JP2011046121A - Laminated slip body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To securely detect a magnetic mark of each conveyed single-leaf slip without arranging a plurality of magnetic sensors to one single magnetic body mark (magnetic mark), with respect to a laminated slip body formed with a plurality of magnetic body marks for detecting the magnetic marks formed on a plurality of single-leaf slips sealed in a sealing body. <P>SOLUTION: The laminated slip body 11 is formed with a plurality of the magnetic body marks 13A (13B, 13C), is composed by laminating a plurality of the single-leaf slips 12A (12B, 12C) having the magnetic marks magnetized with predetermined magnetic body marks of these magnetic body marks, and makes a magnetic sensor detect the magnetic marks in the laminated form after sealed in the sealing body 14. The predetermined magnetic body marks 13A (13B, 13C) are magnetized by vertical magnetization in the same magnetizing direction to the thickness direction to be the magnetic marks. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a laminated form in which a plurality of magnetic marks for detecting each magnetic mark formed on a plurality of single-leaf forms enclosed in a sealed body is formed.

  In recent years, for example, after a form body is enclosed in a sealed body, it is delivered to individual destinations, and the sealed body is actually filled with a form body in which a plurality of single-leaf forms for each individual destination are stacked or different. Matching inspection is performed to check whether single-leaf forms are mixed. Including such a case, it is necessary to reliably recognize each single-leaf form when performing a matching inspection of the laminated form.

  Conventionally, in order to perform matching of stacked forms encapsulated in a sealing body, a magnetic mark for matching is formed on each single-leaf form, and one of the magnetic marks is magnetized to form a magnetic mark. The following patent documents etc. are proposed to detect non-contact by a magnetic sensor.

  Therefore, FIG. 4 shows an explanatory diagram of magnetic mark detection and magnetic mark detection of a conventional single-leaf form. In FIG. 4 (A), a form body 101 on which single-leaf forms are laminated is enclosed in a sealing body 102. Each single-leaf form 101 is printed with, for example, five magnetic sheets by ink mixed with magnetic powder. The body marks 111A to 111E are connected in a direction perpendicular to the transport direction (width direction), and any one of the magnetic body marks 111A to 111E is magnetized at the same position for each single-leaf form.

  With respect to such a form body 101, any one of the magnetic marks 111A to 111E detected by the mark detection unit 130 that is transported and arranged by the transport means 121 to the mark detection position by the transport means 121 is detected. And matching is performed.

  That is, the mark detection unit 130 corresponds to the magnetic marks 111A to 111E of the stacked form body 101 enclosed in the sealing body 102 being conveyed by the magnetic sensors 131 to 135, respectively. These magnetic sensors 131 to 135 detect the position pattern of the magnetic mark.

  As shown in FIG. 4B, the magnetized magnetic mark (here, the magnetic mark 111A) has a maximum magnetic force in the N extreme portion and the S extreme portion, and the distance from each end portion. Accordingly, the magnetic force gradually decreases, and the magnetic force becomes minimum (zero) at the switching point between the N pole and the S pole. Therefore, the magnetic mark 111A has a detectable detectable range X, X ′ and a non-detectable range Y that is difficult to detect in the vicinity of the switching point with respect to a magnetic sensor (here, the corresponding magnetic sensor 131). Will be included.

JP 2009-057123 A

  However, as shown in FIG. 4A, when the form body 101 is transported on the transport means 121, a so-called abare occurs in the direction perpendicular to the transport direction (width direction), and the magnetic sensor is fixedly arranged. If 131 (132 to 135 is also located) within the non-detection range Y, the output value of the magnetic sensor becomes indistinguishable from noise, and the corresponding magnetic mark may not be detected. There's a problem. In Patent Document 1, in order to solve such a problem, a plurality of magnetic sensors are arranged for one magnetic mark (magnetic mark).

  Accordingly, the present invention has been made in view of the above problems, and can reliably detect the magnetic mark of each single-leaf form to be conveyed without arranging a plurality of magnetic sensors for one magnetic mark (magnetic mark). An object of the present invention is to provide a laminated form having a magnetic mark formed thereon.

  In order to solve the above-mentioned problem, in the invention of claim 1, a plurality of magnetic marks are formed on a single-leaf form, and a predetermined magnetic body mark is magnetized among the magnetic marks. Is a laminated form that allows a magnetic mark to be detected by a magnetic sensor after being stacked and sealed in a sealing body, wherein the predetermined magnetic body mark is perpendicular to the thickness direction in the same magnetization direction. The magnetic mark is magnetized to form the magnetic mark.

