proceeds (S41), and it is confirmed whether there is unprocessed cut information 60c (S42). When there is unprocessed cut information 60c, the process returns to the process of S32 (S42: Yes), and when there is no unprocessed cut information 60c (S42: No), this process ends and the process shown in FIG. Return.

  FIG. 13 is a flowchart for explaining the overlapping process when the cut line and the RFID tag T overlap. Here, three processing methods will be described.

  FIG. 13 (a) shows a process for changing the attachment position information indicating the attachment position of the RFID tag T. First, the coordinates G of the center of gravity of the figure formed by the cut line are obtained, and the coordinates of the RFID tag T are obtained. The position is moved in the G direction by Δ (for example, 1 mm) (S43). It is determined whether or not the cut line and the RFID tag T overlap at this coordinate position (S44). If they overlap (S44: Yes), move again by Δ, and if they do not overlap (S44: No), rewrite the RFID information 60a in the RAM 34 using the moved coordinates as the position to attach the RFID (S45). finish.

  FIG. 13B shows a process when changing the cut information 60c. For a line segment that overlaps the RFID tag T to which the line segment indicated by the cut information 60c is attached, first, the line segment indicated by the cut information 60c and Based on the coordinates of the position of the RFID tag T to be attached and the mathematical expression representing the outline of the RFID tag T, the coordinates of the intersection of the cut line and the outline of the RFID are obtained (S46). For example, in the case shown in FIG. 11 (c), coordinates C and D are intersections.

Next, the cut information 60c is changed from the coordinates of these intersections (S47). For example, in the case of the process shown in FIG. 11C, the original cut information 60c is
(1) “Move the cutter to coordinate A”
(2) “Lower the cutter”
(3) “Move cutter to coordinate B”.
this,
(1) “Move the cutter to coordinate A”
(2) “Lower the cutter”
(3) “Move the cutter to coordinate C”
(4) “Raise the cutter”
(5) “Move the cutter to coordinate D”
(6) “Lower the cutter”
(7) “Move the cutter to coordinate B”
Change to

  FIG. 13C shows a process in the case where the RFID tag 60a and the cut information 60c are not changed, and simply indicates that the cut line overlaps the wireless tag, and is provided in the display unit 5 of the printer operation panel. The display is displayed with characters indicating that there is a fear of cutting the RFID tag T (S48). Instead of displaying with characters, the LED may blink, or a warning may be issued by voice. In this state, when the user operates a button on the operation panel, the processing may be stopped, or only printing and RFID attachment may be performed and cutting may not be performed.

  As described above, in the wireless tag attaching apparatus 1 of the present invention, when the RFID information 60a and the cut information 60c are input, the RFID tag T to be attached based on the RFID information 60a is cut based on the cut information 60c. The RFID information 60a or the cut information 60c is changed so that there is no error, or the fact that the cut line and the RFID tag T overlap is displayed and notified to the user, so that the RFID tag is prevented from being cut. be able to.

  Next, a second embodiment will be described with reference to FIGS. 14 and 15. FIG. 14 is a cross-sectional view of the RFID tag attaching apparatus 1 according to the second embodiment, and is a view for explaining the conveyance operation of the printing paper P. FIG. 15 is executed in the RFID tag attaching apparatus 1 according to the second embodiment. 10 is a flowchart of print processing performed. In addition, the same code | symbol is attached | subjected to the part same as 1st Example, and the description is abbreviate | omitted.

  The wireless tag attaching device 1 of the second embodiment is configured by adding a reversing function for reversing the printing paper P to the wireless tag attaching device 1 of the first embodiment. As shown in FIG. 14, a reversing unit 90 is provided at the rear of the apparatus main body 2. In the second embodiment, during the printing process, either RFID attachment, printing, or cutting is executed on one side, and either the RFID sheet is attached, printed, or cut on the opposite side by reversing the front and back of the printing paper P. Is executed.

