JP4784193B2 - Print media - Google Patents

Description

  The present invention relates to a printing medium that is formed in a long shape and has a perforation that can be separated for each fixed printing area, and in particular, with respect to a printing surface that is printed by a printing apparatus, a mountain fold at a fixed folding interval. The present invention relates to a so-called continuous print medium in which valley folding is alternately repeated and folded.

2. Description of the Related Art Conventionally, some printing media printed by a printing device or the like have a perforation and can be separated for each predetermined unit area. In such a print medium, it is possible to obtain a print result in a fixed form by making it possible to separate the print medium every predetermined unit area. Therefore, the printing medium as described above is used for a medium preferably having a certain shape such as a name tag.
As such a printing medium, there is an invention described in Patent Document 1. Patent Document 1 describes a printing label continuum in which a perforation is formed for each unit printing area, and a unit label piece having a unit printing area can be obtained by separating along the perforation. .
In Patent Document 1, when printing is performed using a continuous printing label, if the amount of print data is larger than the amount of data that can be printed by a unit label piece, printing is performed across a plurality of unit labels. To do. Therefore, the user can obtain a label group having a print area that is an integral multiple of the print area of the unit label piece, on which desired print data is printed, using the continuous print label described in Patent Document 1.
JP 2000-318239 A

  On the other hand, there are various types of printing media such as cut paper and roll paper in the printing apparatus. In this regard, there is a continuous print medium as a type of print medium used in the printing apparatus. This continuous printing type print medium is a print medium that is folded by alternately repeating a mountain fold and a valley fold at a constant interval with respect to the print surface. Therefore, when using a continuous printing medium in the printing device, the continuous printing medium is stored in the storage unit in a folded state, and one end of the continuous printing medium is pulled out from the storage unit. Used continuously.

Here, in the printing label continuum described in Patent Document 1, it is used as a continuous printing medium by performing a mountain fold or a valley fold on the printing surface for each of a plurality of unit label pieces. Can do.
However, in the continuous label body for printing described in Patent Document 1, all the label perforations that divide the unit label pieces are in the same mode. Here, since the label perforation is intended only for the purpose of separating the label pieces or the label group, it is difficult to perform the mountain fold and the valley fold based on the label perforation.
In particular, as in Patent Document 1, when printing is performed across a plurality of unit label pieces, since the printing may be performed on the label perforation, the label perforation is made fine and the label is perforated. The print result on the perforation must be legible. In this case, folding based on fine perforations is also difficult to perform.

  When the printing label continuum described in Patent Document 1 is bent at a label perforation and used as a continuous printing medium, the bent label perforation is deformed based on the bending. In this respect, irregularities occur on the printed surface regardless of whether the label perforation is a mountain fold or a valley fold. The printing content printed on the label perforation is deteriorated to such an extent that the printing content is unreadable.

  Therefore, the present invention has been made in view of the above-described problems, and relates to a continuous printing medium formed in a long shape and having a perforation that can be separated for each predetermined printing area. It is an object of the present invention to provide a print medium that can be easily bent in accordance with the above-described method and can perform printing control on a bent portion in a printing apparatus.

The invention according to claim 1, which has been made to solve the above-mentioned problems, is formed in a long shape, and a mountain fold and a valley fold are alternately repeated at a constant folding interval on a printing surface printed by a printing apparatus. In the printing medium folded and folded, for each unit piece having a fixed printing area, the inside of the folding interval is divided into a plurality of sections, and the first cutting portions where the printing medium is cut are intermittently arranged. A cut perforation corresponding to the folding interval, and a second perforation formed by cutting the print medium intermittently arranged, and having a lower strength than the cut perforation; , have a, the width direction dimension of the non-cutting portion sandwiched between the second cutting portion adjacent the perforation folded, the width of the uncut portion sandwiched between the first cutting portion adjacent in the separating perforations Smaller than directional dimension Made is characterized in that is.

  According to a second aspect of the present invention, in the print medium according to the first aspect, the transport direction dimension of the second cutting part is formed larger than the transport direction dimension of the first cutting part. Features.

The invention according to claim 3 is characterized in that, in the printing medium according to claim 1 or 2 , the folding perforation is provided with a folding habit according to a folding state of a mountain fold or a valley fold. To do.

According to a fourth aspect of the present invention, in the print medium according to any one of the first to third aspects, the position of the unit piece within the folding interval is indicated on the back surface of the print surface of the unit piece. A sensor mark is attached.

That is, the printing medium according to claim 1 is formed in a long shape, and is a printing medium in which a mountain fold and a valley fold are alternately repeated at a certain folding interval with respect to a printing surface printed by the printing apparatus. By the separation perforation, the inside of the bending interval can be divided into a plurality of unit pieces each having a fixed printing area, and the unit pieces can be separated. The fold portion corresponding to the fold interval is formed with a fold perforation having a lower strength than the separation perforation, so that the print medium can be easily folded at the fold portion, Can be easily folded based on the spacing.
Moreover, since the 2nd cutting part from which the printing medium was cut | disconnected is intermittently arranged in the bending perforation, a printing medium can be isolate | separated along a bending perforation.
In the print medium, the width direction dimension of the non-cut portion sandwiched between the adjacent second cut portions in the bent perforation is the width of the non-cut portion sandwiched between the adjacent first cut portions in the separation perforation. Since it is formed smaller than the directional dimension, the fold portion can be easily folded along the folding perforation, and the print medium can be easily folded. Furthermore, by forming the width direction dimension of the non-cut portion sandwiched between the adjacent second cut portions small, the portion that needs to be cut is reduced, so that the print medium can be easily separated along the folding perforations. Can do.

And the printing medium according to claim 2 is the printing medium according to claim 1, wherein the transport direction dimension of the second cutting part is formed larger than the transport direction dimension of the first cutting part. In the fold portion, it can be easily folded along the folding perforation, and the print medium can be easily folded. Furthermore, by forming the size in the conveyance direction of the second cutting part larger, the portion where the print medium has already been cut becomes larger in the conveyance direction, and the allowable range for the cutting direction is expanded. The print medium can be easily separated.

And the printing medium according to claim 3 is the printing medium according to claim 1 or 2 , wherein the folding perforation is provided with a folding habit according to the folding mode of mountain folds and valley folds. At the fold portion, it can be easily folded along the folding perforation, and the print medium can be easily folded.

Furthermore, the printing medium according to claim 4 is the printing medium according to any one of claims 1 to 3 , wherein the position of the unit piece within the folding interval is provided on the back surface of the printing surface of each unit piece. Since the sensor mark is shown, printing control based on the position of the unit piece within the bending interval can be performed. In particular, since it is possible to prevent the execution of printing across the folding perforations, it is possible to prevent deterioration in printing quality.

  DETAILED DESCRIPTION Hereinafter, a printing medium according to the present invention will be described in detail with reference to the drawings based on an embodiment in which the printing medium is embodied as a label printer sheet.

