JP5386117B2 - RF tag label tape manufacturing equipment - Google Patents

Description

  The present invention relates to an apparatus for manufacturing an RF tag label tape in which RF tags used for RFID are enclosed in a label tape with a predetermined interval.

  RFID (Radio Frequency Identification) is a non-contact automatic identification technology using radio frequency. A reader connected to a computer reads the identification information of an RF tag attached to a moving object such as a person or an object via radio frequency. It is a system that automatically identifies things. The RF tag is a battery-less communication device including a semiconductor and an antenna in which a transmission / reception circuit, a control circuit, a memory, and the like are made into a single chip.

  The RF tag is made in advance as a continuous body in which the RF tag is continuously arranged. The RF tag is cut and separated one by one from the RF tag continuous body and sealed in a label tape at predetermined intervals to form an RF tag label tape. ing. The RF tag label tape is cut into a predetermined length including one RF tag, whereby an RF tag label is obtained as an IC module.

  The individual RF tags prepared in advance as an RF tag continuum always contain defective products at a fixed rate. In the manufacturing process of the RF tag label tape, the defective products are enclosed in the label tape. It is desirable to remove it before doing so.

  In a conventional RF tag label tape manufacturing apparatus of this type, as shown in Patent Document 1, an RF tag supply line is provided in the same direction as the label tape traveling direction, and an IC is formed on the line. The function of the module (RF tag) is confirmed, and if the function is abnormal, the module is recovered and removed, and only the normal one is supplied into the label tape.

JP 2004-59113 A

  In the case of the above prior art, when RF tag label tapes are arranged in multiple rows in order to increase production efficiency, RF tag supply lines and inspection means for supplying RF tags to the label tape are provided for each row. In order to increase the production efficiency by multi-row production, there is a problem that the equipment cost becomes high.

  The present invention has been made in view of the above, and it is possible to increase the production efficiency of the RF tag label tape by increasing the production line of the RF tag label tape, and to increase the production efficiency of the RF tag label tape. To provide an RF tag label tape manufacturing apparatus which can supply RF tags to a tape and inspect all RF tags with a single RF tag supply apparatus, thereby reducing equipment costs. It is intended.

In order to achieve the above object, an RF tag label tape manufacturing method according to the present invention is a method of laminating a release paper after affixing an RF tag, which is a batteryless communication device, to a label mount on which adhesive has been applied to the entire surface. In the RF tag label tape manufacturing apparatus in which the RF tag is sealed at a predetermined interval in the longitudinal direction in the label tape composed of the label mount and the release paper,
A travel line is provided for the label mount and release paper of the label tape having a tape width that is a multiple of the width of the RF tag label tape, and the label mount and release paper are bonded to the downstream side of each travel line. And a slitting part for dividing the label tape into the widths of the respective RF tag label tapes.
An RF tag supply device that supplies an RF tag to the label mount from a direction orthogonal to the travel direction of the label mount is provided on the side of the label mount travel line,
The width of each RF tag label tape on the label mount is adjusted to match the timing and timing of the label mount, with the RF tag supplied one by one from the RF tag supply device at a position corresponding to the RF tag supply device on the label mount travel line. An RF tag carry-in belt for carrying in to the position is provided,
The RF tag supply device includes an RF tag transport unit that transports the RF tags one by one toward the label mount, and a function inspection unit that inspects the function of each RF tag while being transported by the RF tag transport unit. The function inspection means is provided closer to the travel line of the label mount, and defective product removal means for removing defective products by the function inspection means is provided.
The RF tag transport belt is provided with pins in the rotation direction at the same interval as the tape width of the RF tag label tape, and rotates in the width direction of the traveling label mount on the travel line of the label mount. Provided in
The RF tag transport belt intermittently travels by an interval of the pins when the RF tag supplied to one side in the width direction of the label mount by the RF tag supply device comes into contact with the pins, and the RF tag is attached to the label mount. It is configured to intermittently transport the RF tag label tape by the tape width on the other side in the width direction .

  Then, the RF tag transport means of the RF tag supply device cuts the RF tag continuous body into a single RF tag from the transport means for transporting the dry RF tag continuous body and supplies it to the function inspection means side. A cutting means, or an RF tag conveying means of the RF tag supply device for conveying a wet type RF tag continuous body in which the RF tag is attached to the peeling paper, and a release paper from the RF tag continuous body. And a release paper peeling means for supplying RF tags one by one to the function inspection means side. Further, both the RF tag supply devices can be selectively used.

