JP4494893B2 - Label continuum manufacturing method and manufacturing apparatus - Google Patents

Description

  The present invention relates to a label continuous body manufacturing method and manufacturing apparatus, and more particularly to a label continuous body manufacturing method and manufacturing apparatus in which a label having a magnetic sensitive wire used for theft prevention is continuously formed.

  For example, in a store or the like, in order to prevent theft of merchandise, a monitoring system is employed that installs a monitoring device at the entrance of the store and issues an alarm when an illegal attempt is made to take the merchandise. In such a monitoring system, a magnetic sensitive wire is used as one of the devices that react to the monitoring device. The magnetically sensitive wire is formed of a material whose magnetization state is changed by application of an external magnetic field, for example. If a product with a label having such a magnetic sensitive wire is illegally taken out, a change in the magnetization state of the magnetic sensitive wire is detected by the monitoring device, and an alarm is issued.

  When producing a label continuum in which a label having such a magnetic sensitive wire is continuously temporarily attached on a strip-shaped release mount, a label continuum in which the magnetic sensitive wire is arranged along the longitudinal direction of the release mount. There is a manufacturing method. However, when the magnetic sensitive wire is arranged along the longitudinal direction of the release mount, when the label continuous body is wound, the magnetic sensitive wire is wound, which is inconvenient for handling the label. Therefore, as shown in FIG. 14, the label 3 is formed so that the magnetic sensitive wire 1 is along the longitudinal direction of the release mount 2, and as shown in FIG. 15, the label 3 is attached to another release mount 4, There is a method in which the magnetic sensitive wire 1 is arranged along the width direction of the peeling mount (for example, see Patent Document 1).

  However, in such a method, a process of pasting a label once formed on the release mount on another release mount is required, and manufacturing becomes complicated. Then, as shown in FIG. 16, the manufacturing apparatus which sticks the magnetic sensitive wire 1 to the width direction of the strip | belt-shaped base material 5 in which the adhesive bond layer was formed was considered. In this manufacturing apparatus, in the pressing device 6, the magnetic sensitive wire 1 is fed into a gap extending in the width direction of the substrate 5 formed on the guide 7, and the magnetic sensitive wire 1 is cut by a blade that moves up and down in the guide 7. At the same time, the cut magnetic sensitive wire 1 is pressed against the adhesive layer of the substrate 5. A film 8 is placed on the base material 5 on which the magnetic sensitive wire 1 is pasted, and a continuous label is formed by forming a cut in the film 8 and removing unnecessary portions (see, for example, Patent Document 2). ).

Japanese Patent Laid-Open No. 7-77938 JP 2002-245561 A

  In the method disclosed in Patent Document 2, a magnetic sensitive wire can be directly attached along the width direction of a belt-like base material, but there is one press device for pressing the cut magnetic sensitive wire to the base material. Therefore, there is a problem that only one magnetic sensitive wire can be pasted on the base material, resulting in poor production efficiency. Therefore, it is conceivable to arrange a plurality of press devices and attach a large number of magnetically sensitive wires on the substrate at the same time. However, since the press device is bulky, if a plurality of press devices are arranged, the label interval becomes too wide. Not practical. Further, since the magnetic sensitive wire is fed into the gap of the guide, the magnetic sensitive wire can be prevented from bending in the direction parallel to the surface of the base material, but the bending toward the base material cannot be prevented. . For this reason, for example, if the magnetic sensitive wire is bent in the direction of the base material and its tip is caught on the surface of the base material, it is considered that the magnetic sensitive wire is bent when the magnetic sensitive wire is fed out.

  SUMMARY OF THE INVENTION Therefore, a main object of the present invention is to provide a label continuum manufacturing method and manufacturing apparatus that can supply a magnetic continuity wire on a substrate without bending and can efficiently manufacture a label continuum. It is to be.

