JP5324268B2 - Printing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a printing apparatus which can miniaturize an apparatus configuration and is also high in usefulness to users by constituting to print a passbook and a business form by printers suitable for respective printing, and to discharge both of passbook and the business form after being printed from an inserting port for the passbook by using a common feeding path. <P>SOLUTION: The passbook inserted from the inserting port 11 is stopped once by a first feeding path 21 at a predetermined alignment location, and then conveyed toward a first printer unit 12 by a serial head 12a. Also, the printed passbook is conveyed in the opposite direction and discharged from the inserting port 11. The first feeding path 21 conveys the business form which is printed by a second printer 14 set at the inner side and merged with a second feeding path 25 to the inserting port 11 by back feeding. An alignment shutter 31 is installed at a position inside a predetermined interval from one side end on the first feeding path 21 to be able to retreat along a conveyance direction. The alignment shutter 31 is operated in a retreat state when the business form merged from the second feeding path 25 is conveyed to the inserting port. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a printing apparatus having two types of printer units with different printing methods.

  Currently, dot printers are used for printing on bankbooks used in financial institutions. This dot printer has a dot head that moves in the printing direction, and performs printing by striking the passbooks on the platen together with the ink ribbon by the dot pins. In addition, when printing on passbooks in this way, it is also required to print on forms such as calculation sheets. Conventionally, printing on this form has also been performed by a dot printer used for printing on a passbook (see, for example, Patent Document 1).

  Here, printing with a passbook is indispensable with a dot printer, but printing on a form is not necessarily performed with a dot printer. As is well known, dot printers perform printing by moving a dot head so as to traverse the conveyance direction of a printing target, so the printing speed is relatively low. For this reason, printing with a dot printer up to a form also prolongs the printing time and is not preferable from the viewpoint of efficiency.

  Therefore, it has been considered that the passbook is printed by a dot printer, and the related forms are printed by, for example, a thermal printer using a stationary line head capable of printing at higher speed (for example, see Patent Document 2).

JP 2007-190904 A Japanese Utility Model Publication No. 2-15366 (Japanese Utility Model Application No. 63-93688)

  However, the prior art described in Patent Document 2 has a structure in which a passbook printing device using a dot printer and a form printing device using a thermal printer are simply provided side by side. For this reason, even if it tried to apply to the ATM apparatus etc. of a financial institution, the apparatus structure could not be reduced in size and it was difficult to apply.

  An object of the present invention is to perform printing on a first print medium such as a passbook and a second print medium such as a form by using a printer unit suitable for each, and the first print medium and the second print medium after printing. In addition, it is an object of the present invention to provide a printing apparatus that can be downsized and highly convenient for the user by using the common conveyance path to discharge the first printing medium from the insertion port.

The printing apparatus of the present invention temporarily stops the insertion port and the first print medium inserted through the insertion port at a predetermined alignment position, and then conveys the printed sheet to the predetermined printing position in the downstream direction and performs printing. A first conveyance path for conveying the first print medium in a direction opposite to the downstream direction and discharging the first print medium from the insertion port; and the print position on the first conveyance path. A first printer unit for moving the serial head in the transverse direction of one conveyance path to perform printing on the first print medium, and a rear side of the first printer as viewed from the insertion port; The second printer unit that performs printing on the second print medium having a larger width dimension orthogonal to the transport direction than the first print medium by the stationary line head and the second printer unit. The printed second printing medium is the first printing medium. A second transport path that is joined downstream of the first printer unit and discharged from the insertion port through the first transport path, and a predetermined end from one end of the first transport path. The second transport path is arranged along the transport direction at a position inside the interval and is configured to be retractable from the first transport path, and the first transport path joins the second transport path. An alignment shutter that is operated in a retracted state when transporting the print medium, and the first print medium that is provided in the first transport path, moves the first print medium toward the side surface of the alignment shutter, and An alignment roller that abuts one side of the medium against the side surface of the alignment shutter, and the width dimension of the first transport path is set corresponding to the width dimension of the second print medium, Alignment from one end The interval to the shutter is an interval corresponding to the acceleration / deceleration distance of the serial head .

  In the present invention, the printing speed of the second printer unit is higher than that of the first printer unit.

  In the present invention, the first printer unit is a serial printing method, and the second printer unit is a line printing method.

  According to the present invention, printing on a first print medium such as a bankbook and a second print medium such as a form is performed by a printer unit suitable for each, and the first print medium printed by each printer unit and the first print medium The shape of the conveyance path for discharging the two print media in common from the insertion port of the first print medium and the peripheral portion thereof can be minimized, and the overall size of the apparatus can be reduced.

1 is an external view showing an embodiment of a printing apparatus according to the present invention. FIG. 2 is a plan view of the apparatus main body shown in FIG. It is a front view which shows the internal structure of the apparatus main body shown in FIG.

  Hereinafter, an embodiment of a printing apparatus according to the present invention will be described in detail with reference to the drawings.