  In the release paper travel line, a glue device for applying glue in advance at a position corresponding to the RF tag of the release paper to be attached to the label mount with the dry RF tag attached thereto was provided.

According to the configuration of the first aspect of the present invention, even in a multi-row production line using a label tape having a width multiple of that of the RF tag label tape, one RF tag having an inspection function in each row of label tape The production efficiency of the RF tag label tape can be increased by being able to cope with the supply device, and in the multi-row production line as described above, the supply of the RF tag to the production line of each row and all the RF The tag can be inspected with one RF tag supply device, and the equipment cost can be reduced.
Further, the RF tags supplied by the RF tag supply device can be accurately supplied one by one to a position corresponding to each RF tag label tape of the label mount that travels on the travel line of the label mount.

  Further, by using the RF tag supply device according to claim 2, individual RF tags from a dry type RF tag continuous body, and by using the RF tag supply device according to claim 3, a wet type The individual RF tags can be supplied from the RF tag continuum to the running line of the label mount, and according to the configuration of claim 4, both the RF tag supply devices can be selectively used. In addition, the RF tag can be supplied from a dry type or wet type RF tag continuum.

  According to the configuration described in claim 5, when the dry RF tag is supplied to the label mount using the RF tag supply device according to claim 2, the label mount attached with the RF tag is used. Glue can be applied to the release paper to be laminated at a position corresponding to the RF tag on the label mount. When this dry type RF tag is used, the release paper is bonded to the RF tag of the label mount. Thus, it is possible to obtain an RF tag label tape that does not partially float in a finished product state.

  FIG. 1 is a front view showing an entire manufacturing apparatus of an RF tag label tape according to the present invention. In FIG. 1, 1 is a label tape formed by laminating and laminating a label mount 1a and a release paper 1b. It is in a roll shape and is fed out from the label tape supply unit 2. 3 is a peeling part where the release paper 1b is peeled off from the label tape 1 supplied from the label tape supply part 2 by the roller 4, and 5 is a label mount 1a from which the release paper 1b is peeled off by the peeling part 3. An RF tag attaching unit 8 for attaching RF tags 7 supplied by an RF tag supplying device 6 to be described later at equal intervals in the flow direction of the label mount 1a, and 8 is provided downstream of the RF tag attaching unit 5. Then, the release paper 1b peeled off at the peeling portion 3 is attached to the label mount 1a again by the bonding roller 9, and the RF tag 7 is sandwiched and sealed in the label tape 1 to be an RF tag label tape 10. A mating unit 11 is a tape winding unit that winds up the RF tag label tape 10.

  In the apparatus of the present invention, as shown in FIG. 3, W1 of the label tape 1 is a multiple of the tape width W2 of the RF tag label tape 10 which is a product in this apparatus, for example, four times the width. An RF tag 7 having a tag width W3 narrower than the tape width W2 of the RF tag label tape 10 is supplied from the RF tag supply device 6 to the center of each tape width position. A slitter 12 that cuts the tape width W2 of the RF tag label tape 10 is provided on the downstream side of the bonding portion 8. Further, a glue device 13 for applying glue to the back surface of the release paper 1b is provided in the travel line of the release paper 1b upstream of the laminating section 8.

  The glue device 13 is used when the RF tag 7 supplied from the RF tag supply device 6 is of a dry type, that is, when no glue is attached to the upper surface, and is pasted on the label mount 1a by the laminating unit 8. The glue is applied to the position of the release paper 1b corresponding to the RF tag 7 at the time.

  As shown in FIGS. 2 and 3, the RF tag supply device 6 is provided in the RF tag attaching unit 5 in a posture orthogonal to the side of the travel line of the label mount 1 a.

  2, 3, and 4 show the RF tag supply device 6. FIG. 2 is a view taken along the line AA in FIG. 1, FIG. 3 is a plan view, and FIG. 4 is a view taken along the line BB in FIG. It is an enlarged view.

  In FIG. 2, reference numeral 14 denotes a dry type RF tag continuous body in which individual RF tags 6 are continuously arranged in a long shape, and this RF tag continuous body 14 is predetermined by a drawing roller 15 from a roll-shaped portion. It is pulled out to the loop portion 16 at a pulling speed.