The present invention is a method for producing a continuous label body in which a plurality of labels having magnetically sensitive wires are temporarily attached side by side on a strip-like release mount, and a step of preparing a strip-like substrate on which an adhesive layer is formed A step of preparing two blades for cutting the magnetically sensitive wire, a step of passing the substrate so that the two blades are positioned on the adhesive layer in the vicinity of the widthwise end of the substrate, A step of feeding the magnetic sensitive wire passed through the guide tube together with the guide tube so that the distal end of the guide tube protrudes from the distal end of the guide tube toward the center portion or the other end portion in the width direction of the material; A label continuum comprising a step of pressing the tip of the wire against the adhesive layer, a step of leaving only the guide tube while leaving the magnetic sensitive wire on the adhesive layer, and a step of cutting the magnetic sensitive wire with two blades It is a manufacturing method.
By passing the magnetic sensitive wire through the guide tube in the width direction of the substrate, the magnetic sensitive wire is supplied onto the substrate without bending. And in the state which pressed the front-end | tip part of the magnetic sensitive wire which protruded from the guide tube to the adhesive bond layer of a base material, it arrange | positions so that a magnetic sensitive wire may extend on an adhesive bond layer by pulling back only a guide tube. In this state, the magnetic sensitive wire is attached to the adhesive layer along the width direction of the substrate by cutting the magnetic sensitive wire with two blades. Here, since the two blades are arranged on the adhesive layer in the vicinity of the edge in the width direction of the base material, the magnetic sensitive wire is cut inside the width direction of the base material without being cut. Is done.
In such a label continuum manufacturing method, the step of cutting the magnetic sensitive wire is performed in a state where the tip of the magnetic sensitive wire and the space between the tip of the magnetic sensitive wire and the blade side are pressed against the adhesive layer. You may cut | disconnect a magnetic wire.
In this way, with the magnetic sensitive wire extending in the width direction of the substrate, the tip and the intermediate portion of the magnetic sensitive wire are pressed against the adhesive layer of the substrate and cut, so the magnetic sensitive wire is The adhesive layer is sufficiently pasted in an extended state.

The present invention also provides two blades for cutting the magnetic sensitive wire on the adhesive layer in the vicinity of the end in the width direction of the band-shaped base material on which the adhesive layer is formed, and for passing the magnetic sensitive wire. A guide tube, and a moving device for sending the magnetic sensitive wire passed through the guide tube together with the guide tube in the width direction of the base material, and pulling back only the guide tube while leaving the magnetic sensitive wire on the adhesive layer; And a label continuum manufacturing apparatus including a pressing tool for pressing a tip portion of a magnetic sensitive wire to an adhesive layer of a substrate.
Furthermore, another pressing tool for pressing the space between the tip of the magnetic sensitive wire and the blade side against the adhesive layer of the substrate may be provided.
By using a manufacturing apparatus having such a structure, a label continuous body can be manufactured by the manufacturing method as described above. At this time, the guide tube through which the magnetic sensitive wire is passed can be sent out in the width direction of the substrate or pulled back by the moving device. Further, the moving device moves the guide tube through the magnetic sensitive wire, and it is easy to dispose and move a plurality of guide tubes through the thin magnetic sensitive wire. Therefore, by using a plurality of guide tubes, a plurality of magnetic sensitive wires can be simultaneously stuck on the substrate.

Further, the moving device includes a base that holds the guide tube and reciprocates in the width direction of the base material, and a roller that sandwiches a portion of the magnetic sensitive wire before entering the guide tube with the base, When the base moves toward the base material, the roller does not rotate, and the magnetic sensitive wire is fixed between the roller and the base and moved to the base side together with the base so that the base moves away from the base material. When moving to the position, the roller rotates and the base moves so as to slide under the magnetic sensitive wire so that the magnetic sensitive wire is not moved.
In such a moving device, by moving the base to the base material side, the magnetic sensitive wire passed through the guide tube is sent out together with the guide tube in the width direction of the base material in an extended state. And only the guide tube is pulled back with the magnetic sensitive wire remaining in a state in which the tip portion is pressed against the adhesive layer of the base material and extends. Therefore, it is possible to apply the magnetically sensitive wire to the adhesive layer of the base material in a state of extending cleanly.