  According to the present invention, the magnetic mark formed on each single-leaf form to be a laminated form is magnetized with perpendicular magnetization in the same magnetization direction with respect to the thickness direction to form a magnetic mark. On the surface of the magnetic mark, there is no switching point of the magnetic pole, there is no non-detection range portion where the magnetic force becomes zero, and when the matching is normal, the magnetic force of the magnetic mark of each laminated single-leaf form is superimposed. Since the magnetic sensor detects the magnetic mark, and if the matching is poor, the magnetic force is different and the demagnetizing magnetic force is detected by the magnetic sensor. It can be made possible.

It is a block diagram of the laminated form body which concerns on this invention. It is explanatory drawing of the magnetization of the magnetic body mark of the single-leaf form in FIG. It is explanatory drawing of the magnetic mark detection of the laminated | stacked form body enclosed with the sealing body which concerns on this invention. It is explanatory drawing of the magnetic body mark of the conventional single-leaf form, and a magnetic mark detection.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a configuration diagram of a laminated form according to the present invention. In FIGS. 1A and 1B, the laminated form 11 is composed of, for example, three single-leaf forms 12A to 12C. Each single-leaf form 12A to 12C has, for example, five magnetic shapes that are rectangular in the direction perpendicular to the transport direction when transported later as shown in FIG. The body mark is formed in a continuous state in the vertical direction, and becomes a magnetic body mark group 13A to 13C for each single-leaf form 12A to 12C. FIG. 1B is a conceptual diagram from the side of the laminated form 11, and one magnetic mark 13A-1 (13B-1, 13C-1) constituting the magnetic mark group 13A (13B, 13C). As shown. The magnetic mark can be formed by a general printing technique by mixing magnetic powder such as barium ferrite (Ba ₂ O ₃ Fe ₂ O ₃ ) in printing ink, for example.

  Here, the magnetic marks formed on the single-leaf forms 12A to 12C are not magnetized as they are and become magnetic marks when magnetized. The specific laminated form 11 is enclosed in the sealing body 14 and shipped individually. In the single-leaf form 12A (12B, 12C) of the single laminated form 11, the magnetic group mark 13A (13B, 13C) Among the magnetic marks, the arrangement positions where the magnetic marks are magnetized are the same, and the pattern is set so that this is different for each individual laminated form. That is, if at least one single-leaf form constituting another laminated form is mixed among the single-leaf forms 12A to 12C constituting the predetermined laminated form 11, a magnetic field is applied to the different portions in the arrangement position in the stacked state. Mark will be present.

  Magnetization of the magnetic mark to be used as the magnetic mark is performed in the thickness direction, as shown in FIG. 1C, when the magnetic mark 13A-1 (13B-1, 13C-1) is magnetized. Is performed by perpendicular magnetization in the same magnetization direction. In the figure, the surface (detection side by the magnetic sensor) is the N pole, and the single-leaf form surface side is the S pole. That is, the surface of the magnetic mark is a single pole (shown as N pole, but may be S pole), and there is no switching of poles as shown in FIG. The part that becomes zero is not present.

  As shown in FIG. 1A, the laminated form 11 as described above is enclosed in a sealing body 14, and as shown in FIG. 4A, matching inspection is performed by detecting a magnetic mark with a magnetic sensor. Is done.

  Here, FIG. 2 shows an explanatory diagram of magnetization of the magnetic mark of the single-leaf form in FIG. FIG. 2 (A) shows that the single leaf form 12A (12B, 12C) is stationary with respect to one magnetic body mark 13A-1 (13B-1, 13C-1) formed on the single leaf form 12A (12B, 12C). In this case, the S pole side of the magnetic head 21 perpendicularly magnetized with respect to the corresponding magnetic mark 13A-1 (13B-1, 13C-1) is placed on the magnetic mark 13A-1. By approaching (13B-1, 13C-1), the magnetic mark 13A-1 (13B-1, 13C-1) is perpendicularly magnetized, and the entire surface on the magnetic head 21 side is magnetized to the N pole. Is.

  FIG. 2B shows the magnetization of one magnetic form mark 13A (13B, 13C) formed on the single-leaf form 12A (12B, 12C) while conveying the single-leaf form 12A (12B, 12C). This is the case. In this case, a number of fitting portions 23 corresponding to the magnetic marks 13A (13B, 13C) are formed on the rotating roller 22, and the magnetic head 24 perpendicularly magnetized by the fitting portions 23 at positions corresponding to the magnetization pattern. The S pole is fitted on the front side. That is, the rotating roller 22 that is brought close to the single-leaf form 12A (12B, 12C) that is carried and moved is rotated at the same speed as the carrying speed, so that N is applied to the magnetic mark that is brought close to the magnetic head 24. Magnetization of perpendicular magnetization with the pole as the surface is performed. Alternatively, the rotation roller 22 may be formed in a state where the magnetic head 24 corresponding to the magnetization pattern is embedded in advance, and a predetermined number of rotation rollers 22 corresponding to the magnetization pattern may be prepared.