  Between the loop portion 16 and the travel path of the label tape 1, the pull-out conveyor belt 17 that pulls out the RF tag continuous body 14 from the loop portion 16 and the terminal end portion of the drawer-convey belt 17 are provided. An RF tag cutting device 18 that cuts the RF tag continuous body 14 conveyed by the belt 17 into an RF tag 7 having a width W3, and the RF tag 7 cut by the RF tag cutting device 18 are adsorbed to each other at a predetermined interval. 1st and 2nd suction conveyance belts 19 and 20 which are opened and conveyed, and one RF tag which is provided above the first suction conveyance belt 19 and is conveyed by this first suction conveyance belt 19 It is provided between the RF tag inspection device 21 that inspects these functions one by one and the first and second suction and conveyance belts 19 and 20, and is determined to be defective by the inspection of the RF tag inspection device 21. Sorting board 23 for selectively dropping the F tag 7 receiving box 22 is disposed.

  Suction boxes 19a and 20a are provided inside the first and second suction conveyance belts 19 and 20, and the negative pressure of each of the suction boxes 19a and 20a is RF through a suction hole provided in each belt. Each RF tag 7 after acting on the tag 7 and being cut travels along with the belt.

  A guide plate 24 is provided along the upper surface of the label mount 1a that travels along the travel line of the label mount 1a on the RF tag attaching portion 5 of the travel line of the label mount 1a facing the downstream end of the second suction conveyance belt 20. The RF tag 7 provided and transported by the second suction transport belt 20 is transported onto the guide plate 24. As shown in FIGS. 3 and 4, the end of the guide plate 24 on the label mount 1a in the running direction is positioned away from the downstream end of the label mount 1a of the RF tag 7 loaded on the label mount 1a. The affixing roller 25 can rotate in the running direction of the label mount 1a and move downward so that this portion faces the upper end of the label mount of each RF tag 7 on the label mount 1a. The pressing operation is possible. On the lower side facing the sticking roller 25, an impression cylinder 26 is provided along the lower surface of the label mount 1a so as to be rotatable in the running direction of the label mount 1a.

  On the upper side of the guide plate 24, an RF tag carrying belt 27 for carrying the RF tag 7 carried by the second suction carrying belt 20 onto the guide plate 24 is provided. The RF tag carry-in belt 27 extends from the position where the lower running side of the RF tag carrying belt overlaps with the downstream side of the second suction conveyance belt 20 across the entire width of the label mount 1a and the second suction conveyance belt 20. The upper surface of the guide plate 24 is intermittently driven with a slight gap. The RF tag carrying-in belt 27 is provided with pins 28 at the same interval W2 as the tape width W2 of the RF tag label tape 10. In this embodiment, the RF carry-in belt 27 is provided in two rows in the length direction of the RF tag 7 (traveling direction of the label mount 1a). However, the RF carry-in belt 27 is formed in one row by giving a predetermined width. It may be. The pin 28 moves so that its tip contacts the upper surface of the guide plate 24.

  The RF tag carry-in belt 27 is intermittently operated in conjunction with the second suction / conveying belt 20 and sequentially mounts the RF tags 7 conveyed by the suction / conveying belt 20 one by one in a quadruple width label mount. Each RF tag label tape 1a is loaded into the center position of the tape width W2.

  The operation at this time will be described with reference to FIGS. 4, 5, 6, and 7. In this description, since the diameter of the pin 28 is substantially small, the description will be made ignoring this diameter.

  The RF tag carry-in belt 27 intermittently travels over the interval W2 between the pins 28 with the most upstream pin 28 of the lower traveling portion directed downward. The intermittent running operation is performed when the RF tag 7 conveyed by the second suction conveyance belt 20 abuts on the pin 28 on the most upstream side in the above-mentioned base point state. Detected by the detecting means provided on the side, the tape travels intermittently by the tape width W2 of the RF tag label tape 10 each time. The traveling speed of the RF tag carry-in belt 27 travels faster than the traveling speed of the second suction conveyance belt 20 by a distance of (W2-W3).

  FIG. 5 shows the above-described base point state, that is, the RF tag carry-in belt 27 stopped with the most upstream pin 28 facing downward and the RF suction belt 20 being conveyed by the second suction conveyance belt 20. The tag 7 is in contact with the pin 28. At this time, the distance relationship between the pin 28 of the RF tag carrying-in belt 27 and the label mount 1a in the RF tab attaching portion 5 is such that the pin 28 at the base position is moved by, for example, one pitch over the tape width W2. The pins 28 are in a relationship of being positioned at the RF tag supply side end of the RF tag 7 in the RF tag label tape 10 on the RF tag supply side of the label mount 1a.