First, a schematic configuration of the label printer paper 100 according to the present embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a schematic view of a label printer paper 100 according to the present embodiment, and FIG. 2 is an enlarged view of a main part of the label printer paper 100 according to the present embodiment.
A label printer paper 100 according to the present embodiment includes a thermal label paper 101 and a release paper 102.
The thermal label paper 101 is a long thermal sheet having self-coloring properties, and an adhesive layer (not shown) coated with an adhesive is formed on one side of the thermal label paper 101. The back surface side of the adhesive layer functions as a printing surface on which desired printing is performed by a label printer 1 described later. That is, it is a surface on which thermal printing is performed based on the heat generation mode of the thermal head 31 disposed in the label printer 1.
The release paper 102 is formed with a width dimension equal to that of the thermal label paper 101. One surface of the release paper 102 is subjected to silicon treatment and functions as a release surface.
Therefore, the label printer paper 100 is configured by bonding the adhesive layer of the thermal label paper 101 and the release surface of the release paper 102, and the release surface is subjected to silicon treatment, so that the adhesive layer has an adhesive layer. The thermal label paper 101 can be peeled from the release paper 102 without reducing the force.
And the thermal label paper 101 peeled from the release paper 102 can be affixed on a desired position with the adhesive layer formed in one surface.

  As shown in FIG. 1, the label printer paper 100 according to the present embodiment is a continuous print medium in which mountain folds and valley folds are alternately repeated at a constant folding interval (120 mm in the present embodiment). is there. In the label printer paper 100, a fold of a mountain fold and a valley fold are alternately formed at every folding interval, and a fold perforation 107 is formed at the position of the fold. The bent perforations 107 are formed by alternately arranging cut portions 107A in which the thermal label paper 101 and the release paper 102 are cut and non-cut portions 107B in which the thermal label paper 101 and the release paper 102 are continuous. The heat-sensitive label paper 101 can be cut along the bent perforations 107. The bent perforations 107 will be described in detail later with reference to the drawings.

Further, separation perforations 110 that cross the width direction of the label printer paper 100 formed in a long shape are formed at a predetermined interval (30 mm in the present embodiment) within the bending interval.
Similar to the bent perforation 107, the separation perforation 110 also includes a cut portion 110A in which the thermal label paper 101 and the release paper 102 are cut, and a non-cut portion in which the thermal label paper 101 and the release paper 102 are continuous. 110B are alternately arranged, and the label printer paper 100 can be separated along the separation perforations 110. That is, in the label printer paper 100, by separating along the folding perforation 107 and the separation perforation 110, a constant printing area of “width direction of the label printer paper 100” × “predetermined interval (30 mm)” is obtained. The unit label piece 115 which has can be obtained. Further, in the label printer paper 100, a label piece having a printing area that is an integral multiple of the unit label piece 115 (up to four times in the present embodiment) is obtained by cutting off at any separation perforation 110 within the folding interval. You can also
In addition, the cutting portion 110A in the separation perforation 110 is formed to have a size that allows the printed result to be read sufficiently even when printing is performed on the separation perforation 110, and to reduce the opening area of the cutting portion 110A. Has been.

A sensor mark 105 is provided at a predetermined position on the back side of the release surface of the release paper 102 on the unit label piece 115 partitioned by the bent perforation 107 and the separation perforation 110.
This sensor mark 105 indicates the position of the unit label piece 115 within the folding interval, and is read by the photo sensor 11 described later, and used for printing control in the label printer 1.
More specifically, the sensor mark 105 is attached in correspondence with the order used in the folding interval (the order of transport to the label printer 1) when the label printer paper 100 is used in the label printer 1. The unit label piece 115 used first within the bending interval is provided with the first sensor mark 105A, and the second unit label piece 115 used second is provided with the second sensor mark 105B. Yes. Similarly, the third sensor mark 105C is attached to the unit label piece 115 used third in the folding interval, and the fourth sensor mark 105D is attached to the unit label piece 115 used fourth.
Therefore, when printing on the label printer paper 100, the sensor mark 105 is read by the photosensor 11, thereby obtaining which position within the folding interval the unit label piece 115 to start printing currently corresponds to. can do.
The sensor mark 105 includes three rectangular bit marks arranged in the transport direction, and the bit marks are shown in two colors, black and white. Of the three bit marks constituting the sensor mark 105, the bit mark located at the head is a print start mark indicating the print start position, and any sensor mark 105 is indicated by a black bit mark.
The two bit marks following the print start mark are position specifying marks indicating positions within the folding interval of the unit label piece 115 to which the sensor mark is attached. Specifically, it is possible to detect which position within the folding interval the unit label piece 115 corresponds to by combining the two bit marks black and white of the two bit marks in the position specifying mark.
Specifically, the position specifying mark of the first sensor mark 105A is indicated by “white” in both the front and rear bit marks. The position identification mark of the second sensor mark 105B is indicated by “white” for the front bit mark and “black” for the rear bit mark. Subsequently, the position identification mark of the third sensor mark 105C is indicated by “black” for the front bit mark and “white” for the rear bit mark. Further, the position specifying mark of the fourth sensor mark 105D is indicated by “black” in both the front and rear bit marks. Therefore, when the photo sensor 11 reads the mode of the two bit marks constituting the position specifying mark, the sensor mark attached to the unit label piece 115 is the first sensor mark 105A to the fourth sensor mark 105D. It is possible to determine which is. That is, it is possible to specify a position within the folding interval of the unit label piece 115.

Next, the configuration of the folding perforation 107 and the separation perforation 110 in the label printer paper 100 according to the present embodiment will be described in detail with reference to FIG.
Here, in FIG. 2, the periphery of the bent perforation 107 of the label printer paper 100 according to the present embodiment is shown in an enlarged manner.

  As described above, between the bent perforation 107 and the bent perforation 107, that is, within the folding interval, the unit perforation is divided into four unit label pieces 115 by the separation perforations 110, and the sensor mark 105 is attached to each. Has been. In this regard, as shown in FIG. 2, the two unit label pieces 115 partitioned with the bent perforation 107 as a boundary include a fourth sensor on the unit label piece 115 (lower side in FIG. 2) used earlier. The first sensor mark 105A is attached to the mark 105D and the unit label piece 115 (the upper side in FIG. 2) to be used next.

In the label printer paper 100 according to the present embodiment, the bent perforation 107 is not only different in position from the separation perforation 110 but also in its form. More specifically, the cutting portion 107A of the bent perforation 107 has the same width in the width direction of the label printer paper 100 as compared with the cutting portion 110A of the separation perforation 110, but has a wider width in the transport direction. Is formed.
That is, as shown in FIG. 2, the conveyance direction dimension (Wb) of the cutting part 107 </ b> A of the bent perforation 107 is formed larger than the conveyance direction dimension (Wa) of the cutting part 110 </ b> A of the separation perforation 110.
As a result, the strength of the bent perforation 107 is lower than the strength of the separation perforation 110 as well as the strength on the printing surface of the label printer paper 100, so that the folding perforation 107 is bent along the folding perforation 107. It becomes very easy. In this respect, since the folding perforation 107 becomes easy to be bent, it can be easily used as a continuous printing medium, and can be easily separated along the folding perforation 107.

Next, a schematic configuration of the label printer 1 that can use the label printer paper 100 according to the present embodiment will be described with reference to FIGS.
As shown in FIG. 3, the label printer 1 is constituted by a main body housing 2 in which a printing device such as a thermal head 31 described later is built. A paper cassette 120 in which the label printer paper 100 is stored is detachably disposed at the upper rear edge of the main body housing 2 (see FIG. 4).

A power button 7 and a cut lever 9 are disposed on the front surface of the main body housing 2. The cut lever 9 is disposed in the lower front portion of the main body housing 2 so as to be movable in the left-right direction. The cut lever 9 is interlocked with the cutter unit 8 disposed inside the main body housing 2, and the cutter unit 8 inside the main body housing 2 is also moved by moving the cut lever 9 in the left-right direction. The label printer paper 100 can be cut by moving in conjunction with each other.
A transparent resin tray 6 is erected above the power button 7 so as to face the front center of the upper cover (not shown).
On the other hand, a power cord 10 (see FIG. 4) is connected to one side end of the lower part on the back side of the main body housing 2, and a personal computer (not shown) is connected to the other side end. A connector portion (not shown) that is configured by a USB (Universal Serial Bus) or the like and that configures a communication interface 68 described later is provided.