  According to this invention, the guide tube through which the magnetic sensitive wire has passed is sent out in the width direction of the base material, and only the guide tube is pulled back with the tip of the magnetic sensitive wire pressed against the adhesive layer of the base material. The magnetic wire can be arranged on the substrate without being bent. In addition, the number of guide tubes for passing the magnetically sensitive wire can be easily increased, so a large number of magnetically sensitive wires can be affixed onto the substrate at the same time, enabling efficient production of continuous label bodies. It is.

  The above object, other objects, features, and advantages of the present invention will become more apparent from the following description of the best mode for carrying out the invention with reference to the drawings.

  FIG. 1 is a perspective view showing an example of a continuous label produced by the production method of the present invention, and FIG. 2 is a sectional view thereof. The label continuum 10 includes a strip-shaped release mount 12. On the peeling mount 12, a plurality of rectangular labels 14 are temporarily attached. The label 14 includes an adhesive mount 16, and an adhesive layer 18 is formed on one surface of the adhesive mount 16. The adhesive layer 18 is temporarily attached to the release mount 16. Further, on the other side of the adhesive mount 16, the magnetic sensitive wire 20 is arranged, and the surface paper 24 on which the adhesive layer 22 is formed covers the magnetic sensitive wire 20 so that the other side of the adhesive mount 16 is covered. It is stuck on the top.

  The magnetic sensitive wire 20 is disposed so as to extend in the longitudinal direction of the label 14. And the label 14 is arrange | positioned so that the longitudinal direction may follow the width direction of the peeling mount 12. Therefore, the magnetic sensitive wire 20 is arranged along the width direction of the peeling mount 12. Such labels 14 are continuously arranged in a line in the longitudinal direction of the release mount 12. The label continuum 10 is used by being attached to a label applicator such as a handler labeler.

  Here, as the magnetic sensitive wire 20, for example, high magnetic permeability materials such as permalloy and sendust, Co-B, Co-Fe-B, Co-Fe-Ni-B, Fe-Ni-Mo-B, etc. System, Fe-Ni-P-B system, Fe-Ni-B system, Fe-B system, Fe-Mo-B system, Co-Fe-Mo-B-Si system amorphous metal material, Fe- Uses various so-called soft magnetic materials whose magnetization state changes due to changes in a relatively weak external magnetic field, such as metal materials exhibiting large Barkhausen jumps such as Si-based and Ni-Fe-based materials, and oxide materials such as soft ferrite. be able to.

  Examples of the adhesive mount 16 and the surface paper 24 include films or sheets of polypropylene, polyethylene, polyethylene terephthalate, nylon, polyvinyl chloride, art paper, craft paper, high-quality paper, coated paper, resin-impregnated paper, and the like. Paper, synthetic paper, and the like can be used. Further, the adhesive layer 18 and the adhesive layer 22 are formed by applying a pressure-sensitive adhesive to the main surface of the adhesive mount 16 or the surface paper 24, or on the main surface of the adhesive mount 16 or the surface paper 24, for example. It is formed by transferring the pressure sensitive adhesive layer formed on the release paper.

  When this label 14 is used, the label 14 is peeled off from the peeling mount 12 and attached to the article by the adhesive layer 18. When the article passes through the detection region, a magnetic field that changes in a predetermined manner, such as an alternating magnetic field, is applied to the magnetic sensitive wire 20. By applying such a magnetic field, the magnetization state of the magnetic sensitive wire 20 changes, and the magnetic field emitted from the magnetic sensitive wire 20 changes corresponding to the change in the magnetization state. An alarm is issued when the change in the magnetic field is detected.