  When the RF tag 7 transported by the second suction transport belt 20 is transported to a position where it abuts on the most upstream pin 28 in this base point state, the RF tag transport belt 27 extends over the tape width W2. It operates at a speed faster by W2-W3 than the transport speed of the second suction transport belt 20. Therefore, while the pin 28 one upstream from the most upstream pin 28 travels by the tape width W2, the RF tag is brought into contact with the rear end of the RF tag 7 and moved across the tag width W3 and stopped. This RF tag 7 is sent to the label mount 1a side. This state is shown in FIG.

  While the RF tag carry-in belt 27 is stopped in the state shown in FIG. 6, the next RF tag 7 conveyed by the second suction conveyance belt 20 contacts the next pin 28 located on the most upstream side. . As a result, the RF tag carry-in belt 27 is operated by the tape width W2, and the RF tag 7 is fed to the label mount 1a side over the tape width W2. The RF tag 7 previously sent by this operation moves on the guide plate 24 with the tape width W2 as one pitch. In this state, the RF tag 7 is positioned in the center in the width direction of the first RF tag label tape 10.

  Thus, as shown in FIG. 3 and FIG. 7, in a state where each RF tag 7 is aligned with the running direction of the label mount 1a on the guide plate 24 at the center of each tape width W2 of the label mount 1a. Supported. In this state, the RF tag supply device 6 temporarily stops, and therefore the RF tag carry-in belt 27 also temporarily stops. Next, each affixing roller 25 shown in FIG. 3 and FIG. 4 moves downward to pinch the label mount 1 a and the RF tag 7 between the impression cylinders 26. In this state, each RF tag 7 is attached to the center in the width direction of each tape width W2 of the label mount 1a as the label mount 1a travels.

  Thereafter, the RF tag supply device 6 operates again and the above operation is repeated. At this time, the label mount 1a is traveling at a constant speed, and the attaching position of each RF tag 7 by the attaching roller 25 with respect to the traveling direction of the label mount 1a depends on the traveling speed of the label mount 1a and the RF tag supply. By matching the operation timing of the device 6, it is set to an appropriate position.

  At this time, during the operation of the RF tag supply device 6, each RF tag 7 cut into a single unit by the RF tag cutting device 18 is conveyed while being conveyed on the first suction conveyance belt 19. One by one is inspected by the inspection device 21. Then, the RF tag 7 determined as a defective product by this inspection is sorted by the sorting plate 23 that is operated by this inspection signal and dropped into the receiving box 22.

  As a result, there is at least one gap between the conveyance intervals of the RF tag 7 toward the second suction conveyance belt 20, but the RF tag carry-in belt 27 is stopped during that interval, and the next RF tag 7 is connected to the pin 28. The loading operation is performed by contacting the At this time, the conveyance time for one RF tag 7 is delayed until the four RF tags 7 are aligned on the guide plate 24, so that the travel of the label mount 1a is stopped during that time.

  FIG. 8 shows an example of an RF tag attachment position on the label mount 1a. If each RF tag 7 having a length of L1 is attached with an interval of L3, four rows of the next RF tag 7 are arranged. The supply operation on the label mount 1a may be performed within the L3 transport time of the label mount 1a, and can be performed continuously without stopping the label mount 1a normally. Then, if there is one or two supply intervals for eliminating the defective products, the supply of the RF tag 7 is stopped at that time, and the supply of the RF tags 7 for four rows is stopped. After completing the operation, resume running and paste together with intermittent feeding.

  In FIG. 8, L2 indicates the length when the RF tag label tape 10 is cut in the subsequent process to form the RF tag label 10a.

  In the above-described embodiment, the pin 28 provided on the RF tag carry-in belt 27 moves while the tip of the pin 28 abuts against the upper surface of the guide plate 24 to push the RF tag 7 on the guide plate 24. In this example, in order to more reliably push the RF tag 7 by the pin 28, a groove is provided in the guide plate 24 over the movement locus of the pin 28, and the pin 28 is immersed in the groove. The above pushing operation may be performed.

  In FIG. 1, 29 is a re-inspection device provided on the downstream side of the bonding portion 8, 30 is a printing device, and this re-inspection device 29 re-inspects each RF tag 7 arranged in four rows. The RF tag 7 determined to be defective in the reinspection is printed by the printing device 30 from the upper side of the release paper 1b.

  In the above-described configuration, the label tape 1 supplied from the label tape supply unit 2 is peeled off by the peeling unit 3 from the release paper 1b to become the label mount 1a. After that, the RF tag attaching unit 5 The RF tags 7 supplied from the tag supply device 6 are pasted over four rows.