As shown in FIG. 3, the main body housing 2 is formed with a holder storage portion 4 to which the holder 3 is attached, and the holder 3 in the holder storage portion 4 is provided on one side of the holder storage portion 4. A holder support member 15 for supporting and fixing the position is provided.
The holder supporting member 15 is formed with a first positioning groove portion 16 having a substantially vertically U-shape in front view that opens upward, and a mounting member 13 of the holder 3 to be described later can be fitted therein. An engagement recess 15A is formed at the inner base end of the holder support member 15, and an elastic locking piece 12A (see FIG. 6) protruding from the lower end of the positioning member 12 is engaged therewith.
Thereby, the holder 3 accommodated in the holder accommodating part 4 can be fixed to a predetermined position. As a result, the positional fluctuation of the label printer paper 100 can be prevented, and high-quality printing is possible.

On the other hand, on the bottom surface of the holder storage portion 4, a positioning recess 4 </ b> A that is horizontally long in plan view is formed with a predetermined depth (in this embodiment, a depth of about 1.5 to 3 mm). On the other hand, on the bottom surface of the holder housing portion 4 on the positioning member 12 side (right side in FIG. 3), a discrimination recess 4B having a rectangular shape in plan view is formed.
Here, the discrimination recess 4B is formed deeper than the positioning recess 4A by a predetermined depth (in this embodiment, a depth of about 1.5 to 3 mm). Sheet discriminating sensors S1, S2, S3, S4, and S5 configured by a plurality of push-type micro switches are provided in an L shape. That is, by storing the holder 3 in the holder storage unit 4, the sheet determination unit 60 (see FIG. 6) formed at the lower end of the positioning member 12 is fitted into the determination recess 4 </ b> B, and the five formed in the sheet determination unit 60. Based on the position of the sensor hole 60A (see FIG. 6), the information related to the label printer paper 100 (the type of the label printer paper 100, the material of the thermal label paper 101, the width of the thermal label paper 101, etc.) can be determined. .

An insertion port 18 into which the label printer paper 100 pulled out from the paper cassette 120 is inserted is formed in front of the holder storage unit 4. And from the rear-end edge part of the insertion port 18 to the front side upper-end edge part of the holder accommodating part 4, it extends substantially horizontal, and the mounting part 21 is comprised. In the mounting portion 21, four second positioning groove portions 22 </ b> A to 22 </ b> D having a substantially L-shaped cross section corresponding to a plurality of width dimensions of the label printer paper 100 are formed at the edge corners on the rear side in the transport direction. Has been.
Here, a guide member 20 constituting the holder 3 described later is a second positioning groove portion (any one of the second positioning groove portions 22A to 22D) corresponding to the width of the label printer paper 100 attached to the holder 3. It is fitted, and its tip extends to the insertion port 18. As a result, the label printer paper 100 attached to the holder 3 is guided to the insertion port 18 while being in contact with the guide member 20.

The main body housing 2 is provided with a lever 27 for performing a vertical movement operation of the thermal head 31 (see FIG. 4) on the front portion of the side surface (left side in FIG. 2) facing the holder support member 15. When the lever 27 is rotated upward, the thermal head 31 moves downward and moves away from the platen roller 26 (see FIG. 5). On the other hand, when the lever 27 is rotated downward, the thermal head 31 moves upward and presses the label printer paper 100 against the platen roller 26 so that printing is possible.
Here, a control circuit unit 61 (see FIG. 7) for driving and controlling each mechanism unit according to a command from an external personal computer or the like is formed inside the main body housing 2 below the holder housing unit 4. A control board 32 (see FIG. 4) is provided.

Here, a schematic configuration of the holder 3 attached to the holder storage portion 4 will be described in detail with reference to the drawings. FIG. 6 is an external perspective view of the holder 3.
As shown in FIG. 6, the holder 3 abuts on the positioning member 12 attached to the holder support member 15 formed in the holder storage portion 4 and one end of the label printer paper 100 and guides it to the insertion port 18. The holder member 40 is sandwiched between the guide member 20, the positioning member 12, and the guide member 20, and includes a holder shaft member 40 on which the label printer paper 100 moves.
Specifically, a flange portion 36 is formed on the outer peripheral portion at one end of the holder shaft member 40, and the flange portion 36 is fixed to the outer end surface of the guide member 20. On the other hand, the other end side of the holder shaft member 40 is fitted into the second tube portion of the positioning member 12 and is fixed to the second tube portion.
As described above, the positioning member 12 and the guide member 20 are fixed to the holder shaft member 40, whereby the integrated holder 3 is formed. In this regard, when the paper width of the label printer paper 100 is different, the holder 3 corresponding to the paper width of the label printer paper 100 can be easily manufactured by changing the length dimension of the holder shaft member 40.

Next, the guide member 20 will be described in detail with reference to FIG.
As shown in FIG. 6, the guide member 20 extends from the lower outer peripheral portion of the outer end surface of the first tube portion in the lower direction, and a first extension portion 42 is formed. The first extending portion 42 is fitted into the positioning recess 4 </ b> A of the holder storage portion 4.
And the 2nd extension part 43 extended to the upper part of the guide member 20 is formed in the guide member 20, Furthermore, from the outer peripheral part of the 2nd extension part 43 to the insertion port 18 (refer FIG. 4) vicinity A third extending portion 44 is formed in which the upper end edge portion extends in a front-down manner.
Here, the lower end surface of the distal end portion of the third extending portion 44 is formed substantially horizontally and abuts on the placement portion 21 of the label printer 1. As a result, one side edge portion of the label printer paper 100 mounted on the holder 3 is guided to the insertion port 18 by the inner surface of the third extension portion 44 and the second extension portion 43.
Further, a fourth extending portion 45 extending from the position facing the rear end edge in the transport direction of the mounting portion 21 to the first extending portion 42 is formed on the lower end surface of the third extending portion 44. The When the lower end surface of the third extending portion 44 is brought into contact with the mounting portion 21, the leading end portion in the transport direction of the fourth extending portion 45 is a label printer sheet attached to the holder storage portion 4. It is inserted into a second positioning groove (any one of the second positioning grooves 22A to 22D) corresponding to 100 paper widths (see FIG. 4).

  Subsequently, the positioning member 12 constituting the holder 3 will be described in detail with reference to FIG. As shown in FIG. 6 (B), the outer surface of the positioning member 12 is substantially orthogonal to the axial center from the edge of the axial center of the holder shaft member 40 and is vertically rectangular in the vertical direction. A mounting member 13 is projected. The attachment member 13 is formed so as to be narrow in the downward direction when viewed from the front, and is formed so as to be able to closely contact the first positioning groove portion 16 that is narrow in the downward direction of the holder support member 15 of the label printer 1. Further, the protruding height dimension of the mounting member 13 is formed substantially equal to the width dimension of the first positioning groove 16.