  FIG. 14 schematically shows a process in which the front and back sides of the printing paper P are reversed. The printing paper P set in the paper feeding tray 8 is pulled out from the paper feeding tray 8 by driving the paper feeding device 11. 14 (a) and 14 (b), guided by a guide roller (not shown) and a guide plate, and supplied to the internal paper feed roller 18. The printing paper P supplied to the internal paper feed roller 18 is pushed toward the front surface of the apparatus main body 2 in accordance with the drive of the internal paper feed roller 18. The extruded printing paper P passes through the paper sensor and is conveyed to the lower surface of the head unit 3, that is, the position facing the printing head 3a. Then, the print head 3a is operated while transporting the printing paper P to the front side of the apparatus main body 2, and printing on the printing paper P and attachment or cutting of the RFID tag are executed (FIG. 14C). When the processing on one side is completed, the paper feeding device 11 rotates the paper feeding roller 9 in the reverse direction and pulls the printing paper P sent onto the upper surface 2b of the insertion port 2a into the inside of the apparatus main body 2. (Fig. 14 (d)).

  The drawn printing paper P is guided so as to come into contact with the lower surface of the internal paper feed roller 18 and is fed toward the bottom surface of the apparatus main body 2 (FIG. 14E). Then, the printing paper P is introduced into the reversing unit 90 by being guided from a lower surface of the internal paper feed roller 18 to an introduction roller (not shown) arranged in a row toward an introduction port 92 provided below the reversing unit 90. The In the reversing unit 90, the printing paper P circulates around the outer periphery of the roller from the lower side of the reversing roller 91 and is sent to the upper side of the reversing roller 91, so that the front and back of the printing paper P are reversed. Then, the printing paper P is fed in an inverted state from the delivery port 93 provided on the upper side of the reversing unit 90 to the upper surface of the internal paper feed roller 18 (FIG. 14G), and the internal paper feed roller. By driving 18, the paper passes again through the paper sensor and is conveyed to a position facing the head unit 3 and the RFID adding device 4 (FIG. 14 (h)). Then, printing, RFID tag T pasting or cutting is performed on the opposite side of the printing paper P.

  Therefore, first, printing is performed on one side of the printing paper P, and then the front and back sides of the printing paper P are reversed and the RFID tag T is attached to the back side and cut, or printing is performed on one side of the printing paper P. Next, reverse the front and back of the printing paper P and attach the RFID tag T to the back, and then reverse the front and back again and cut, or first attach the RFID tag T to one side and then print the paper It is possible to perform processing such as inverting the front and back of P, printing on the back side, and cutting the back side.

  FIG. 15 is a flowchart showing the control when the RFID tag T is attached to one side, the front and back sides of the printing paper P are turned over, the back side of the side to which the RFID is attached is printed, and the side is cut. is there. First, the received RFID information 60a, print information 60b, and cut information 60c for one page are stored in areas assigned to the RAM 34 (S51). Next, it is determined whether or not the RFID information 60a is stored in the RFID memory 34a of the RAM 34 (S52). When the RFID information 60a is stored (S52: Yes), coordinate conversion is performed on all the RFID information 60a (S53). In this coordinate conversion, since the RFID tag T is attached to the back surface with respect to the printing surface, it is necessary to convert the coordinates to coordinates corresponding to the back surface. In this conversion, the X coordinate is left as it is, and the Y coordinate is set to a length obtained by subtracting the value of the Y coordinate from the length of the printing paper P in the vertical direction.

  After performing this conversion on all the RFID information 60a, the RFID tag T is pasted using the converted coordinates (S54). This attachment process is performed by a subroutine shown in FIG. When the RFID attachment process for one page is completed, the front and back sides of the printing paper P are reversed (S55), and it is determined whether the printing information 60b is stored in the printing information memory 34b of the RAM 34 (S56). When the print information 60b is stored (S56: Yes), the print process is performed (S57). When the print information 60b is not stored (S56: No) and when the print process is completed, It is determined whether or not the cut information 60c is stored in the cut information memory 34c of the RAM 34 (S58). If the cut information 60c is stored (S58: Yes), a cutting process is performed. (S59) This cutting process is performed by a subroutine shown in FIG. When the cut information 60c is not stored (S58: No) and when the cutting process is finished, the printing paper P is discharged (S60), and this process is finished.