  Therefore, FIG. 3 shows an explanatory view of magnetic mark detection of the laminated form enclosed in the sealing body according to the present invention. Here, the case where the magnetic material marks 13A-1 (13B-1, 13C-1) formed on the single leaflets 12A (12B, 12C) are magnetized as described above will be described. Further, as the system for detecting the magnetic mark of the single-leaf form 12A (12B, 12C) and performing the matching inspection, the transport means and the magnetic sensor shown in FIG. 4A are applied.

  In FIG. 3A, when, for example, three single-leaf forms 12A-12C constituting the laminated form 11 enclosed in the sealing body 14 are regular, the magnetic marks formed on the single-leaf forms 12A-12C are arranged. Since the magnetic marks 13A-1 (13B-1, 13C-1), which are magnetic marks in the stacking direction, have the same N pole on the surface side, the three magnetic marks are: As shown in the figure, this is the same as one magnetic mark in the stacked state.

  Therefore, the magnetic force of each magnetic mark is superposed by three, and when the magnetic sensor detects this magnetic force, a sensor current corresponding to this is output, and the three single-leaf forms 12A to 12C are sealed. 14 can be determined.

  On the other hand, as described above, for example, when a single sheet of another laminated form is mixed in, as described above, the magnetic force of two magnetic marks is detected and mixed in for two sheets as described above. However, since the arrangement pattern is different for a single leaf form, it is detected by a different magnetic sensor. As a result, the two sheets are legitimate, but one can be determined as not legitimate (defective). Further, even if all three sheets are regular single-leaf forms 12A to 12C, as shown in FIG. 3B, if one sheet (for example, single-leaf form 12C) is turned upside down, the single-leaf forms 12B, 12C The magnetic force is canceled between them, and it can be determined by detecting the demagnetized magnetic force of only the uppermost single-leaf form 12A. Similarly, the front and back of the two sheets are reversed or the front and back are reversed. Even in the case of being degenerated, it is possible to determine a matching failure in a demagnetized state.

  In this way, it is possible to eliminate the non-detection range portion on the entire surface of the magnetic mark formed on the single-leaf form 12A (12B, 12C) read by the magnetic sensor. In addition, when the single-leaf forms 12A (12B, 12C) are stacked and stacked, the reading surface by the magnetic sensor is made to have the same pole so that even if the single-leaf forms 12A (12B, 12C) are displaced due to conveyance, the top and bottom Since the phenomenon of canceling out the magnetic field does not occur, the number of sheets can be detected and determined based on the amount of detection current of the magnetic sensor.

  Further, as shown in FIG. 3B, for example, the single-leaf form 12C is reversed, and the magnetic mark (magnetic material mark 13C-) is placed at the same position in the stacking direction as the magnetic mark (magnetic material marks 13A-1, 13B-1). When 5) is positioned, the sensor reading surface of the magnetic mark (magnetic mark 13C-5) is the S pole. Therefore, the 12B magnetic mark (magnetic mark 13B-1) and magnetic mark (magnetic mark 13C-5) of the single-leaf form have their magnetic forces canceled out, and the magnetic mark (magnetic mark 13A-1) of the single-leaf form 12A. ) Magnetic force is detected by the magnetic sensor.

  Thereby, it can be determined that any one of the laminated forms 11 enclosed in the sealing body 14 is reversed.

  The laminated form of the present invention can be used in the delivery printed matter manufacturing industry that inspects the magnetized magnetic mark among the magnetic marks formed on each single-leaf form in a laminated form in the sealed body.

DESCRIPTION OF SYMBOLS 11 Laminated form body 12 Single-leaf form 13 Magnetic body mark group 14 Sealing body 21,22 Magnetization head

Claims (1)

A plurality of magnetic material marks are formed on a single-leaf form, and a predetermined magnetic body mark among the magnetic body marks is magnetized. After the plurality of single-leaf forms are stacked and sealed in a sealing body, the stacked form And a laminated form for detecting a magnetic mark by a magnetic sensor,
The laminated form body, wherein the predetermined magnetic body mark is magnetized by perpendicular magnetization in the same magnetization direction with respect to the thickness direction to form the magnetic mark.

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