Further, the lower end portion of the attachment member 13 is projected from the lower end portion of the attachment member 13 in the left-right direction by a predetermined length (in the present embodiment, about 1.5 mm to 3 mm) in front view. A substantially rectangular flat plate-like guide portion 57 (in this embodiment, the thickness is about 1.5 mm to 3 mm) is formed. Thus, when the holder 3 is mounted, the mounting member 13 is inserted into the first positioning groove 16 while the guide portion 57 formed at the lower end of the mounting member 13 is brought into contact with the outer end surface of the holder support member 15. Thus, the holder 3 can be mounted while being positioned easily.
A substantially rectangular sheet discriminating portion 60 is formed at the lower end of the extending portion 56 of the positioning member 12 so as to extend a predetermined length in a substantially right-angle inner direction. As described above, in the sheet determination unit 60, five sensor holes 60A are formed in a substantially L shape at predetermined positions facing the sheet determination sensors S1 to S5.
Accordingly, when the holder 3 is installed in the holder storage portion 4 and the sheet determination portion 60 is inserted into the determination recess 4B, each sensor hole 60A is positioned at a position corresponding to the sheet determination sensors S1 to S5. And since sheet | seat discrimination | determination sensors S1-S5 are push-type microswitches, a different signal can be output based on whether the corresponding sensor hole 60A is opened. The CPU 62 can acquire information on the label printer paper 100 attached to the label printer 1 by the output mode from the sheet discrimination sensors S1 to S5.
In addition, a vertically long rectangular through hole 52 is formed in the extending portion 56 at the lower end portion of the attachment member 13 of the positioning member 12, and the upper end edge of the through hole 52 is directed downwardly toward the distal end. An elastic locking piece 12 </ b> A in which a protruding portion is formed is provided.

In the label printer 1 according to the present embodiment, not only the label printer paper 100 which is a continuous print medium but also a roll paper print medium wound around a cylindrical member can be used. In this case, the holder shaft member 40 is fitted into a cylindrical member around which a roll paper-like print medium is wound, and the cylindrical member can be rotated, whereby the holder 3 to which the roll paper is mounted is obtained. Then, the label printer 1 can perform printing on the roll paper by attaching the holder 3 loaded with the roll paper to the holder housing 4.
At this time, the position of the sensor hole 60 </ b> A formed in the holder 3 is formed differently from the holder 3 used in the case of the label printer paper 100. Therefore, the label printer 1 can discriminate between the label printer paper 100, which is a continuous print medium, and the roll paper-like print medium, and can perform print control.

Next, an operation when printing on the label printer paper 100 using the label printer 1 and the holder 3 described above will be described in detail with reference to the drawings.
First, in order to perform printing on the label printer paper 100 in the label printer 1, an operation for attaching the holder 3 to the holder storage portion 4 is required. Therefore, the user engages the elastic locking piece 12A with the engagement recess 15A while fitting the attachment member 13 into the first positioning groove 16 on the positioning member 12 side. At this time, on the guide member 20 side, the lower end portion of the guide member 20 is brought into contact with the positioning recess 4A while the lower surface of the distal end portion of the guide member 20 is fitted into any of the second positioning groove portions 22A to 22D. By performing this operation, the holder 3 is detachably attached to the holder storage portion 4.
In addition, by attaching the holder 3 to the holder accommodating part 4, the sheet | seat discrimination | determination part 60 provided in the lower end of the positioning member 12 is inserted in the discrimination | determination recessed part 4B, and five sensor hole 60A and each sheet | seat discrimination | determination sensor S1-S5 are inserted. By collaborating, it is possible to acquire information related to the label printer paper 100 attached to the label printer 1.

Thus, after attaching the holder 3 to the holder accommodating portion 4, it is necessary to pull out the label printer paper 100 from the paper cassette 120 attached to the rear portion of the main body housing 2 so as to enable printing.
In this case, first, the lever 27 is rotated upward to separate the thermal head 31 and the platen roller 26 from each other. Thereafter, the label printer paper 100 is pulled out from the paper cassette 120, and the end of the label printer paper 100 is inserted into the insertion slot 18.
The insertion port 18 is composed of an upper surface of a placement portion 21 on which the distal end portion of the guide member 20 is placed, and a lower surface of a paper guide portion 28 disposed in front of the placement portion 21. Further, the front end edge of the mounting portion 21 extends downward from the front end edge by a predetermined length, and further extends a predetermined length toward the platen roller. A protruding portion 24 is formed.

As shown in FIG. 5, a sheet guide path 25 that guides the label printer paper 100 to the lower end surface of the platen roller 26 is formed between the extending portion 24 and the paper guide portion 28. Therefore, when the label printer paper 100 pulled out from the holder 3 is inserted into the insertion slot 18, it moves along the sheet guide path 25 and is guided to the lower side of the platen roller 26.
When passing through the insertion port 18 and the sheet guide path 25, the label printer paper 100 moves with the back side of the release paper 102, that is, the surface to which the sensor mark 105 is attached, as the upper surface.

In the main body housing 2, the photosensor 11 is disposed in the vicinity of the end edge portion on the holder support member 15 side while facing the upper surface of the extending portion 24. The photo sensor 11 is a reflection type optical sensor as a mark detection sensor, and detects a sensor mark 105 attached to the back side of the label printer paper 100 sliding on the sheet guide path 25.
Note that the photosensor 11 may be provided at a position facing the back side of the minimum width dimension of the label printer paper 100. As a result, the label printer paper 100 used in the label printer 1 can correspond to the label printer paper 100 of all width dimensions.

By inserting one end of the label printer paper 100 into the insertion slot 18 and passing through the sheet guide path 25, the label printer paper 100 as a printing medium is positioned between the thermal head 31 and the platen roller 26. (See FIG. 5).
Thereafter, by rotating the lever 27 downward, the label printer paper 100 inserted from the insertion port 18 is urged to be pressed toward the platen roller 26 by the line-type thermal head 31. Accordingly, the platen roller 26 is rotated by a sheet feed motor 72 (see FIG. 7) constituted by a stepping motor or the like, and the thermal head 31 is driven and controlled, so that printing is performed while the label printer paper 100 is conveyed. Image data can be printed sequentially on the surface. Further, the label printer paper 100 discharged onto the tray 6 is cut by the cutter unit 8 by moving the cut lever 9 in the right direction.

Next, the control system circuit of the label printer 1 configured as described above will be described with reference to FIG.
As shown in FIG. 7, the control circuit unit 61 formed on the control board 32 of the label printer 1 includes a CPU 62, a CGROM 63, a ROM 64, a flash memory 65 (EEPROM), a RAM 66, an input / output interface 67, and a communication interface 68. Etc. Further, the CPU 62, the CGROM 63, the ROM 64, the flash memory 65, the RAM 66, the input / output interface 67, and the communication interface 68 are connected to each other via a bus line 69, and exchange data with each other.

Here, the CGROM 63 stores dot pattern data corresponding to each character. Therefore, when printing is performed on the label printer paper 100, the dot pattern data is read from the CGROM 63, and the dot pattern is printed on the thermal label paper 101 based on the dot pattern data.
The ROM 64 stores various programs. The ROM 64 stores various programs necessary for controlling the label printer 1 such as a print control program described later in the label printer 1.
The ROM 64 is provided with a paper type storage area 64A. Information about the output mode from each of the sheet discrimination sensors S1 to S5 and the label printer paper 100 (the type of the label printer paper 100, the material of the thermal label paper 101). , Label printer paper 100 width, etc.) are stored in association with each other. Accordingly, the CPU 62 determines information on the label printer paper 100 attached to the label printer 1 (the type of the label printer paper 100, the material of the thermal label paper 101, the label printer) based on the output signals from the sheet discrimination sensors S1 to S5. The width of the paper 100 and the like can be specified, and print control corresponding to the label printer paper 100 can be executed.