  In order to manufacture the label continuous body 10, a manufacturing apparatus as shown in FIG. 3 is used. In this manufacturing apparatus 30, the base material 32 is drawn out from a roll 34 around which a belt-like base material 32 that will eventually become the surface paper 24 is wound. Note that what is wound around the roll 34 is one in which the adhesive layer 22 is formed on one surface of the substrate 32, and the release paper 36 is temporarily attached onto the adhesive layer 22. Then, the release paper 36 is peeled off from the drawn base material 32 and wound around the roller 38. Thereby, the adhesive layer 22 is exposed on the upper surface of the substrate 32.

  On the surface of the base material 32 where the adhesive layer 22 is not formed, as shown in FIG. 4, marks 40 are printed at equal intervals on one end in the width direction. A sensor 42 for reading the mark 40 is attached on the movement path of the base material 32. By reading the mark 38 with this sensor 42, the transfer amount of the base material 32 can be controlled. FIG. 3 is a diagram showing the flow of the base material 32 and does not accurately represent the direction of the base material 32. Actually, as shown in FIG. 4, the base material 32 is pulled out so that the sensor 42 is disposed on the upper side. Then, on the downstream side of the sensor 42, the base material 32 and the release paper 36 are reversed by the roller 44, and transferred so that the release paper 36 faces up. After that, when the release paper 36 is peeled off, it is transferred with the adhesive layer 22 exposed on the substrate 32.

  The base material 32 from which the adhesive layer 22 is exposed is transferred to the wire sticking device 50. As shown in FIG. 5, the wire sticking device 50 includes a frame 52. The frame 52 includes four leg portions 54 and a top plate portion 56 on the leg portion 54. The base material 32 is passed through the frame 52 in the direction of the arrow. The base material 32 is passed over a table 58 in the frame 52 as shown in FIG. On both sides in the width direction of the base material 32, the table 58 is formed so as to be gradually lowered, and the base material 32 passed over the table 58 is bent so that both sides in the width direction are lowered. It passes through the frame 52.

  An air cylinder 60 is attached to the upper surface of the central portion of the top plate portion 56, and a shaft of the air cylinder 60 is formed to extend into the frame 52. Two pressing tools 62 are attached to the shaft of the air cylinder 60. The pressing tool 62 is formed in an elongated shape along the longitudinal direction of the base material 32 passing through the frame 52. A flexible material such as sponge is attached to the lower surface of the pressing tool 62, and the pressing tool 62 is pressed against the surface of the adhesive layer 22 on the substrate 32 by the operation of the air cylinder 60. A base 62 a of the pressing tool 62 is attached to the shaft of the air cylinder 60. A spring or the like is provided in the base 62a, and when the pressing tool 62 is pressed against the surface of the adhesive layer 22, it is urged toward the adhesive layer 22 by the spring.

  Lower blades 64 for cutting the magnetically sensitive wire 20 are arranged on both sides in the width direction of the base material 32 passed through the frame 52. The lower blade 64 is formed so as to be spanned between support members 66 attached to the inside of the leg portion 54 in the longitudinal direction of the base material 32. Here, the lower blade 64 is disposed above the adhesive layer 22 with its cutting edge slightly inside the widthwise ends of the table 58. Further, an upper blade 68 is slidably attached to the support member 66. The upper blade 68 is formed along the longitudinal direction of the substrate 32, and the magnetic sensitive wire 20 is cut in cooperation with the lower blade 64.

  Further, the base 70 a of another pressing tool 70 is attached to the upper blade 68. The pressing tool 70 is formed in an elongated shape along the upper blade 68, and a flexible material such as sponge is attached to the lower surface thereof. The lower surface of the pressing tool 70 is attached to the upper blade 68 so as to be positioned below the cutting edge of the upper blade 68. When the upper blade 68 is lowered, the pressing tool 70 is pressed against the surface of the base material 32, The blade 68 and the lower blade 64 are engaged. A spring or the like is provided on the base portion 70 a of the pressing portion 70, and when the pressing tool 70 is pressed against the surface of the adhesive layer 22 of the base material 32, the spring 70 is biased toward the adhesive layer 22.