  In this way, when printing and attaching and cutting the RFID tag T to the printing paper P, first the RFID tag T is attached and then the printing paper P is reversed and printing is performed on the opposite surface. It can be further cut. If the printing surface and the application surface of the RFID tag T are on the same surface of the printing paper P, if the RFID tag T is attached after printing, a part of the printed display is hidden by the attached RFID tag T, and printing is performed. This leads to a decrease in aesthetics and a decrease in print display discrimination. Further, if printing is performed after the RFID tag T is attached, printing is performed directly on the RFID tag T, which causes deterioration in print quality. However, such an inconvenience can be solved by attaching the RFID tag T to the surface opposite to the printing surface. Further, if the RFID tag T is attached prior to printing, the inside of the apparatus main body 2 is not moved in a state where the printing paper P is printed, so that contamination inside the apparatus main body 2 can be reduced, A decrease in print quality due to rubbing of the print surface can be suppressed.

  Conversely, printing can be performed first, and then the printing paper P can be reversed, and the RFID tag T can be attached to the surface opposite to the printing surface and cut. In this case, since the printing is performed before the RFID tag T is pasted, there is no concern that the printing is disturbed due to the unevenness generated by the pasting of the RFID tag T, and a printed matter with good print quality can be obtained. .

  The present invention has been described based on the embodiments. However, the present invention is not limited to the above-described embodiments, and various improvements and modifications can be easily made without departing from the spirit of the present invention. It can be guessed.

  For example, in the above embodiment, the carriage on which the inkjet head or the like is mounted is moved in the direction perpendicular to the sheet material feeding direction. However, the sheet material is fixed like a so-called XY plotter, and the carriage is moved to the sheet. You may enable it to move to the arbitrary positions of a material.

  In the above embodiment, the printing apparatus is an ink jet type, but may be a thermal type or a dot impact type.

  Further, in the above-described embodiment, it is detected whether or not the RFID tag T attached to the RFID sticking apparatus 40 and the cut line overlap, and if it overlaps, an overlapping process such as changing the attachment position information so as not to overlap is performed. However, this overlapping process may be executed when the RFID information 60a and the cut information 60c are created in a personal computer or the like.

  In the above embodiment, the RFID sticking device 40 is configured to attach the RFID tag T to the printing paper P by the adhesive force of the adhesive tape 52. Instead, the RFID sticking device 40 is attached to the printing paper P. A hot melt adhesive may be applied, and the RFID tag T may be fixed by the applied adhesive. Further, a metal member such as a wire penetrates the base material having the RFID tag T and the printing paper P, and the leading end portion of the penetrated wire is bent, whereby the RFID tag T is locked to the printing paper P (for example, stapler or the like). It may be configured as follows.

  In the above embodiment, the cut information 60c stored in the cut information memory 34c is received from the outside. However, when the print information 60b is data representing a figure (including a table and a graph), The cut information 60c may be formed from the contour of graphic data.

  Further, in the above-described embodiment, the sheet material is cut at the end of the application or printing of the RFID tag T. However, for example, when cutting the sheet material like a perforation, it is not always the last. For example, the RFID tag T may be attached lastly by cutting after printing.

1 is a perspective view showing an overview of an inkjet printer that is an embodiment of the present invention. It is the figure which showed the internal structure of RFID addition apparatus. It is the figure which showed the structure of the label tape in detail. It is the figure which showed the attachment operation | movement of the RFID tag by a RFID sticking apparatus. It is a block diagram which shows the outline of the electric circuit structure of an inkjet printer. It is a figure which shows RFID information, printing information, and cut information. It is the figure which showed an example produced with this inkjet printer. It is a flowchart explaining the printing on the printing paper by the RFID sticking apparatus, the sticking and cutting operation of the RFID tag. It is a flowchart which shows the RFID sticking process which sticks a RFID tag. It is a flowchart which shows the cutting process which cut | disconnects printing paper. It is a figure which shows typically the process in case an RFID tag and a cutting position overlap. It is a flowchart explaining the process which detects whether an RFID tag and a cutting position overlap. It is a flowchart explaining a process in case an RFID tag and a cutting position overlap. It is a figure which shows a mode that the front and back of a printing paper are reversed. It is a flowchart explaining the operation | movement which affixes an RFID tag on one side with an RFID sticking apparatus, then reverses the front and back of a printing paper, cuts after printing. It is sectional drawing of the front-end | tip part of a cutter head.