The CPU 62 performs various calculations based on various programs stored in the ROM 64. Accordingly, the print control program stored in the ROM 64 is calculated by the CPU 62. In addition, the ROM 64 classifies outline data (outline data) that defines the outline of each character for each type of character (such as Gothic typeface, Mincho typeface) for each character such as a large number of characters. Stored in correspondence with the code data. Based on the outline data, dot pattern data is developed on the print buffer 66A.
The flash memory 65 stores dot pattern data such as external character data received from an external personal computer or the like, dot pattern data of various symbol data, etc. with a registration number, and stores the power of the label printer 1. Even if it is turned off, the stored contents are retained.
The RAM 66 is for temporarily storing various calculation results calculated by the CPU 62, and is provided with various memories such as a print buffer 66A and a work area 66B. Here, in the print buffer 66A, dot patterns for printing such as a plurality of characters and symbols, the number of applied pulses that are the amount of energy for forming each dot, and the like are stored as dot pattern data, and the thermal head 31 is stored in the print buffer 66A. Dot printing is performed according to the stored dot pattern data.

The input / output interface 67 includes a drive circuit 71 for driving the sheet determination sensors S1 to S5, the photosensor 11, a drive circuit 71 for driving the thermal head 31, and a sheet feed motor 72 for rotating the platen roller 26. 73 are connected to each other.
The communication interface 68 is composed of, for example, a USB (Universal Serial Bus) or the like, and is connected to an external personal computer via a USB cable or the like to enable bidirectional data communication.

Next, a print control program stored in the ROM 64 and calculated when printing on the label printer paper 100 will be described in detail with reference to the drawings. FIG. 8 is a flowchart of a print control program in the label printer 1 according to this embodiment.
When a print command is received from a personal computer (not shown) via the communication interface 68, the CPU 62 starts executing the print control program.

When execution of the print control program is started, first, the CPU 62 determines whether or not the label printer paper 100 is present. That is, the CPU 62 determines whether or not the label printer paper 100 is mounted on the label printer 1 in a printable state.
Here, when the label printer paper 100 is loaded in a printable state, the label printer paper 100 is positioned between the thermal head 31 and the platen roller 26 via the sheet guide path 25 as described above. Will do. Therefore, the CPU 62 determines the presence or absence of the label printer paper 100 by detecting the presence of the label printer paper 100 in the sheet guide path 25 by the photo sensor 11. If the label printer paper 100 is present (S1: YES), the process proceeds to S2. On the other hand, if there is no label printer paper 100 (S1: NO), a paper feed error display (S3) is performed.
In the paper feed error display (S3), the CPU 62 transmits a paper feed error signal to the personal computer connected via the communication interface 68. After transmitting the paper feed error signal, the CPU 62 returns to S1 again and determines whether or not the label printer paper 100 is present.
At this time, a message “Please set label printer paper 100” is displayed on the liquid crystal display of the personal computer that has received the paper feed error signal.

  On the other hand, in the case where the label printer paper 100 is loaded in the label printer 1 (S1: YES), the label printer paper 100 is transported in S2 which is shifted to. Specifically, in the label printer paper 100 attached to the label printer 1, the unit label piece 115 positioned at the head is detected by the photo sensor 11, and the platen roller 26 is driven to reach the head of the unit label piece 115. The label printer paper 100 is conveyed. After the label printer paper 100 is conveyed to the head of the unit label piece 115 located at the head, the process proceeds to S4.

Subsequently, in S <b> 4, the CPU 62 reads the sensor mark 105 attached to each unit label piece 115 by the photo sensor 11. That is, the CPU 62 first transports the label printer paper 100 by the platen roller 26 and detects the print start mark of the sensor mark 105. Thereafter, the label printer paper 100 is further conveyed by a predetermined amount (a width corresponding to the bit mark conveyance direction), and the bit mark is read by the photo sensor 11.
That is, in S4, after reading the print start mark, the label printer paper 100 is transported by a predetermined amount, and one of the bit marks constituting the position specifying mark (that is, the bit mark on the downstream side in the transport direction) is read. Thereafter, the label printer paper 100 is further conveyed by a predetermined amount, and the last bit mark is read to read the entire position specifying mark.
After reading the print start mark and the position specifying mark constituting the sensor mark 105 in this way, the platen roller 26 is driven again, and the label printer paper 100 is conveyed to the print start position where the leading end portion of the print start mark is read. . Thereby, the position moved by reading the sensor mark 105 is returned to the predetermined print start position.
In S <b> 4, the reading result of the sensor mark 105 read by the photosensor 11 is stored in the RAM 66. After the reading result of the sensor mark 105 is stored in the RAM 66, the process proceeds to S5.

Next, in S5, the CPU 62 determines whether or not the sensor mark read in S4 is the first sensor mark 105A. That is, the CPU 62 reads the reading result of the sensor mark 105 from the RAM 66 and determines whether or not both of the bit marks constituting the position specifying mark are “white”.
When the reading result of the sensor mark 105 corresponds to the first sensor mark 105A (S5: YES), the process proceeds to S6. On the other hand, when the reading result of the sensor mark 105 is not the first sensor mark 105A (S5: NO), the process proceeds to S8.

In S6, the CPU 62 determines whether or not the print data received from the external personal computer can be printed with four unit label pieces including the unit label piece 115 with the sensor mark 105 read in S4. Make a decision.
Here, when printing on a plurality of unit label pieces 115 across the folding perforation 107 of the label printer paper 100, the cutting portion 107A of the folding perforation 107 is more than the cutting portion 110A of the separation perforation 110. Since the print surface is deformed by bending at the folding perforation 107, printing on the folding perforation 107 becomes unclear.
At the time of S6, since the unit label piece 115 with the first sensor mark 105A is printed first, the unit label piece that can be printed without straddling the bent perforation 107. 115 is a maximum of four.
Accordingly, in S6, the CPU 62 determines whether or not printing data can be printed without straddling the folding perforation 107.

When the print data can be printed without straddling the folding perforation 107, that is, when the print data is smaller than the print data printable by the four unit label pieces 115 (S6: YES). Based on the data amount of the print data, printing on the label printer paper 100 is performed (S7). Here, in the printing process (S7), print data is printed on the minimum necessary unit label piece 115. For example, when the amount of print data is equivalent to two unit label pieces 115, printing using two unit label pieces 115 is performed. This also applies to the case where the data amount of the print data is one unit label piece 115 or three.
Since this printing process (S7) is the same as the printing process conventionally performed, detailed description thereof will be omitted. When the printing process (S7) ends, the CPU 62 ends the execution of the printing control program.

On the other hand, when four or more unit label pieces 115 are required to print the print data, that is, when the print data is printed, the print will surely straddle the perforation 107 (S6: NO). The CPU 62 transmits an editing error signal to the personal computer via the communication interface 68 (S8). At this time, in the personal computer that has received the editing error signal, an editing error is displayed on the liquid crystal display, and “not printable, prompting editing of print data” is displayed.
Then, after transmitting the edit error signal, the CPU 62 ends the execution of the print control program.

In S9 when the sensor mark 105 read in S4 is not the first sensor mark 105A (S5: NO), the CPU 62 determines that the reading result of the sensor mark stored in the RAM 66 is the second sensor mark. A determination is made as to whether or not 105B is indicated. That is, the CPU 62 reads the reading result of the sensor mark 105 from the RAM 66, and among the bit marks constituting the position specifying mark, the front bit mark is “white” and the rear bit mark is “black”. Make a judgment about
When the reading result of the sensor mark 105 corresponds to the second sensor mark 105B (S9: YES), the process proceeds to S10. On the other hand, when the reading result of the sensor mark 105 is not the second sensor mark 105B (S9: NO), the process proceeds to S13.