  As shown in FIG. 6, one end of an arm 72 is attached to the upper blade 68, and one end side of an L-shaped arm 74 is attached to the other end of the arm 72. The L-shaped arm 74 is rotatably attached at the bent portion, and a long hole 76 is formed on the other end side. Bolts 80 and the like attached to the rotator 78 are passed through the long holes 76, and the rotator 78 is rotated by a motor or the like. Return to position. Thereby, the arm 72 reciprocates up and down, and the upper blade 68 moves up and down. 6 shows an arm 72, an L-shaped arm 74, a rotating body 78, and the like for one upper blade 68, but the other upper blade 68 has the same configuration.

  Further, on both sides of the frame 52, a moving device 100 for moving the magnetic sensitive wire 20 is arranged. As shown in FIG. 5, the moving device 100 is disposed on both sides in the width direction of the base material 32 passed through the frame 52. As shown in FIG. 7, the moving device 100 includes a rail 102, and a base 104 is attached on the rail 102. The base 104 is formed on the rail 102 so as to reciprocate in the direction of the frame 52.

  A roller 106 is provided on the base 104. A gear 110 is attached to the roller 106 via a one-way clutch 108. The gear 110 is meshed with a rack 112 fixed to the side of the base 104. Therefore, when the base 104 moves in the direction of the frame 52, even if the rotational force is transmitted to the one-way clutch 108 by the combination of the gear 110 and the rack 112, the rotational force is not transmitted to the roller 106. Does not rotate. Conversely, when the base 104 moves away from the frame 52, the roller 106 is rotated by the rotational force transmitted to the one-way clutch 108.

  A holder 114 is formed on the frame 52 side with respect to the roller 106, and a plurality of guide tubes 116 are held by the holder 114. The guide tube 116 extending from the holder 114 is slidably held by a sliding holder 118 attached to the frame 52. In the sliding holder 118, the guide tube 116 slides and is sent out or pulled back to the base material 32 side.

  As shown in FIG. 7, an introduction portion 120 is provided on the opposite side of the holder 114 with respect to the roller 106, and the magnetic sensitive wire 20 is introduced through the introduction portion 120. That is, the magnetic sensitive wire 20 is first passed through the introduction portion 120 and then passed through the guide tube 116 so that the tip thereof reaches the occlusal position between the lower blade 64 and the upper blade 68 through the base 104. This operation is performed by raising (separating) the roller 106 from the base 104. When the magnetic sensitive wire 20 is passed, the roller 106 is lowered so that the magnetic sensitive wire 20 is sandwiched between the base 104 and the roller 106. As the guide tube 116, for example, a tube having an inner diameter of 0.2 mm is used, and as the magnetic sensitive wire 20, for example, a tube having a diameter of 0.16 mm is used. In the frame 52, the tip of the magnetic sensitive wire 20 protrudes from the tip (exit side) of the guide tube 116 and is disposed at the occlusal position of the upper blade 68 and the lower blade 64 as shown in FIG.

  When the base material 32 is sent into the frame 52, the base 104 moves toward the frame 52, and the guide tube 116 slides in the sliding holder 118 as shown in FIG. Move to near the center of the width direction. Since the moving device 100 is provided on both sides of the frame 52, the guide tube 116 moves from both sides in the vicinity of the central portion of the base material 32 in the width direction. When the base 104 moves, the gear 110 and the rack 112 are engaged with each other, but the roller 106 is not rotated by the one-way clutch 108. Therefore, the magnetic sensitive wire 20 sandwiched between the roller 106 and the base 104 moves together with the guide tube 116 to the vicinity of the central portion of the base material 32 in a state in which the distal end portion protrudes from the distal end of the guide tube 116.

