JP6475470B2 - Form continuous paper - Google Patents

Description

  The present invention relates to a continuous form paper in which a plurality of form paper pieces to which an RFID label is attached are continuous.

  A continuous form paper in which a plurality of form paper pieces are continuous is known in which mountain folds and valley folds are alternately repeated so that the plurality of form paper pieces are folded in a bellows shape. The form continuous paper is stored or transported in a state of being folded in a bellows shape. Such a form continuous paper is used by cutting out each form paper piece and may be used with an RFID label or a card attached to each form paper piece. Here, FIG. 11 illustrates the continuous form sheet 101 with the RFID label 111 attached thereto. This continuous form sheet 101 has a long strip shape, and is formed by a plurality of continuous rectangular form sheet pieces 105 via perforations 104 formed at regular intervals in the longitudinal direction. Each form sheet 105 is attached with an RFID label 111 at a position closer to one of the two perforations 104 that define each form sheet piece 105. As the RFID label 111, an RFID label 112 having an IC chip and an antenna (not shown) attached by an adhesive sheet (not shown) is known (see FIG. 5). Since the RFID inlet 112 can communicate with the predetermined communication device (input / output device) in the form sheet piece 105 with the RFID label 111 attached, in recent years, the traffic / leisure field, the logistics field, the security field, It has been introduced in a wide range of fields such as factory production.

  On the other hand, for example, Patent Document 1 has been proposed as a configuration in which a card is affixed to each piece of form paper constituting the form continuous paper. In such a configuration, a card is affixed to each form paper piece, and a sheet piece having the same thickness as the card is affixed, and a plurality of form paper pieces are folded by the sheet piece. Form cards can be prevented from overlapping and locally thickening, and workability during storage and transportation can be improved.

Japanese Patent No. 3310341

  By the way, in the continuous form paper 101 to which the RFID label 111 is attached, the attaching position for attaching the RFID label 111 on each form paper piece 105 is predetermined as shown in FIG. Are set at the same position in all the form paper pieces 105. Such a conventional continuous form sheet 101 is formed by overlapping a plurality of form sheet pieces 105 in an accordion shape as shown in FIG. 12 by alternately repeating a mountain fold and a valley fold of each perforation 104. In addition, a plurality of RFID labels 111 are overlapped in the vertical direction, and a portion where the RFID labels 111 overlap is locally thickened. This is because the IC chip constituting the RFID inlet 112 has a predetermined thickness, and a plurality of the RFID inlets 112 are overlapped in the vertical direction. When a plurality of RFID inlets 112 are overlapped in the vertical direction as described above, the IC chip may receive pressure from the vertical direction due to the thickness or weight of the IC chip of each RFID inlet 112, and the IC chip may be damaged. is there. Further, when a plurality of the continuous form sheets 101 folded as described above are stacked for storage or transportation, the pressure received by the IC chip of the RFID inlet 112 is further increased. There is a further concern about the problem of breakage of the IC chip. Further, when the thickness is increased locally as described above, when a plurality of folded continuous form sheets 101 are stacked, the stacked state tends to collapse, and there is a possibility that a problem occurs in workability during storage and transportation. .

  On the other hand, it is also conceivable to apply the above-described configuration of Patent Document 1 to a configuration in which an RFID label is affixed to a form paper piece. In this case, an RFID label is attached to each form sheet piece, and a sheet piece having the same thickness as the RFID label is attached. According to such a structure, it can prevent becoming thick locally, and there can exist an effect that workability | operativity at the time of storage or conveyance can be improved like the case where a card | curd is stuck. However, in the case of this configuration, since it is necessary to affix the sheet piece separately, an increase in the cost of the sheet piece, an increase in the process of attaching the sheet piece, and the like occur, and productivity is reduced. Furthermore, in the state in which a plurality of form paper pieces are overlapped, the IC chip of each RFID label that is overlapped in the vertical direction is still subjected to pressure due to the weight of each IC chip. Therefore, the problem of damage to the IC chip described above still remains.

  The present invention solves the above-described problems, and reduces the pressure applied to the IC chip of the RFID label in a state of being folded in an accordion shape, thereby suppressing breakage of the IC chip. This is a proposal.

  The present invention includes a plurality of continuous form paper pieces, and each form paper piece is folded in a bellows shape, and an RFID label comprising an IC chip and an antenna connected to the IC chip is provided for each form. In the continuous form papers affixed to one side of a piece of paper, the attachment position of the RFID label affixed to the form paper piece with respect to the form paper piece is different for every other form paper piece. Is a continuous form.