In S10, the CPU 62 determines whether the print data received from the external personal computer can be printed with three unit label pieces including the unit label piece 115 to which the sensor mark 105 read in S4 is attached. I do.
Here, since the sensor mark 105 attached to the unit label piece 115 printed first is the second sensor mark 105B, the three pieces including the unit label piece 115 are included up to the bent perforation 107. There is a unit label piece 115.
Accordingly, when the print data can be printed without straddling the bent perforation 107, that is, when the print data is smaller than the print data printable by the three unit label pieces 115 (S10: YES), printing is performed on the label printer paper 100 based on the amount of print data (S12). On the other hand, when three or more unit label pieces 115 are required for printing the print data (S10: NO), the process proceeds to S11.

  Here, in the printing process (S12), printing based on the print data is performed using the minimum necessary unit label pieces 115. The printing process (S12) is the same as the printing process that has been performed conventionally, and is the same as the above-described printing process (S7), and thus detailed description thereof is omitted. When the printing process (S12) ends, the CPU 62 ends the execution of the printing control program.

  On the other hand, when three or more unit label pieces 115 are required for printing the print data, that is, when the print data is printed, the print is surely straddling the folding perforation 107 (S10: NO), S11. The CPU 62 drives the platen roller 26 and conveys the label printer paper 100 to the head position of the next unit label piece 115. After the conveyance of the label printer paper 100 is completed, the process returns to S4, and the sensor mark 105 attached to the next unit label piece 115 is read.

In S13, where the sensor mark 105 read in S4 is not the second sensor mark 105B (S9: NO), the CPU 62 determines that the sensor mark read result stored in the RAM 66 is the third sensor mark. A determination is made as to whether or not 105C is indicated. That is, the CPU 62 reads the reading result of the sensor mark 105 from the RAM 66, and among the bit marks constituting the position specifying mark, the front bit mark is “black” and the rear bit mark is “white”. Make a judgment about
When the reading result of the sensor mark 105 corresponds to the third sensor mark 105C (S13: YES), the process proceeds to S14. On the other hand, when the reading result of the sensor mark 105 is not the third sensor mark 105C (S13: NO), the process proceeds to S16.

In S14, the CPU 62 determines whether or not the print data received from the external personal computer can be printed with the two unit label pieces 115 including the unit label piece 115 attached with the sensor mark 105 read in S4. Make a decision.
Here, since the sensor mark 105 attached to the unit label piece 115 printed first is the third sensor mark 105C, the two pieces including the unit label piece 115 are included by the perforation 107. There is a unit label piece 115.
Therefore, when the print data can be printed without straddling the bent perforation 107, that is, when the print data is smaller than the print data printable by the two unit label pieces 115 (S14: YES), printing on the label printer paper 100 is performed based on the data amount of the print data (S15). On the other hand, when two or more unit label pieces 115 are required for printing the print data (S14: NO), the process proceeds to S11.

  Here, in the printing process (S15), printing based on the print data is performed using the minimum necessary unit label pieces 115. Note that the printing process (S15) is the same as the printing process that has been conventionally performed, and is the same as the above-described printing process (S7, S12), and thus detailed description thereof is omitted. When the printing process (S15) ends, the CPU 62 ends the execution of the printing control program.

  On the other hand, when two or more unit label pieces 115 are required to print the print data, that is, when the print data is printed, the print will surely straddle the folding perforation 107 (S14: NO), S11. The CPU 62 drives the platen roller 26 and conveys the label printer paper 100 to the head position of the next unit label piece 115. After the conveyance of the label printer paper 100 is completed, the process returns to S4, and the sensor mark 105 attached to the next unit label piece 115 is read.

Next, in S16, where the sensor mark 105 read in S4 is not the third sensor mark 105C (S13: NO), the CPU 62 determines that the sensor mark read result stored in the RAM 66 is the fourth sensor mark. It is determined whether or not the mark 105D is indicated. That is, the CPU 62 reads the reading result of the sensor mark 105 from the RAM 66 and determines whether or not any of the bit marks constituting the position specifying mark is “black”.
When the reading result of the sensor mark 105 corresponds to the fourth sensor mark 105D (S16: YES), the process proceeds to S17. On the other hand, when the reading result of the sensor mark 105 is not the fourth sensor mark 105D (S16: NO), the process proceeds to S19.

Here, a case will be described in which it is determined in S16 that the sensor mark 105 read in S4 is not the fourth sensor mark 105D, that is, the process proceeds to S19. As shown in FIG. 7, when the process proceeds to S19, the determination process of S5, S9, and S13 has already been performed. Therefore, the sensor marks read in S4 are the first sensor mark 105A and the second sensor mark 105B. None of the third sensor marks 105C. In S16, it is determined that the sensor mark is not the fourth sensor mark 105D. That is, since none of the sensor marks 105 is attached to the label printer paper 100 according to the present embodiment, the case of shifting to S19 is a case of a reading error of the sensor mark 105 by the photosensor 11.
Accordingly, in S19, the CPU 62 transmits a mark reading error signal to the personal computer via the communication interface 68.
Here, in the personal computer that has received the mark reading error signal, a message indicating that a sensor mark reading error has occurred is displayed on the liquid crystal display.
Then, after transmitting the mark reading error signal, the CPU 62 ends the print control program without printing the print data.

In S17, the CPU 62 determines whether the print data received from the external personal computer can be printed by the unit label piece 115 to which the sensor mark 105 read in S4 is attached.
Here, since the sensor mark 105 attached to the unit label piece 115 printed first is the fourth sensor mark 105D, only the unit label piece 115 is reached up to the bent perforation 107. Therefore, when the print data can be printed without straddling the bent perforation 107, that is, when the print data is smaller than the print data printable by one unit label piece 115 (S17: YES), printing is performed on the label printer paper 100 based on the amount of print data (S18). On the other hand, when one or more unit label pieces 115 are required for printing the print data (S17: NO), the process proceeds to S11.

  Here, in the printing process (S18), printing based on the print data is performed using the unit label piece 115 to which the fourth sensor mark 105D is attached. The printing process (S18) is the same as the printing process conventionally performed, and is the same as the above-described printing process (S7, S12, S15), and thus detailed description thereof is omitted. When the printing process (S18) ends, the CPU 62 ends the execution of the printing control program.

  On the other hand, when one or more unit label pieces 115 are required to print the print data, that is, when the print data is printed, the print will surely straddle the folding perforation 107 (S17: NO), S11. The CPU 62 drives the platen roller 26 and conveys the label printer paper 100 to the head position of the next unit label piece 115. After the conveyance of the label printer paper 100 is completed, the process returns to S4, and the sensor mark 105 attached to the next unit label piece 115 is read.

  As described above, in the label printer paper 100 according to the present embodiment, after printing by the label printer 1, separation is performed along the separation perforation 110 or the bent perforation 107, so that desired printing can be performed. The unit label piece 115 made can be acquired. Moreover, since it can isolate | separate by arbitrary separation perforations 110, the label which has the printing area of the integral multiple (2-4 times) of the printing area of the unit label piece 115 can also be obtained.

  Further, in the label printer paper 100 which is a continuous printing medium, the cutting portion 107A of the folding perforation 107 formed at a predetermined folding interval has a dimension in the conveyance direction of the cutting portion 110A of the separation perforation 110. It is formed larger than the dimension in the conveyance direction, and the cut portions 107A are arranged in a line. Therefore, the label printer paper 100 can be easily bent along the bent perforations 107.