  The leading end of the magnetic sensitive wire 20 that has moved is in a state of being opposed in the vicinity of the central portion in the width direction of the base material 32, and as shown in FIG. The tip of the wire 20 is pressed against the adhesive layer 22 of the substrate 32. After that, the base 104 moves away from the frame 52, and the guide tube 116 is also pulled back to the original position as shown in FIG. At this time, since the gear 110 and the rack 112 are engaged with each other, a rotational force is applied to the roller 106 via the one-way clutch 108, and the roller 106 rotates on the magnetic sensitive wire 20. By rotating the roller 106, the magnetic sensitive wire 20 is not fixed by the roller 106 and the base 104, and the magnetic sensitive wire 20 is left pressed by the pressing tool 62, so that it is below the magnetic sensitive wire 20. The base 104 moves so as to slide, and only the guide tube 116 is pulled back.

  Next, the rotating body 78 rotates and the upper blade 68 moves in the direction of the lower blade 64 as shown in FIG. Thereby, first, the portion between the tip portion of the magnetic sensitive wire 20 and the lower blade 64 is pressed against the adhesive layer 22 by the pressing tool 70. Further, when the upper blade 68 moves in the direction of the lower blade 64, as shown in FIG. 12, the upper blade 68 and the lower blade 64 are engaged, and the magnetic sensitive wire 20 is cut. At this time, both end portions in the width direction of the base material 32 are bent, and are disposed on the lower side and slightly outside the cutting edge of the lower blade 64, so that the end of the cut magnetic sensitive wire 20 is the base material. It is arrange | positioned inside 32 both ends of the width direction.

  In this manner, the plurality of magnetic sensitive wires 20 are attached to both sides of the base material 32 in the width direction. When these magnetic sensitive wires 20 are affixed to the base material 32, the pressing tools 62 and 70 and the upper blade 68 are raised, and the tip of the magnetic sensitive wire 20 is at the occlusal position of the upper blade 68 and the lower blade 64. The original state as shown in FIG. Thus, when the magnetic sensitive wire 20 is affixed to the base material 32, the base material 32 moves, and the base material 32 stops when a new surface of the base material 32 enters the frame 52. Such an operation (the operation after paragraph [0029]) is repeated, and the magnetic sensitive wire 20 is continuously attached in the longitudinal direction of the substrate 32. The feed amount of the base material 32 is controlled by reading the mark 40 formed on the end portion of the base material 32 by the sensor 42.

  A laminated body 130 in which the peeling mount 12 and the bonding mount 16 are laminated is laminated on the base material 32 to which the magnetic sensitive wire 20 has been attached via the adhesive layer 22. That is, as shown in FIG. 3, the wound laminated body 130 is drawn out, and the adhesive mount 16 side is overlaid on the adhesive layer 22 of the base material 32. Therefore, the magnetic sensitive wire 20 is sandwiched between the base material 32 and the adhesive mount 16, and the base material 32 and the adhesive mount 16 are adhered by the adhesive layer 22 around the magnetic sensitive wire 20.

  Next, in the cutting device 140, a cut 142 is formed in the base material 32, the adhesive layers 18 and 22, and the adhesive mount 16 of the laminate. That is, a cut 142 is formed from the opposite side of the release mount 12 of the laminate to the surface of the release mount 12. The cut 142 is formed around the magnetic sensitive wire 20, and unnecessary portions outside thereof are peeled from the peeling mount 12 together with the base material 32, the adhesive layers 18 and 22, and the bonding mount 16. The peeled unnecessary portions are removed by being wound by a roller 150, and as shown in FIG. 13, a continuous label body in which the labels 14 are formed so as to form two rows in the width direction of the peeling mount 12 is obtained. The obtained label continuous body is slit at the center in the width direction of the peeling mount 12, and the separated label is wound up by two rollers 152, whereby the label continuous body 10 as shown in FIG. It is to be noted that the label continuous body 10 as shown in FIG. 1 can also be obtained by winding up without slitting at the central portion in the width direction of the peeling mount 12, then rewinding and slitting, and winding up the separated one. Can be obtained. The mark 40 printed on the end portion in the width direction of the substrate 32 is on the unnecessary portion side, and the mark 40 does not remain on the label continuous body 10 by winding up and removing the unnecessary portion. Further, the base material 32 covering the magnetic sensitive wire 20 becomes the surface paper 24 of the label 14.