  Here, the present invention includes not only the case where the RFID label is attached to all the form paper pieces of the form continuous paper but also the case where the RFID label is attached to every other form paper piece. Further, “a plurality of form paper pieces are folded in a bellows shape” means that a plurality of form paper pieces are folded by alternately repeating a mountain fold and a valley fold between adjacent form paper pieces. In a state of being folded in a bellows shape, adjacent form paper pieces are opposite to each other, and every other form paper piece is in the same direction. Therefore, as in the conventional configuration described above (see FIGS. 11 and 12), when the RFID label is attached to the same position on all the form paper pieces, the attaching position of the RFID label is between the other form paper pieces. It will be the same. The inventors of the present invention have found such knowledge by earnest study and have reached the present invention based on the knowledge.

  In other words, in the configuration of the present invention, the position of the RFID label applied to every other form paper piece is made different so that the number of RFID labels overlapping in the vertical direction can be reduced when folded in a bellows shape. . Thereby, the number of the form paper pieces interposed between the RFID labels which are overlapped in the vertical direction is increased as compared with the above-described conventional configuration (see FIGS. 11 and 12). The form paper pieces interposed between the RFID labels serve as a buffer material between the RFID labels (IC chips), and the buffering action tends to increase as the form paper pieces increase. Therefore, in the configuration of the present invention, the pressure received by the RFID label (IC chip) that overlaps in the vertical direction can be reduced as compared with the above-described conventional configuration. Therefore, according to the structure of this invention, it can suppress as much as possible that the IC chip of the RFID label which overlaps with an up-down direction in the state which folded the several paper sheet piece in the shape of a bellows.

  In addition, the configuration of the present invention can suppress local thickening in a state of being folded in an accordion-like shape because the RFID label sticking position differs between every other form paper piece. Thereby, workability | operativity at the time of storage or transportation can also be improved.

  Furthermore, the configuration of the present invention is such that the position where the RFID label is attached differs between every other form, and a conventionally known RFID label can be applied. Therefore, in the manufacturing process of the continuous form paper, it is necessary to change only the RFID label attaching position, and other various specification changes are not necessarily required. Therefore, the continuous form paper of the present invention has an excellent advantage that it can be manufactured relatively easily and stably.

  In the above-described continuous form of the present invention, different RFID labels are attached to every other form sheet in a state where a plurality of form sheet pieces are folded in a bellows shape and at least the IC chip of each RFID label is attached. A configuration that is a non-overlapping position is proposed.

  In such a configuration, since the IC chips do not overlap in the vertical direction between every other piece of form paper in the state of being folded in a bellows shape, the effect of suppressing breakage of the IC chip as described above. Can be played. Therefore, for every other form paper piece, if the IC chips do not overlap in the vertical direction, the RFID label affixing position on each form paper piece is set so that the mutual RFID labels partially overlap in the vertical direction Is possible.

  In the above-described continuous form of the present invention, a pair of adjacent form paper pieces have the same RFID label attaching position to the form paper piece, and the pair of form paper pieces are combined with the pair of form paper pieces and the pair of form paper pieces. A configuration is proposed in which the RFID label is attached continuously to another pair of form paper pieces with different attachment positions.

  According to such a configuration, since the RFID label attaching position differs between every other form paper piece, the above-described operational effects of the present invention can be stably exhibited. In addition, since this configuration can be manufactured by attaching RFID labels so that a pair of form paper pieces and another pair of form paper pieces are alternately repeated, the setting change of the attaching position can be minimized. It is possible to suppress the cost required for setting as much as possible.

  In the above-described continuous form paper of the present invention, a set of form paper pieces in which a predetermined number of three or more continuous form paper pieces are connected, and the respective RFID paper label positions on the form paper pieces are mutually determined. In addition, a configuration is proposed in which a plurality of sets of form paper pieces are continuously arranged. Here, each form paper piece constituting a set of form paper pieces has a different RFID label affixing position from each other,

  In such a configuration, each form paper piece constituting a set of form paper pieces has a different RFID label attaching position from each other. Thereby, since the position where the RFID label is applied is different between every other form sheet, the above-described operational effects of the present invention can be stably exhibited. In addition, since this configuration can manufacture a set of form paper pieces in which a predetermined number of form paper pieces are continuous by setting the RFID label application position so as to be repeated continuously, the setting change of the application position is relatively small. It is easy and the cost required for setting the manufacturing process can be suppressed as much as possible.

  As described above, the continuous form paper according to the present invention is such that the position of the RFID label attached to the form paper piece is different for every other form paper piece. When the form piece is folded in a bellows shape, the number of RFID labels that overlap at the same position in the vertical direction can be reduced as compared with the conventional configuration described above. This increases the number of form paper pieces interposed between the RFID labels that overlap in the vertical direction in the folded state of the bellows, and the IC chip of the RFID label is damaged by the buffering action of the form paper pieces. It can be suppressed as much as possible.