  At this time, the RF tag 7 is supplied from the side orthogonal to the traveling direction of the label mount 1a, and only the ones that have been inspected by the RF tag inspection device 21 are supplied to each of the four rows of RF tag label tapes 10. The

  Next, the release paper 1b peeled off at the peeling part 3 by the laminating part 8 is overlapped and pasted on the label mount 1a to which the RF tag 7 is attached. At this time, the back surface of the release paper 1b after peeling is glued to the portion corresponding to the RF tag 7 when pasted to the label mount 1a by the pasting unit 8 by the glue device 13, and the pasting unit 8 The release paper 1b bonded together in step 1 is re-adhered to the label mount 1a and is bonded to the entire surface of the RF tag 7.

  After that, the RF tag 7 enclosed between the label mount 1a and the release paper 1b is re-inspected by the re-inspection device 29 on the downstream side of the laminating unit 8, and when defective products are mixed. Further, on the downstream side, predetermined printing is performed for each defective product by the printing device 30 for each column, and this can be discriminated and removed at the use stage.

  However, the re-inspection and defective product printing in this process can be inspected and removed by the processing unit in the next process as a winding roll of the individual RF tag label tape 10 that is wound up in four rows. Equipment costs can be reduced.

  After the re-inspection, the sheet is cut in the running direction by the slitter 12 and completed as a four-row RF tag label tape 10 as a winding roll in the winding unit 11.

  9, FIG. 10 and FIG. 11 show another embodiment of the invention.

  FIG. 9 shows an RF tag supply device 6a when a wet type RF tag is used. The RF tag continuum 14a in this case has a configuration in which the individual RF tags 7 are attached to the release paper 31 with glue, and the RF tag continuum 14a is pulled out by the pulling and conveying belt 17. After the release paper 31 is peeled off by the release paper take-up device 32, the RF tags are conveyed one by one to the first and second suction conveyance belts 19 and 20, and thereafter, as shown in FIG. The individual RF tags 7 are supplied to the label mount 1a by the same operation as in the embodiment. Also in this embodiment, each RF tag 7 is inspected by the inspection device 21, and defective products are classified by the sorting plate 23.

  According to the embodiment shown in FIG. 9, the RF tag cutting device 18 as in the embodiment shown in FIG. 2 is not required because the release paper 31 is peeled to form individual RF tags. Further, since glue is attached to the surface of each RF tag 7, and the release paper 1b peeled off from the label tape 1 is directly attached to the surface of the RF tag 7, the glue in the embodiment shown in FIG. The device 13 becomes unnecessary.

  The configuration of the RF tag supply device 6a using the wet type RF tag shown in FIG. 9 and the configuration of the RF tag supply device 6 using the dry type RF tag shown in FIG. The configuration on the downstream side from 19 is the same, and the configuration on the upstream side from this is selectively used depending on whether the continuum is a dry type or a wet type with an RF tag. Note that the entire apparatus may be selectively used.

  In FIG. 10, the label mount 1a and the release paper 1b are supplied separately, and the paste is applied to the entire surface of the label mount 1a by the paste unit 33 for the mount, and the RF tag attaching unit 5 applies the RF to the label mount 1a. An embodiment in which an RF tag 7 supplied from a tag supply device 6 is pasted is shown. When the RF tag 7 supplied from the RF tag supply device 6 at this time is a dry method, the paste device 13 glues the RF tag 7 on the release paper 1b at the bonding position.

  11 shows an RF tag supply device 6b having a configuration in which a short side width RF tag supply device 34 for supplying a short side width RF tag 7 is connected to the side of the drawer conveying belt 17 of the RF tag supply device 6 shown in FIG. Indicates. The short-side width RF tag supply device 34 pulls out the short-side-width RF tag continuous body 14b from the roll portion by the pulling roller 15a, pulls it out by the pull-out conveying belt 17a through the loop portion 16a, and then cuts the RF tag. The apparatus 18a is cut in the long side direction, and is supplied onto the drawer conveyance belt 17 of the RF tag supply device 6 by the suction conveyance belt 19a.

  According to this embodiment, the width of the roll-like portion of the RF tag continuum can be used in two ways: the long side of the RF tag and the short side.