  In the above-described example, the base material 32 is finally the surface paper 24. However, the base material 32 is a laminated body 130 in which the release mount 12, the adhesive layer 18, and the adhesive mount 16 are stacked. Also good. In this case, the adhesive layer 22 is formed on the adhesive mount 16 of the laminated body 130, and the magnetic sensitive wire 20 is stuck on the adhesive layer 22. And the base material which becomes the surface paper 24 finally is laminated | stacked so that the magnetic sensitive wire 20 may be covered. Thus, as the base material 32, the surface paper 24 side may be used, or the side of the peeling mount 12 and the adhesive mount 16 may be used.

  Further, as the label 14, in the cross-sectional view shown in FIG. 2, the adhesive mount 16 and the adhesive layer 18 are not provided, and the magnetic sensitive wire 20 is attached to the adhesive layer 22 formed on one surface of the surface paper 24. It may be. In the case of the label continuous body 10 having such a label 14, the peeling mount 12 is used in place of the laminate 130 shown in FIG. 3, and the adhesive layer 22 on the substrate 32 to which the magnetic sensitive wire 20 is attached is used. The peeling mount 12 is laminated. Such a label 14 is attached to the article by an adhesive layer 22 around the magnetic sensitive wire 20.

  Furthermore, in the wire sticking device 50 shown in FIG. 5, the moving device 100 may be provided only on one side in the width direction of the base material 32. In such a wire sticking device 50, the guide tube 116 from which the tip of the magnetic sensitive wire 20 protrudes is sent out from one end side in the width direction of the base material 32 toward the other end side. Then, on the other end side in the width direction of the substrate 32, the tip of the magnetic sensitive wire 20 is pressed against the adhesive layer 22 by the pressing tool 62. Therefore, the label continuous body 10 as shown in FIG. 1 is directly manufactured by using such a wire sticking apparatus 50.

  If this manufacturing apparatus 30 is used, a large number of magnetically sensitive wires 20 can be simultaneously adhered on the base material 32, and the label continuous body 10 can be manufactured efficiently. In addition, when the magnetic sensitive wire 20 is stuck on the base material 32, the guide tube 116 through the magnetic sensitive wire 20 is sent out onto the base material 32. It can be stuck on the material 32. Furthermore, since the end portion side in the width direction of the base material 32 is inclined and enters the lower side of the lower blade 64 in the wire sticking apparatus 50, the magnetic sensitive wire 20 is on the inner side than the end portion in the width direction of the base material 32. It is cut at. Therefore, the finally obtained label 14 has a structure in which the magnetic sensitive wire 20 is not exposed at the end. Therefore, the handling of the label 14 is easy and the hand or the like is not damaged. Further, when the magnetic sensitive wire 20 is completely covered with the adhesive mount 16 and the surface paper 24, there is no fear that the magnetic sensitive wire 20 is dropped when the label 14 is attached to an article.