FIG. 3 is a plan view showing the form continuous paper 1 according to the first embodiment. It is explanatory drawing which shows the state which repeats the mountain fold and valley fold of the perforation 4 alternately. It is explanatory drawing which shows the state which folded the some form paper piece 5a, 5b in the bellows shape. It is the X section enlarged view of FIG. FIG. 3 is a plan view of the RFID label 11 with a part of an adhesive sheet 13 cut out. It is a graph which shows the experimental result which verified the buffering effect of the base material of a form paper piece. FIG. 6 is a plan view showing a form continuous paper 51 of Example 2. It is explanatory drawing which shows the state which folded the some form paper piece 55a-55c in the bellows shape. It is the Y section enlarged view of FIG. It is a top view which shows the form continuous paper 81 of another example. It is a top view which shows the form continuous paper 101 of a conventional structure. It is explanatory drawing which shows the state which folded the paper sheet piece 105 of the conventional structure in the shape of a bellows.

Embodiments according to the present invention will be described according to the following Examples 1 and 2.
In Examples 1 and 2 below, the longitudinal direction of the continuous form paper is a direction in which a plurality of continuous form paper pieces are continuous, and the direction orthogonal to the longitudinal direction is the width direction of the continuous form paper and the form paper pieces. . In the individual form paper pieces, the continuous direction will be described as the front-rear direction. The direction in which a plurality of form paper pieces are stacked in a state in which each form paper piece of the continuous form paper is folded in a bellows shape will be described as the vertical direction. It should be noted that the present invention is not limited to use in such a defined direction.
Further, “overlapping in the vertical direction” to be described later is a state of being folded in an accordion shape, and the positions on the paper surface of the respective paper sheets stacked in the vertical direction substantially coincide with each other in the vertical direction. It means overlapping or overlapping at a predetermined interval in the vertical direction.

  The form continuous paper 1 according to the first embodiment is made of a long belt-like rectangular paper made of high-quality paper or the like. As shown in FIG. 1, a plurality of perforations 4 that cross in the width direction are formed in the continuous form 1 at regular intervals in the longitudinal direction. The perforation 4 is formed so as to be foldable and cuttable, and rectangular form paper pieces 5a and 5b are respectively formed by portions separated by two adjacent perforations 4 and 4. In this way, the continuous form sheet 1 is formed by a plurality of continuous form sheet pieces 5 a and 5 b through the perforation 4.

  As shown in FIG. 2, the continuous form paper 1 has a plurality of perforations 4 alternately and repeatedly folded in a mountain and a valley, thereby forming a plurality of continuous form paper pieces 5a and 5b in a bellows shape as shown in FIG. Can be folded. Folding in a bellows shape in this way is advantageous in storage space and transportation work, and therefore has the advantage that workability during storage and transportation can be improved.

  The form continuous paper 1 is printed with predetermined information on a front cover surface and / or back paper surface of each form paper piece 5a, 5b by a printer or the like. Then, by cutting the perforation 4, the form paper piece 5 can be separated and used. In addition, since the well-known thing can be applied to such a form continuous paper 1 conventionally, the detail is abbreviate | omitted.

  In the first embodiment, the RFID label 11 is attached to each continuous form sheet piece 5a, 5b on the form continuous sheet 1. The RFID label 11 is composed of an RFID inlet 12 and an adhesive sheet 13 as shown in FIG. Here, the RFID inlet 12 includes an IC chip 15 and an antenna 16 connected to the IC chip 15 on a synthetic resin film (not shown). The RFID inlet 12 is a non-contact type battery-less type capable of transmitting and receiving signals such as commands and data in a non-contact manner using an electromagnetic wave with an input / output device (reader / writer device) (not shown). Commands and data communicated with the input / output device are stored in the memory of the IC chip 15. A small antenna such as a dipole antenna or a meander line antenna can be applied to the antenna 16. And the antenna length etc. of this antenna 16 are suitably set according to the electromagnetic waves used for communication of the RFID inlet 12.

  The pressure-sensitive adhesive sheet 13 is obtained by applying a pressure-sensitive adhesive with a substantially uniform thickness to the entire surface of one side of a rectangular synthetic resin film. And the adhesive sheet 13 is set so that the area may become a size larger than said RFID inlet 12. FIG. The above-described RFID label 11 is configured by adhering such an adhesive sheet 13 to the RFID inlet 12 such that the application surface of the adhesive faces the RFID inlet 12. Since the RFID label 11 can be a known one, it will not be described in detail.

  Here, in all RFID labels 11 used in the first embodiment, the RFID inlet 12 is disposed at a substantially central portion of the adhesive sheet 13. Therefore, as described later, when a plurality of RFID labels 11 overlap in the vertical direction, the respective RFID inlets 12 and IC chips 15 constituting the RFID labels 11 overlap in the vertical direction.