Explanation of symbols

1 RFID tag mounting device (RFID tag labeling device)
3 Head unit (printing means)
4 RFID addition device (wireless tag attachment means)
5 Operation panel display (notification means)
11 Paper feeding device (drive means, sheet material drive means)
12 Head moving device (part of driving means, carriage driving means)
15 Carriage 20 Cutting device 32 CPU (control means)
34 RAM (storage means)
40 RFID sticking device 71 Cutter 90 Reversing unit (sheet material reversing means)
100 Personal computer P Printing paper (sheet material)
T wireless tag

Claims (13)

A wireless tag attaching means for attaching the wireless tag to the sheet material;
Cutting means for cutting the sheet material to which the wireless tag is attached by the wireless tag attaching means into a predetermined shape;
A carriage integrally mounting the wireless tag attaching means and the cutting means;
Driving means for driving the carriage or the sheet material in one direction along the plane of the sheet material and in a direction intersecting the direction;
Storage means for storing attachment position information indicating a position where the wireless tag attaching means attaches the wireless tag to a sheet material, and cutting position information indicating a position where the cutting means cuts the sheet material;
The drive unit and the RFID tag mounting unit are controlled based on the mounting position information stored in the storage unit, and the drive unit and the cutting unit are controlled based on the cutting position information stored in the storage unit. and control means for,
Detecting means for detecting whether or not the position of the wireless tag attached on the sheet material and the cutting position for cutting the sheet material overlap based on the attachment position information and the cutting position information stored in the storage means;
Position information changing means for changing the cutting position information or the mounting position information so that the wireless tag and the cutting position do not overlap when the detecting means detects that the wireless tag and the cutting position overlap . An RFID label producing apparatus characterized by the above. The cutting position information includes information indicating a cutting line for cutting the sheet material, and the position information changing unit is a portion where the wireless tag and the cutting line overlap from a line indicated by the cutting position information stored in the storage unit. 2. The RFID label producing apparatus according to claim 1, wherein the cutting position information is changed by deleting a line. The cutting position information includes information indicating a cutting line for cutting the sheet material, and the position information changing unit does not overlap the wireless tag with the line indicated by the cutting position information stored in the storage unit, 2. The RFID label producing apparatus according to claim 1, wherein the RFID label producing apparatus changes to information indicating a line surrounding the position indicated by the mounting position information stored in the storage means. A wireless tag attaching means for attaching the wireless tag to the sheet material;
Cutting means for cutting the sheet material to which the wireless tag is attached by the wireless tag attaching means into a predetermined shape;
A carriage integrally mounting the wireless tag attaching means and the cutting means;
Driving means for driving the carriage or the sheet material in one direction along the plane of the sheet material and in a direction intersecting the direction;
Storage means for storing attachment position information indicating a position where the wireless tag attaching means attaches the wireless tag to a sheet material, and cutting position information indicating a position where the cutting means cuts the sheet material;
The drive unit and the RFID tag mounting unit are controlled based on the mounting position information stored in the storage unit, and the drive unit and the cutting unit are controlled based on the cutting position information stored in the storage unit. and control means for,
Detecting means for detecting whether or not the position of the wireless tag attached on the sheet material and the cutting position for cutting the sheet material overlap based on the attachment position information and the cutting position information stored in the storage means;
A wireless tag label producing apparatus comprising: an informing means for informing that the wireless tag and the cutting position overlap when the detection means detects that the wireless tag and the cutting position overlap . The drive means is constituted by carriage drive means for driving the carriage in one direction and sheet material drive means for driving the sheet material in a direction intersecting the one direction. The RFID label producing apparatus according to any one of 1 to 4 . The carriage includes printing means, and the storage means stores printing information to be printed on a sheet material, and the control means controls the driving means and the printing means based on the printing information. The RFID label producing apparatus according to any one of claims 1 to 5, wherein: Sheet material reversing means for reversing the front and back of the sheet material;
Position information conversion means for converting the mounting position information stored in the storage means into position information corresponding to the back surface of the sheet material;