Further, the sensor paper 105 indicating the position of the unit label piece 115 within the folding interval is attached to the release paper 102 of the label printer paper 100 for each unit label piece 115. Then, by performing printing control with the label printer 1 based on the sensor mark 105, printing across the fold including the folding perforation 107 is not performed. In other words, the print surface is not illegible due to the deformation of the print surface accompanied by bending and the presence of the cut portion 107A of the bent perforation 107, and the label piece is always provided with good print quality. Can do.
In this regard, even when printing is performed on the separation perforation 110, as described above, the cutting direction 110A is formed with a small size in the conveyance direction, so that the printing quality is not greatly reduced, and separation is performed. The printed result on the perforation 110 is sufficiently legible.

Subsequently, an embodiment different from the first embodiment will be described as a second embodiment, which will be described in detail with reference to FIG. Here, in 2nd Example, about the structure of the label printer 1 and the holder 3, it is the same structure as 1st Example mentioned above. The printing control program executed in the label printer 1 is also the same. Therefore, the same components as those in the first embodiment will be described using the same reference numerals.
In the second embodiment, the configuration of the label printer paper used in the label printer 1 is different. Therefore, the configuration of the label printer paper will be described in detail with reference to the drawings.

The label printer paper 100 in the second embodiment is a continuous print medium as in the first embodiment, and the release paper 102 is formed on the adhesive layer formed on one surface of the long thermal label paper 101. Affixed and configured.
Also in the second embodiment, the label printer paper 100 is repeatedly fold-folded and valley-folded at a constant folding interval (120 mm in the present embodiment), and a folding perforation 107 is provided at the position of the fold. Is formed. Similar to the label printer paper 100 according to the first embodiment, the bent perforations 107 are configured by alternately arranging cutting portions 107A and non-cutting portions 107B.
Similarly to the first embodiment, the separation perforations 110 that traverse in the width direction of the label printer paper 100 formed in a long shape have a predetermined interval (30 mm in the present embodiment) within the bending interval. Is formed. Similarly to the first embodiment, the separation perforations 110 are configured by alternately arranging cutting portions 110A and non-cutting portions 110B.
Also in the label printer paper 100 according to the second embodiment, the separation perforation 110 divides the folding interval into four print areas. That is, by separating along the perforation 107 and the separation perforation 110, the label printer paper 100 within the bending interval can be made into four unit label pieces 115.

  Each unit label piece 115 is provided with a sensor mark 105 at a predetermined position on the back side of the release surface of the release paper 102. Similar to the first embodiment, the sensor mark 105 is a mark indicating the position of the unit label piece 115 within the folding interval, and the first sensor mark 105A according to the position of the unit label piece 115 within the folding interval. Any one of the second sensor mark 105B, the third sensor mark 105C, and the fourth sensor mark 105D is attached.

  As described above, the label printer paper 100 according to the second embodiment has the same basic configuration as the label printer paper 100 according to the first embodiment, but there is a difference with respect to the bent perforation 107. . This point will be described in detail with reference to FIG. FIG. 9 is an enlarged view around the bent perforation 107 in the label printer paper 100 according to the second embodiment.

As described above, in the first embodiment, the cutting portion 107A of the bent perforation 107 is formed larger in the transport direction of the label printer paper 100 than the cutting portion 110A of the separation perforation 110.
In this regard, as shown in FIG. 9, in the label printer paper 100 according to the second embodiment, the cutting part 107A of the bent perforation 107 is formed in the same size as the cutting part 110A of the separation perforation 110. However, the width direction dimension (Rb) of the non-cut portion 107B is smaller than the width direction dimension (Ra) of the non-cut portion 110B of the separation perforation 110 (see FIG. 9).
Therefore, the ratio of the non-cut portion 107B to the bent perforations 107 is reduced, and most of the bent perforations 107 are cut by the cut portions 107A. Thereby, the bending work on the bending perforation 107 can be easily performed. Furthermore, since the width of each non-cut portion 107B is narrow, the unit label piece 115 can be easily and beautifully separated along the bent perforation 107.
In the second embodiment, the cutting portion 107A of the bent perforation 107 and the cutting portion 110A of the separation perforation 110 are formed with the same size, but the size of the cutting portion 107A is separated from the separation perforation 110. You may form larger than the cutting part 110A. For example, as in the first embodiment, it is needless to say that the conveyance direction dimension of the cutting part 107A of the bent perforation 107 may be larger than that of the cutting part 110A of the separation perforation 110.

Subsequently, an embodiment different from the first and second embodiments will be described as a third embodiment, which will be described in detail with reference to FIG. Here, also in the third embodiment, the configurations of the label printer 1 and the holder 3 are the same as those in the first and second embodiments described above. The printing control program executed in the label printer 1 is also the same. Therefore, the same components as those in the first and second embodiments will be described using the same reference numerals.
In the third embodiment, the configuration of the label printer paper used in the label printer 1 is different from the first embodiment and the second embodiment. Therefore, the configuration of the label printer paper will be described in detail with reference to the drawings.

The label printer paper 100 in the third embodiment is a continuous print medium as in the first and second embodiments, and is formed on an adhesive layer formed on one surface of the long thermal label paper 101. The release paper 102 is pasted.
Also in the third embodiment, the label printer paper 100 is repeatedly folded into a fold and a valley with a constant folding interval (120 mm in this embodiment), and a bent perforation 107 is formed at the position of the fold. Is formed. The bent perforation 107 is configured by alternately arranging cutting portions 107A and non-cutting portions 107B.
Similarly to the first and second embodiments, the separation perforation 110 that crosses the width of the label printer paper 100 formed in a long shape has a predetermined interval (this embodiment) within the bending interval. 30 mm). Similarly, the separation perforation 110 is configured by alternately arranging cutting portions 110A and non-cutting portions 110B.
In the label printer sheet 100 according to the third embodiment, the separation perforation 110 also divides the folding interval into four print areas. That is, by separating along the perforation 107 and the separation perforation 110, the label printer paper 100 within the bending interval can be made into four unit label pieces 115.

  Each unit label piece 115 is provided with a sensor mark 105 at a predetermined position on the back side of the release surface of the release paper 102. Similar to the first embodiment, the sensor mark 105 is a mark indicating the position of the unit label piece 115 within the folding interval, and the first sensor mark 105A according to the position of the unit label piece 115 within the folding interval. Any one of the second sensor mark 105B, the third sensor mark 105C, and the fourth sensor mark 105D is attached.

  As described above, the label printer paper 100 according to the third embodiment has the same basic configuration as the label printer paper 100 according to the first embodiment and the second embodiment. There are differences. This point will be described in detail with reference to FIG. FIG. 8 is an enlarged view around the bent perforation 107 in the label printer paper 100 according to the third embodiment.

As shown in FIG. 9, in the label printer paper 100 according to the third embodiment, the cutting portion 107A of the bent perforation 107 is more labeled than the cutting portion 110A of the separation perforation 110, as in the first embodiment. It is formed as an opening cutting part enlarged in the conveyance direction of the printer paper 100.
Here, the bent perforation 107 and the separation perforation 110 are formed by punching the label printer paper 100. In this regard, in the first embodiment and the second embodiment, only the bent perforation 107 and the separation perforation 110 are formed on the label printer paper 100, but in the third embodiment, the label printer paper 100 is formed. When the bent perforation 107 is formed, the bent recess 113 is also formed. The separation perforations 110 in the third embodiment are formed by punching only the separation perforations 110 as in the first and second embodiments.