  As shown in FIG. 1, such RFID labels 11 are attached to the front cover surfaces (or back paper surfaces) of the respective slip paper pieces 5 a and 5 b constituting the continuous slip paper 1. In the first embodiment, two different application positions 31a and 31b are set as positions where the RFID labels 11 are applied to the respective form paper pieces 5a and 5b. Then, the pasting positions 31a and 31a are respectively set on the pair of first form paper pieces 5a and 5a adjacent to each other through one perforation 4, and another pair of adjacent to each other through the other perforation 4. The pasting positions 31b and 31b are respectively set on the second form paper pieces 5b and 5b. That is, in the pair of first form paper pieces 5a and 5a, the pasting positions 31a and 31a are determined at the same position on the respective paper surfaces, and in the pair of second form paper pieces 5b and 5b, the pasting positions 31a and 31a are pasted at the same positions on the respective paper surfaces. Positions 31b and 31b are defined. The form continuous paper 1 according to the first embodiment is formed by alternately connecting the pair of first form paper pieces 5a and 5a and the pair of second form paper pieces 5b and 5b, and each of the first form paper pieces 5a. The RFID label 11 is affixed to the affixing position 31a and the affixing position 31b of each second form sheet piece 5b.

  Here, the attachment positions 31a and 31b of the RFID label 11 are positions set on the paper surface of the form paper pieces 5a and 5b, both of which are adjacent two perforations 4, which divide the form paper pieces 5a and 5b. 4 is set close to one perforation 4. That is, the RFID label 11 is affixed to each form paper piece 5a, 5b near the perforation 4 on the same side in the front-rear direction. The pasting position 31a set for the pair of first form paper pieces 5a, 5a is determined at a predetermined position close to the one perforation 4. Further, the pasting position 31b set for the pair of second form paper pieces 5b, 5b is determined at a position farther from the one perforation 4 than the pasting position 31a of the form paper piece 5a, and the pasting position 31a. More central. Thereby, the sticking position 31a of the first form paper piece 5a and the sticking position 31b of the second form paper piece 5b are different from each other in the front-rear direction. Therefore, the RFID inlet 12 and the IC chip 15 of the RFID label 11 attached to the attaching position 31a and the RFID inlet 12 and the IC chip 15 of the RFID label 11 attached to the attaching position 31b are mutually different from each other. They are arranged at different positions on the paper surface of 5a and 5b. In the first embodiment, if the form paper pieces 5a and 5b are stacked vertically so that the positional relationship in the front-rear direction is the same, the RFID label 11 attached to the application position 31a and the application position Each attachment position 31a, 31b is set so that the RFID label 11 attached to 31b does not overlap at all in the vertical direction (see FIG. 4).

  Since the form continuous paper 1 of the first embodiment is a series of the first form paper pieces 5a and 5a and the pair of second form paper pieces 5b and 5b alternately arranged as described above, the first form paper pieces 5a. And second form sheet pieces 5b are repeatedly present. The pair of first form paper pieces 5a and 5a constitutes a pair of form paper pieces of the present invention, and the pair of second form paper pieces 5b and 5b constitutes another pair of form paper pieces of the present invention. In addition, the front surface (or the back surface) of the form paper pieces 5a and 5b to which the RFID label 11 is attached is one side of the form paper piece according to the present invention.

  As described above, when the form paper pieces 5a and 5b of the continuous form paper 1 are folded in a bellows shape, the cover surfaces of the adjacent first form paper pieces 5a and 5a face each other as shown in FIG. Since they overlap each other (or the back paper surfaces face each other and overlap), the positional relationship between the two in the front-rear direction is opposite to each other. Therefore, the RFID labels 11 and 11 attached to the pair of adjacent first form paper pieces 5a and 5a do not overlap in the vertical direction. Similarly, even if it exists in a pair of adjacent 2nd form paper pieces 5b and 5b, since the front-back positional relationship of both becomes reverse, the RFID labels 11 and 11 each affixed to these do not overlap in the up-down direction. . Furthermore, similarly, since the front-rear positional relationship between the first form paper piece 5a and the second form paper piece 5b is opposite to each other, the RFID labels 11, 11 affixed to them are respectively in the vertical direction. It does not overlap.

  Further, in the state of being folded in the shape of a bellows as described above, the first and second form paper pieces 5a and 5b are arranged so that their positional relations in the front-rear direction are mutually as shown in FIGS. The same direction. Here, the pasting position 31a of the first form paper piece 5a and the pasting position 31b of the second form paper piece 5b are different from each other in the front-rear direction as described above. Therefore, even when the first form paper piece 5a and the second form paper piece 5b have the same positional relationship in the front-rear direction when folded in a bellows shape, the RFID label affixed to the first form paper piece 5a 11 and the RFID label 11 attached to the second form sheet piece 5b do not overlap in the vertical direction.