The control means attaches a wireless tag based on the attachment position information converted by the position information conversion means, then reverses the sheet material by the sheet material reversing means, and prints the print information stored in the storage means. 7. The RFID label producing apparatus according to claim 6 , wherein printing is performed on a sheet material on the basis of the sheet material, and the sheet material is controlled based on the cutting position information stored in the storage unit. Sheet material reversing means for reversing the front and back of the sheet material;
Position information conversion means for converting the attachment position information and the cutting position information stored in the storage means into position information corresponding to the back surface of the sheet material,
The control means performs printing based on the printing information stored in the storage means, then reverses the sheet material by the sheet material reversing means, and wirelessly based on the mounting position information converted by the position information converting means. 7. The RFID label producing apparatus according to claim 6 , wherein a tag is attached to the sheet material, and the sheet material is controlled based on the cutting position information converted by the position information converting means. . Sheet material reversing means for reversing the front and back of the sheet material;
Position information conversion means for converting the mounting position information stored in the storage means into position information corresponding to the back surface of the sheet material;
The control means performs printing based on the printing information stored in the storage means, then reverses the sheet material by the sheet material reversing means, and wirelessly based on the mounting position information converted by the position information converting means. The tag is attached to the sheet material, and then the sheet material is reversed by the sheet material reversing means, and the sheet material is controlled based on the cutting position information stored in the storage means. The RFID label producing apparatus according to claim 6 . A wireless tag attaching means for attaching the wireless tag to the sheet material, a cutting means for cutting the sheet material to which the wireless tag is attached by the wireless tag attaching means into a predetermined shape, and the wireless tag attaching means and the cutting means A control program for a RFID label producing apparatus that controls a RFID label producing apparatus comprising: a carriage mounted on the apparatus; and a driving unit that drives the carriage or the sheet material in one direction along a plane of the sheet material and in a direction intersecting the direction. In
A wireless tag to be attached on a sheet material based on attachment position information indicating a position of the wireless tag attached to the sheet material by the wireless tag attachment means and cutting position information indicating a cutting position at which the cutting means cuts the sheet material. A detection step for detecting whether or not the position of and the cutting position for cutting the sheet material overlap,
And a position information change processing step for changing the cutting position information or the mounting position information so that the wireless tag and the cutting position do not overlap when it is detected that the wireless tag and the cutting position overlap by the detection step. A control program for a RFID label producing apparatus characterized by the above. The cutting position information is constituted by information indicating a line for cutting the sheet material, and the position information change processing step is performed by deleting a line at a portion where the wireless tag and the cutting line overlap from the line indicated by the cutting position information. The control program for a RFID label producing apparatus according to claim 10 , wherein the cutting position information is changed. The cutting position information includes information indicating a line for cutting the sheet material, and the position information change processing step changes the line indicated by the cutting position information to a line surrounding the wireless tag without overlapping the wireless tag. The control program for a RFID label producing apparatus according to claim 10 , wherein the control program is used. A wireless tag attaching means for attaching the wireless tag to the sheet material, a cutting means for cutting the sheet material to which the wireless tag is attached by the wireless tag attaching means into a predetermined shape, and the wireless tag attaching means and the cutting means A control program for a RFID label producing apparatus that controls a RFID label producing apparatus comprising: a carriage mounted on the apparatus; and a driving unit that drives the carriage or the sheet material in one direction along a plane of the sheet material and in a direction intersecting the direction. In
Based on attachment position information indicating a position of the wireless tag attached on the sheet material by the wireless tag attachment means and cutting position information indicating a cutting position where the cutting means cuts the sheet material, the wireless tag attached on the sheet material A detection step for detecting whether or not the position and the cutting position for cutting the sheet material overlap,
A wireless tag attachment device process comprising: a notification step for notifying that the wireless tag and the cutting position overlap when it is detected that the wireless tag and the cutting position overlap in the detection step program.

Images