It is a front view which shows the whole apparatus of this invention. It is an AA arrow directional view of FIG. 1, and is explanatory drawing which shows RF tag supply apparatus. It is a top view which shows RF tag supply apparatus. It is a BB arrow enlarged view of FIG. It is operation | movement explanatory drawing of RF tag supply apparatus. It is operation | movement explanatory drawing of RF tag supply apparatus. It is operation | movement explanatory drawing of RF tag supply apparatus. It is a top view which shows RF tag label tape. It is explanatory drawing which shows the other example of RF tag supply apparatus. It is a front view which shows the other example of the manufacturing apparatus of RF tag label tape. It is a top view which shows the other example of RF tag supply apparatus.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Label tape, 1a ... Label mount, 1b, 31 ... Release paper, 2 ... Label tape supply part, 3 ... Peeling part, 4 ... Peeling roller, 5 ... RF tag sticking part, 6, 6a, 6b ... RF tag Supply device, 7 ... RF tag, 8 ... bonding section, 9 ... bonding roller, 10 ... RF tag label tape, 10a ... RF tag label, 11 ... tape take-up section, 12 ... slitter, 13 ... glue device, 14,14a ... RF tag continuum, 15 ... drawing roller, 16 ... loop part, 17 ... drawing conveyor belt, 18 ... RF tag cutting device, 19, 20 ... first and second suction conveying belts, 19a, 20a ... suction box, DESCRIPTION OF SYMBOLS 21 ... RF tag inspection apparatus, 22 ... Receptacle box, 23 ... Sorting plate, 24 ... Guide plate, 25 ... Pasting roller, 26 ... Impression cylinder, 27 ... RF tag carrying-in belt, 28 ... Pin, 29 ... Re-inspection equipment , 30 ... printing apparatus, 32 ... peeling paper take-up device, 33 ... mount for glue system, 34 ... short-side width RF tag supplying apparatus.

Claims (5)

Affix the RF tag, which is a battery-less communication device, to the label mount with glue applied on the entire surface, and then stack the release paper to place the RF tag in the longitudinal direction within the label tape made up of the label mount and release paper. In an RF tag label tape manufacturing apparatus that is sealed at a predetermined interval,
A travel line is provided for the label mount and release paper of the label tape having a tape width that is a multiple of the width of the RF tag label tape, and the label mount and release paper are bonded to the downstream side of each travel line. And a slitting part for dividing the label tape into the widths of the respective RF tag label tapes.
An RF tag supply device that supplies an RF tag to the label mount from a direction orthogonal to the travel direction of the label mount is provided on the side of the label mount travel line,
The width of each RF tag label tape on the label mount is adjusted to match the timing and timing of the label mount, with the RF tag supplied one by one from the RF tag supply device at a position corresponding to the RF tag supply device on the label mount travel line. An RF tag carry-in belt for carrying in to the position is provided,
The RF tag supply device includes an RF tag transport unit that transports the RF tags one by one toward the label mount, and a function inspection unit that inspects the function of each RF tag while being transported by the RF tag transport unit. The function inspection means is provided closer to the travel line of the label mount, and defective product removal means for removing defective products by the function inspection means is provided.
The RF tag transport belt is provided with pins in the rotation direction at the same interval as the tape width of the RF tag label tape, and rotates in the width direction of the traveling label mount on the travel line of the label mount. Provided in
The RF tag transport belt intermittently travels by an interval of the pins when the RF tag supplied to one side in the width direction of the label mount by the RF tag supply device comes into contact with the pins, and the RF tag is attached to the label mount. An apparatus for producing an RF tag label tape, wherein the tape is intermittently conveyed by the tape width of the RF tag label tape to the other side in the width direction. The RF tag carrying means of the RF tag supply device is
Claim, characterized in that consists of a conveying means for conveying the RF tag continuum of dry type, and cutting means for supplying to the function test means side was cut from the RF tag continuum in the RF tag of one by one 1 The manufacturing apparatus of RF tag label tape of description. The RF tag carrying means of the RF tag supply device is
A transport means for transporting a wet-type RF tag continuum formed by attaching an RF tag to a release paper, and a detachment for peeling the release paper from the RF tag continuum and supplying the RF tags one by one to the function inspection means RF tag label tape manufacturing apparatus according to claim 1, characterized by comprising a paper stripping means. And claim 2 RF tag supplying apparatus according claim 3 RF tag label tape manufacturing apparatus according to claim 1, characterized in that the RF tag supplying apparatus to be able to selectively use according. 3. A glue device that preliminarily applies glue at a position corresponding to the RF tag of the release paper to be attached to the label mount with the dry type RF tag attached to the travel line of the release paper. 4. An apparatus for producing an RF tag label tape according to 4 .

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