  Further, in the state of being folded in the shape of a bellows as described above, the form paper pieces 5a and 5b arranged every other are in the same direction in the front-rear direction. That is, the pair of first form paper pieces 5a and 5a and the pair of first form paper pieces 5a and 5a that are separated from the pair of second form paper pieces 5b and 5b that are continuous with each other have a positional relationship in the front-rear direction. The same direction. Similarly, the pair of second form paper pieces 5b, 5b and the pair of second form paper pieces 5b, 5b separated from the pair of first form paper pieces 5a, 5a continuous with each other have a positional relationship in the front-rear direction. They are in the same direction. In this way, in the first form paper pieces 5a, 5a that are in the same direction in the front-rear direction, the RFID labels 11 (IC chips 15) attached to the respective attachment positions 31a, 31a overlap in the vertical direction, and mutually in the front-rear direction. In each second form paper piece 5b, 5b having the same orientation, the RFID label 11 (IC chip 15) affixed to each affixing position 31b, 31b overlaps in the vertical direction.

  Between the two first form paper pieces 5a, 5a that are in the same direction in the front-rear direction, there are three pairs of second form paper pieces 5b, 5b and one first form paper piece 5a. For this reason, four base materials (paper materials) of the form paper pieces 5a and 5b are interposed between the upper and lower sides of the RFID labels 11 and 11 which are attached to the two first form paper pieces 5a and 5a and overlap in the vertical direction. . Similarly, three of a pair of first form paper pieces 5a, 5a and one second form paper piece 5b are interposed between the upper and lower sides of two second form paper pieces 5b, 5b that are in the same direction in the front-rear direction. Four substrates are interposed between the upper and lower sides of the RFID labels 11 and 11 that are attached to each other and overlap in the vertical direction. The intervening base material includes the base material to which one RFID label 11 is attached.

Here, the configuration of the first embodiment described above is compared with the above-described conventional form continuous sheet 101. FIG.
As shown in FIG. 11, the conventional continuous form paper 101 is made of a long rectangular paper made of high-quality paper or the like, and a plurality of form paper pieces 105 are continuously connected through the perforation 104 as shown in FIG. It will be. Each form paper piece 105 has an RFID label 111 attachment position (not shown) at a position near one of the two perforations 104, 104 that divides the form paper piece 105. It has been established. This pasting position is set at a position close to the one perforation 4, and is the same for all the form paper pieces 105. For comparison with the first embodiment, this conventional configuration is the same as that in the first embodiment except that the RFID label 111 is attached to the same position in all the form paper pieces 105. In such a conventional configuration, when a plurality of form paper pieces 105 are folded in a bellows shape, the RFID label 111 (IC chip of the RFID inlet 112) is placed on every other form paper piece 105, 105 as shown in FIG. Overlapping in the vertical direction. In this case, two base sheets of the form paper piece 105 are interposed between the upper and lower sides of the RFID labels 111 and 111 that overlap in the vertical direction.

  In the configuration of the first embodiment described above, there are four base materials (paper materials for the form paper pieces 5a and 5b) interposed between the RFID labels 11 and 11 that are vertically stacked in a state of being folded in a bellows shape, In the above-described conventional configuration, there are two base materials (paper materials for the form paper piece 105) interposed between the RFID labels 111 and 111 that overlap in the vertical direction. The relationship between the number of intervening substrates and the pressure received by the RFID labels that overlap in the vertical direction was confirmed by experiments.

This experiment was performed by using a sample in which an RFID label was sandwiched between high-quality papers and applying a pressure from above the sample to measure the load at which the IC chip of the RFID label was damaged. Here, the sample (specimen) is one in which an RFID label is affixed on the surface of a piece of high-quality paper, and the high-quality paper is stacked so as to be sandwiched from both the upper and lower sides. Three different types were used. Details are as described in (1) to (3) below. In addition, as a device for applying pressure, a digital force gauge was used, and a steel ball having a diameter of 2 mm was attached to the tip of the probe.
(1) Sample A: One sheet of high-quality paper sandwiched from above and below (2) Sample B: Three sheets of high-quality paper sandwiched from above and below (3) Sample C: Each of five sheets of high-quality paper sandwiched from above and below In the case of high quality paper, paper having a continuous weight of 86 kg and a thickness of 100 μm was used, and “SMARTRAC Belt iM PAPERFACE” was used for the RFID inlet of the RFID label.
As an experimental method of this experiment, the sample is placed at a predetermined position on a test table, and a point pressure is applied from above by pressing a steel ball with the device. At this time, the steel ball is pressed from directly above the IC chip of the RFID label of the sample. During the experiment, a predetermined signal was continuously read from the IC chip by a predetermined input device (reader device), and when the reading could not be performed, the IC chip was broken, and the load at that time was measured. Here, it is confirmed that the IC chip is destroyed after the experiment. The number of samples of each sample A, B, C is 5 (n number = 5).
The result of this experiment is shown in FIG. The fracture load of the experimental result is an average value of n number = 5. In this experimental result, the breaking load of sample A is the lowest and the breaking load of sample C is the highest. As the number of high quality papers sandwiching the RFID label from above and below increases, the breaking load of the IC chip tends to increase. Thus, it can be seen that the high-quality paper sandwiching the RFID label from above and below works as a buffer material, and the buffering action tends to increase as the number of the high-quality paper increases.