The formation of the folding perforation 107 and the folding recess 113 on the label printer paper 100 according to the third embodiment will be described. As described above, the label printer paper 100 according to the third embodiment is a continuous printing medium in which mountain folds and valley folds are alternately repeated with respect to the printing surface at every predetermined folding interval. Therefore, as shown in FIG. 10, the bent recess 113 formed at each folding interval corresponds to a mountain fold and a valley fold, and therefore when the print surface is folded into a fold, a recess is formed on the release paper 102 side. When the print surface is folded, a recess is formed on the thermal label paper 101 side.
For example, as shown in FIG. 10 (b), when forming the perforation 107 at the valley portion of the print surface, punching is performed from the thermal label paper 101 side, thereby bending the printed surface. A perforation 107 and a bent recess 113 are formed. In this regard, when forming the folding perforation 107 at the portion to be folded with respect to the printing surface, the folding perforation 107 and the folding recess 113 are formed by punching from the release paper 102 side. The

As shown in FIG. 10B, the folding perforation 107 is formed at the innermost part of the folding concave part 113, and the innermost part of the folding concave part 113 is the fold of the label printer paper 100 at both ends of the folding concave part 113. Thus, the label printer paper 100 is folded. And since the bending recessed part 113 is formed corresponding to the mountain fold and valley fold with respect to a printing surface, the label printer paper 100 can be folded in ninety-nine folds. In this regard, when the folding perforation 107 is formed, by forming the folding recess 113, the fold is formed once on the label printer paper 100, so that the strength of the portion corresponding to the fold is weakened and is easy. In addition, the label printer paper 100 can be folded.
As described above, in the label printer 1 according to the present embodiment, since the print control based on the sensor mark 105 is performed by executing the print control program, the print across the bent perforation 107 is not executed. Therefore, even when the peripheral portion of the bent perforation 107 is deformed by forming the bent concave portion 113, the printing result on the label printer paper 100 is not adversely affected and can be sufficiently read. A label printed with print quality can be provided.

As described above, the label printer paper 100 according to the present invention is a so-called continuous printing medium that is formed in a long shape and is repeatedly folded and folded at predetermined folding intervals. A separation perforation 110 is formed to separate the inside of the bending interval into unit label pieces 115 having a predetermined printing area.
Here, at the position where the label printer paper 100 is bent by a mountain fold or a valley fold, a bent perforation 107 is formed.
In the first embodiment, the conveyance direction dimension of the cutting part 107 </ b> A of the bent perforation 107 is formed larger than the conveyance direction dimension of the cutting part 110 </ b> A of the separation perforation 110. Therefore, the label printer paper 100 can be easily bent along the bent perforations 107. Furthermore, since the permissible range for cutting is expanded by forming the cutting portion 107 </ b> A with a large conveyance direction dimension, the unit label pieces 115 can be easily separated along the bent perforations 107.

  In the second embodiment, the width direction dimension of the uncut portion 107B of the bent perforation 107 is formed to be smaller than the width direction size of the uncut portion 110B of the separation perforation 110. It is possible to increase the ratio of the cut portion 107A. As a result, the number of parts that need to be folded is reduced, so that the label printer paper 100 according to the second embodiment can be easily folded along the folding perforations 107. Furthermore, inevitably, since the ratio of the non-cutting portion 107B in the bent perforation 107 is reduced, the portion that needs to be cut is reduced, and the unit label piece 115 can be easily separated.

  And in 3rd Example, when forming the bending perforation 107, the bending recessed part 113 corresponding to a mountain fold and a valley fold is formed. In this regard, by forming the bent concave portion 113, the bent perforation 107 has a bending habit corresponding to a mountain fold or a valley fold. Therefore, in the third embodiment, the label printer paper 100 can be easily folded along the folding perforations 107.

  Further, in the label printer paper 100 according to the present invention, a sensor mark 105 indicating the position of the unit label piece 115 within the folding interval is attached to each unit label piece 115 formed within the folding interval. In the label printer 1 in which the label printer paper 100 is used, the photo sensor 11 reads the sensor mark 105 to perform print control for preventing printing across the bent perforation 107. Thereby, even when the bent perforation 107 is formed as in the first to third embodiments, the print quality of the printed label is not affected, and a high print quality label is provided. can do.

In addition, this invention is not limited to description of the said embodiment, A various change is possible in the range which does not deviate from the meaning.
For example, in this embodiment, the label printer paper 100 including the thermal label paper 101 and the release paper 102 has been described as the continuous printing medium, but the present invention is not limited to this. That is, the present invention can also be applied to a printing medium that does not have an adhesive layer and is configured only by so-called thermal paper.

  Further, in the above embodiment, the inside of the folding interval is divided into four by the separation perforations 110, and each unit label piece 115 has a predetermined printing area, so that a maximum of four unit label pieces 115 can be obtained. Although it was possible to acquire, it is not limited to this aspect. For example, the inside of the bending interval may be divided by the separation perforations 110 so as to have more unit label pieces 115, or the inside of the bending interval may be divided into two or three unit label pieces 115. You may do it.

It is the schematic of the label printer paper which concerns on this embodiment. FIG. 5 is an enlarged view around a bent perforation in the label printer paper according to the first embodiment. 1 is an external perspective view of a label printer according to an embodiment. It is a sectional side view of the label printer which concerns on this embodiment. It is principal part sectional drawing of the label printer which concerns on this embodiment. It is a perspective view of the holder attached to the label printer which concerns on this embodiment. It is a block diagram which shows the control system of the label printer which concerns on this embodiment. It is a flowchart of the printing control program of the label printer which concerns on this embodiment. FIG. 6 is an enlarged view around a bent perforation in a label printer sheet according to a second embodiment. It is explanatory drawing of the label printer paper which concerns on 3rd Example. (A) is an enlarged view around the bent perforation, and (b) is a cross-sectional view around the bent perforation.

DESCRIPTION OF SYMBOLS 1 Label printer 100 Label printer paper 105 Sensor mark 105A 1st sensor mark 105B 2nd sensor mark 105C 3rd sensor mark 105D 4th sensor mark 107 Bending perforation 107A Cutting part 110 Separation perforation 110A Cutting part 113 Bending recessed part 115 Unit label piece

Claims (4)

In a printing medium that is formed in a long shape and is folded by alternately repeating mountain folds and valley folds at a constant folding interval with respect to the printing surface printed by the printing device,
For each unit piece having a fixed printing area, the inside of the bending interval is divided into a plurality, and the first perforated portion where the printing medium is cut is intermittently arranged;
Corresponding to the bending space, said together with the second cutting portion printed medium is cut is intermittently arrayed, have a, a perforation bent formed lower strength than the separating perforations,
The width direction dimension of the non-cut portion sandwiched between the adjacent second cut portions in the bent perforation is smaller than the width direction dimension of the non-cut portion sandwiched between the adjacent first cut portions in the separation perforation. A printing medium characterized by being formed. The printing medium according to claim 1,
The printing medium according to claim 1, wherein a dimension in the conveyance direction of the second cutting part is formed larger than a dimension in the conveyance direction of the first cutting part. In the printing medium according to claim 1 or 2 ,
A printing medium according to the present invention, wherein the folding perforation is provided with a folding habit according to a folding state of a mountain fold or a valley fold. In the printing medium according to any one of claims 1 to 3 ,
A printing medium, wherein a sensor mark indicating the position of the unit piece within the folding interval is attached to the back surface of the printing surface of each unit piece.

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