It is a perspective view which shows an example of the label continuous body manufactured with the manufacturing method of this invention. It is sectional drawing of the label continuous body shown in FIG. It is an illustration figure which shows the manufacturing apparatus of the label continuous body of this invention. It is a perspective view which shows an example of the base material drawer | drawing-out part of the manufacturing apparatus shown in FIG. It is a perspective view which shows the wire sticking apparatus of the manufacturing apparatus shown in FIG. It is an illustration figure which shows the inside of the flame | frame used for the wire sticking apparatus shown in FIG. It is a perspective view which shows the moving apparatus used for the wire sticking apparatus shown in FIG. It is an illustration figure which shows the state by which the magnetically sensitive wire and the guide tube were sent out on the base material in a flame | frame. It is an illustration figure which shows the state which pressed down the front-end | tip part of the sent magnetic sensitive wire with a pressing tool. It is an illustration figure which shows the state which left the magnetic sensitive wire and pulled back only the guide tube. It is an illustration figure which shows the state which pressed down the magnetic sensitive wire with another pressing tool between a pressing tool and a lower blade. It is an illustration figure which shows the state which cut | disconnected the magnetic sensitive wire pressed on the base material. It is a perspective view which shows the label continuous body obtained using the wire sticking apparatus shown in FIG. It is a top view which shows the label continuous body which formed the label which has arrange | positioned the magnetically sensitive wire along the longitudinal direction of a peeling mount by the conventional manufacturing method. It is a top view which shows the label continuous body obtained by affixing the label shown in FIG. 14 on another peeling mount. It is an illustration figure which shows the label manufacturing apparatus used for another conventional manufacturing method.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Label continuous body 12 Stripping mount 14 Label 16 Adhesive mount 18 Adhesive layer 20 Magnetic-sensitive wire 22 Adhesive layer 24 Surface paper 30 Manufacturing apparatus 32 Base material 50 Wire sticking apparatus 60 Air cylinder 62 Pressing tool 64 Lower blade 68 Upper Blade 70 Pressing tool 100 Moving device 104 Base 106 Roller 108 One-way clutch 110 Gear 112 Rack 116 Guide tube 130 Laminate 140 Cutting device

Claims (5)

A method for producing a label continuum in which a plurality of labels having magnetically sensitive wires are temporarily attached side by side on a strip-like release mount,
Preparing a belt-like substrate on which an adhesive layer is formed,
Preparing two blades for cutting the magnetically sensitive wire,
Passing the substrate so that the two blades are positioned on the adhesive layer in the vicinity of the widthwise end of the substrate;
From the end in the width direction of the base material toward the center or the other end, the magnetosensitive wire passed through the guide tube is sent out together with the guide tube so that the end of the guide tube protrudes from the end of the guide tube. Process,
Pressing the tip of the magnetically sensitive wire against the adhesive layer;
A method for producing a label continuum, comprising: a step of pulling back only the guide tube while leaving the magnetic sensitive wire on the adhesive layer; and a step of cutting the magnetic sensitive wire with two blades.   The step of cutting the magnetically sensitive wire includes cutting the magnetically sensitive wire in a state in which the tip of the magnetically sensitive wire and the space between the tip of the magnetically sensitive wire and the blade side are pressed against the adhesive layer. The manufacturing method of the label continuous body of Claim 1 characterized by the above-mentioned. Two blades for cutting the magnetic sensitive wire on the adhesive layer in the vicinity of the end in the width direction of the band-shaped base material on which the adhesive layer is formed;
A guide tube for passing the magnetically sensitive wire,
Sending out the magnetosensitive wire passed through the guide tube in the width direction of the base material together with the guide tube, and pulling back only the guide tube while leaving the magnetosensitive wire on the adhesive layer An apparatus for producing a label continuum, comprising: a moving device; and a pressing tool for pressing the tip of the magnetically sensitive wire against the adhesive layer of the substrate.   The manufacturing apparatus of the label continuous body of Claim 3 which further contains another pressing tool for pressing between the front-end | tip part of the said magnetic sensitive wire, and the said blade side against the said adhesive bond layer of the said base material. The moving device includes a base that holds the guide tube and reciprocates in the width direction of the base material, and a roller that sandwiches a portion of the magnetic sensitive wire before entering the guide tube between the base Including
When the base moves toward the substrate, the roller does not rotate, the magnetic sensitive wire is fixed between the roller and the base, and moved together with the base toward the base, The roller rotates when the base moves away from the base material, and the base moves so as to slide under the magnetic sensitive wire so as not to move the magnetic sensitive wire. The manufacturing apparatus of the label continuous body of Claim 3 or Claim 4.

Images