  According to these experimental results, when a plurality of form paper pieces are folded in a bellows shape as described above, the IC chip of the RFID label moves up and down as the number of base materials of the form paper pieces interposed between the RFID labels increases. It can be seen that the effect of relaxing the pressure received from the direction is increased. That is, in the configuration of the first embodiment, compared to the above-described conventional configuration (FIGS. 11 and 12), the number of base materials interposed between the RFID labels 11 and 11 overlapping in the vertical direction is doubled. The pressure received by the IC chip 15 of the RFID label 11 from above and below in the state of being folded in a bellows shape can be reduced.

As described above, the configuration of the first embodiment is such that a pair of first form paper pieces 5a and a pair of second form paper pieces 5b are alternately continued, and the first form paper pieces 5a and the second form paper pieces 5b are mutually connected. Since the RFID label 11 is attached to the different application positions 31a and 31b, the application position of the RFID label 11 is different between every other form paper piece 5a and 5b. According to this configuration, in the state in which the form paper pieces 5a and 5b are folded in a bellows shape, every other form paper piece 5a and 5b has the same positional relationship in the front-rear direction, but the pasting positions 31a and 31b. Therefore, the RFID labels 11 and 11 attached to each other do not overlap in the vertical direction. In the configuration of the first embodiment, three form paper pieces 5a and 5b are interposed between the first form paper pieces 5a and 5a or between the second form paper pieces 5b and 5b whose positional relationships in the front-rear direction are the same. Therefore, four base materials (paper materials of form paper pieces) are interposed between the RFID labels 11 and 11 that overlap in the vertical direction, and the number of the interposed base materials increases as compared with the above-described conventional configuration. As described above, according to the configuration of the first embodiment, it is possible to reduce the number of RFID labels 11 overlapping in the vertical direction in a state in which the form paper pieces 5a and 5b are folded in a bellows shape. The pressure acting on the IC chip 15 from above and below can be reduced. Therefore, it is possible to suppress as much as possible that the IC chip 15 of each RFID label 11 is damaged by the pressure when folded in the bellows shape.
Furthermore, in the configuration of the first embodiment, when the pasting positions 31a and 31b set on the respective form paper pieces 5a and 5b are set near one perforation 4 in the front-rear direction, when folded in a bellows shape Adjacent form paper pieces 5a and 5b are opposite to each other. Therefore, it is possible to suppress a local increase in thickness due to the plurality of RFID labels 11 overlapping in the vertical direction. Furthermore, since the pasting position 31a and the pasting position 31b are set at different positions in the front-rear direction, the above-mentioned local thickness increase can be further suppressed. By suppressing the local increase in thickness in this way, it becomes difficult to collapse when stacking a plurality of continuous paper sheets 1 folded in a bellows shape during storage or transportation, and the storage and transportation. Workability can be improved.

  Note that the continuous form 1 of the first embodiment described above forms perforations 4 at regular intervals on a long strip of rectangular paper constituting the continuous form 1 and attaches a pre-manufactured RFID label 11 thereto. It can manufacture by sticking to the positions 31a and 31b, respectively. That is, the conventional manufacturing process can be applied except for the process of attaching the RFID label 11 to the attaching positions 31a and 31b. The step of attaching the RFID label 11 can be performed by setting the attaching positions 31a and 31b using a predetermined attaching device. As described above, the continuous form 1 of the first embodiment can be manufactured relatively easily and stably while suppressing an increase in cost required for manufacturing.

  The form continuous paper 51 of the second embodiment is formed of a long belt-like rectangular paper as in the first embodiment, and a plurality of perforations 4 are formed via a plurality of perforations 4 formed at regular intervals as shown in FIG. Form paper pieces 55a to 55c are continuously formed. As will be described later, the configuration of the second embodiment is the same as that of the first embodiment described above except for the attaching positions 61a to 61c of the RFID label 11 to be attached to the form paper pieces 55a to 55c. Omitted.

  In the second embodiment, three form paper pieces 55a to 55c in which three different sticking positions 61a to 61c are set are continuously arranged in a predetermined order through the perforation 4, and further, the three continuous form paper pieces are provided. 55a-55c is made into one set, and this set of form paper pieces 55a-55c is repeated continuously. Therefore, the adhering positions 61a to 61c of the RFID label 11 are different between adjacent form paper pieces and every other form paper piece. Here, the application position 61a of the RFID label 11 on the form sheet piece 55a is set to a predetermined position close to one perforation 4 that divides the form sheet piece 55a. In addition, the application position 61b of the RFID label 11 on the form paper piece 55b is set at a predetermined position farther from one perforation 4 that divides the form paper piece 55b than the application position 61a of the form paper piece 55a. In addition, the application position 61c of the RFID label 11 on the form paper piece 55c is set at a predetermined position farther from one perforation 4 that partitions the form paper piece 55c than the application position 61b of the form paper piece 55b. Each of the pasting positions 61a to 61c is a position different from each other in the front-rear direction of each form paper piece 55a to 55c, and each is closer to one perforation 4 than the center in the front-rear direction of each form paper piece 55a to 55c. It is in. Even in the second embodiment, if the three form paper pieces 55a to 55c are stacked one above the other so that the positional relationship in the front-rear direction is in the same direction, the three sheets affixed respectively. The pasting positions 61a to 61c are set so that the RFID label 11 does not overlap at all in the vertical direction.

  When the form paper pieces 55a to 55c of the continuous form paper 51 are folded in a bellows shape, as shown in FIGS. 8 and 9, every other form paper piece 55a, 55c, every other form paper piece 55b, 55a, In the alternate form paper pieces 55c and 55b, the positional relationship in the front-rear direction is the same. However, in these alternate form paper pieces 55a to 55c, the mutual sticking positions 61a to 61c are different, so that the RFID labels 11 attached to each other do not overlap in the vertical direction. Since the adjacent form paper pieces 55a to 55c are opposite in the positional relationship in the front-rear direction as in the first embodiment, the RFID labels 11 attached to each other do not overlap in the vertical direction.

  In the configuration of the second embodiment, three continuous form paper pieces 55a to 55c are set as one set, and this set of form paper pieces 55a to 55c is repeated continuously. The two form paper pieces 55a and 55a, the two form paper pieces 55b and 55b, or the two form paper pieces 55c and 55c are each provided with five form paper pieces 55a to 55c. In other words, six sheets of paper sheets 55a to 55c are interposed between the two RFID labels 11 and 11 that are overlapped in the vertical direction while being folded in a bellows shape. In this case, as compared with the above-described conventional configuration (see FIGS. 11 and 12), the number of base materials interposed between the two RFID labels 11 overlapping in the vertical direction is tripled. Therefore, according to the above-described experimental result (see FIG. 6), the pressure received by the IC chip 15 of the RFID label 11 that overlaps in the vertical direction can be reduced as compared with the conventional configuration.

As described above, the continuous form paper 51 of the second embodiment can reduce the number of RFID labels 11 that overlap in the vertical direction in a state of being folded in a bellows shape, and therefore, between the two RFID labels 11 that overlap in the vertical direction. Form paper pieces 55a to 55c interposed in the number increase compared to the conventional configuration described above. Therefore, the pressure received by the IC chip 15 of the RFID label 11 from the vertical direction can be relaxed by the buffering action of the base material of the form paper pieces 55a to 55c. Therefore, it is possible to suppress as much as possible that the IC chip 15 of each RFID label 11 is damaged by the pressure when folded in the bellows shape. Furthermore, in the configuration of the second embodiment, since the number of base materials interposed between two RFID labels 11 that overlap in the vertical direction is larger than that of the first embodiment, the pressure received by the IC chip 15 of the RFID label 11 is as follows. Can be further reduced, and the effect of preventing breakage of the IC chip 15 is further improved.
Even in the configuration of the second embodiment, the number of RFID labels 11 overlapping in the vertical direction can be reduced as in the first embodiment described above, and therefore, the local thickness generated when a plurality of the RFID labels 11 are stacked. Can be suppressed.
As described above, even in the configuration of the second embodiment, the same operational effects as those of the first embodiment described above can be exhibited.

  Note that the form continuous paper 51 of the second embodiment is the same as the first embodiment except that the pasting positions 61a to 61c of the RFID label 11 are set. It is possible to manufacture relatively easily and stably while suppressing an increase in cost required.

  In the configurations of the first and second embodiments described above, the mutually different application positions are folded in a bellows shape, and the RFID labels attached to the application positions of every other form paper piece are completely overlapped in the vertical direction. However, the present invention is not limited to this, and each sticking position may be set so that only the adhesive sheet of the RFID label partially overlaps. Also in this case, the RFID inlet of the RFID label does not overlap in the up-down direction in every other form paper piece in which the positional relationship in the front-rear direction is the same as each other in the state of being folded in a bellows shape. Therefore, as in the first and second embodiments, the pressure received by the IC chip of the RFID inlet can be reduced, and the effect of preventing the IC chip from being damaged by the pressure is exhibited. Furthermore, as for the position where each RFID label is attached to every other form, the RFID inlet antennas are partially connected if the IC chip of the RFID label does not overlap in the vertical direction when folded in a bellows shape. It is also possible to set so as to overlap each other. Also in this case, since the IC chips do not overlap with each other in the vertical direction, the effect of preventing breakage of the IC chips can be exhibited.

  Further, in the configurations of the first and second embodiments described above, the pasting position for pasting the RFID label is set to be different in the front-rear direction. However, the present invention is not limited to this and can be variously set. is there. For example, different pasting positions can be set in the width direction of the form paper pieces, and a specific configuration is shown in FIG. 10 as another example of the first embodiment. This another form continuous sheet 81 is composed of a pair of first form paper pieces 85a and 85a and a pair of second form paper pieces 85b and 85b that are alternately continuous, and the first form paper piece 85a has an RFID label. 11 affixing positions 91a are set, and the affixing positions 91b of the RFID labels 11 are set on the second form paper piece 85b. Each of the pasting positions 91a and 91b is located near one of the two perforations 4 and 4 that divides the form paper pieces 85a and 85b, and the pasting position 91a is closer to one side end in the width direction. The sticking position 91b is set at a predetermined position near the opposite side end in the width direction. Even in the configuration of this other example, since the pasting positions 91a and 91b are different between the other first form paper piece 85a and the second form paper piece 85b, as in the first embodiment described above, Four base materials (paper material of form paper pieces) are interposed between the RFID labels 11 and 11 which overlap in the direction. Therefore, even if it has the structure of another example, there can exist an effect similar to Example 1 mentioned above.

  Note that, as described above, the attaching position for attaching the RFID label can be set as appropriate. However, when the RFID label application position is set at the center in the front-rear direction of the form paper piece, the two form paper pieces having the center as the attachment position need not be adjacent to each other through the perforation. This is because the center positions in the front-rear direction overlap each other by folding adjacent form paper pieces even if the positional relationships in the front-rear direction are opposite to each other. For this reason, in the configuration of the first embodiment described above, the RFID label attaching position is not set at the center in the front-rear direction of the form sheet piece. On the other hand, in the configuration of the second embodiment described above, the RFID label application position can be set at the center in the front-rear direction of the form paper piece.

  Moreover, in the structure of Examples 1 and 2 described above, the RFID label 11 is a structure in which the RFID inlet 12 and the adhesive sheet 13 attached on the RFID inlet 12 are integrated. Not limited to this, it is also possible to use RFID labels having other configurations. For example, the RFID label is formed by sticking a piece of paper having substantially the same shape as the RFID inlet on the same RFID inlet as in the embodiment, and applying an adhesive to the back surface of the synthetic resin film constituting the RFID inlet. It is also good. Even when the RFID label having such a configuration is used, the same operational effects as those of the first and second embodiments can be obtained.

  Further, in the configuration of the above-described embodiment 2, the combination of three consecutive form paper pieces having different RFID label attaching positions is sequentially repeated, but is not limited thereto. You may make it repeat continuously the combination which followed four form paper pieces from which affixing positions mutually differ, and five form paper pieces etc. sequentially. The number of form sheet pieces in such a combination can be set as appropriate by three or more.

  In this invention, it is not limited to the Example mentioned above, About the structure other than the above-mentioned Example, it can change and implement suitably within the range of the meaning of this invention. For example, a plurality of form paper pieces constituting the continuous form paper use a pair of adjacent form paper pieces as one form, and the present invention can also be applied to a configuration in which RFID labels are attached to every other form paper piece. In this configuration, the RFID label application position is different between every other form sheet to which the RFID label is attached.

1, 51 Form continuous paper 5a First form paper piece 5b Second form paper piece 11 RFID label 12 RFID inlet 13 Adhesive sheet 15 IC chip 16 Antenna 31a, 31b, 61a, 61b, 61c Affixing position 55a, 55b, 55c Form paper piece

Claims (1)

A plurality of continuous form paper pieces, each form paper piece being folded in a bellows shape, and an RFID label comprising an IC chip and an antenna connected to the IC chip is provided on one side of each form paper piece In the continuous form papers affixed to the paper,
The RFID label to be affixed to the form paper piece is attached to the form paper piece so that every other form paper piece is different,
Further, the RFID label sticking position for every other form paper piece is a position where at least the IC chip of each RFID label does not overlap in a state where a plurality of form paper pieces are folded in a bellows shape,
The adhering position of the RFID label to the adjoining pair of form paper pieces is the same, and the pair of form paper pieces is another pair of adhering positions of the pair of form paper pieces and the RFID label different from each other. Form continuous paper characterized by being continuous with the form paper piece.

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