  FIG. 1 shows the external shape of a printing apparatus according to this embodiment. FIG. 2 shows a plan view of the printing apparatus shown in FIG. Further, FIG. 3 shows the internal configuration of the printing apparatus shown in FIG.

  In FIG. 1, an insertion port 11 for a first print medium such as a passbook (hereinafter, proceeding as a passbook) is provided at the left end of the apparatus body 10. Further, a first printer unit 12 that performs printing on the inserted bankbook is provided at a position on the left side of the center of the apparatus main body 10 in the figure. As the first printer unit 12, for example, a dot printer having a serial head that moves in the printing direction is used. Note that the passbook that has been printed by the dot printer 12 is back-fed in the apparatus main body 10 as will be described later, and is discharged from the insertion slot 11 at the left end in the figure.

  A second printer unit 14 that prints a second print medium (hereinafter, advancing as a form or a sheet) composed of a form such as a calculation form is installed at a position on the right side of the apparatus main body 10 in the figure. For example, a thermal printer having a stationary line head is used as the second printer unit 14. The thermal printer 14 performs predetermined printing on a sheet supplied from a sheet supply unit 15 provided at the right end of the apparatus main body 10 in the drawing, and creates a form such as a calculation form. The paper supply unit 15 stores paper wound in a roll shape. The thermal printer 14 takes in the paper from the paper supply unit 15 from the right side in the figure, performs predetermined printing, and conveys it to the left side in the figure. The printed form paper is discharged from an insertion port 11 at the left end in the figure through a later-described transport path in the apparatus main body 10.

  Next, with reference to FIGS. 2 and 3, the configuration in the apparatus main body 10, particularly focusing on the conveyance path will be described. In the apparatus main body 10, the 1st conveyance path 21 is comprised linearly toward the illustration right side from the insertion port 11 provided in the illustration left end. The dot printer 12 is provided in the middle of the downstream side (right side in the drawing) of the first transport path 21. The first transport path 21 once stops and aligns the passbook inserted through the insertion slot 11 at a predetermined alignment position, and then transports the passbook toward the predetermined print position by the dot printer 12 in the downstream direction. Further, after printing by the dot printer 12, the passbook is conveyed (back fed) in the direction opposite to the downstream direction (left side in the drawing) and discharged from the insertion port 11.

  Specifically, the first transport path 21 is configured by arranging a plurality of pairs of upper and lower transport rollers including a driving roller 22 and a pinch roller 23 at predetermined intervals along the transport direction. FIG. 2 is a view of a part of the first transport path 21 as viewed from above with the upper half of the first transport path 21 open. Only the lower pinch roller 23 is shown. Further, as shown in FIG. 3, a shutter 24 is provided at a position near the insertion roller 11 in the first transport path 21 so as to be opened and closed. The shutter 24 is normally closed so that the bankbook cannot enter the inside of the apparatus main body 10. In front of the shutter 24 (on the left side in the figure), a paper width detection sensor (not shown) for detecting the paper width of the bankbook inserted from the insertion slot 11 and a paper insertion sensor (not shown) for detecting the insertion of the bankbook are provided. It has been. Of course, a transport drive roller 22 and a pinch roller 23 are also provided in front of the shutter 24.

  Further, a pair of upper and lower transport rollers including a drive roller 22 and a pinch roller 23 on the back side (right side in the drawing) of the first transport path 21 can pinch a passbook having a minimum sheet length by two pairs. Arranged at intervals. A portion of the first transport path 21 on the back side from the shutter 24 is an alignment position for aligning the passbook with respect to the dot printer 12.

  The alignment position on the first conveyance path 21 is located at a position (indicated by a one-dot chain line B in FIG. 2) inside a predetermined interval from one side end (indicated by a solid line A in FIG. 2) of the first conveyance path 21. The alignment shutter 31 is disposed along the transport direction and is configured to be retractable from the first transport path 21. The installation interval between the alignment shutter 31 and the side end of the first conveyance path 21 will be described later. A pair of upper and lower alignment rollers (only the pinch roller 33 is shown in FIG. 2) consisting of a drive roller 32 and a pinch roller 33 are arranged at the alignment position on the first transport path 21 with the transport rollers 22 and 23. It is provided in the orthogonal direction. The alignment rollers 32 and 33 move the passbook stopped at the alignment position toward the side surface of the alignment shutter 31, and align one side of the passbook with the side surface of the alignment shutter 31 for alignment.

  In FIG. 3, the alignment shutter 31 and the alignment rollers 32 and 33 are illustrated in a perspective manner in order to prevent complication of the drawing.

  In addition, although not shown, a sensor for detecting the paper length of the passbook is provided at this alignment position.

  The dot printer 12 includes a dot head 12 a and a platen 12 b arranged above and below the first transport path 21. The platen 12b is installed on the first conveyance path 21 in a direction crossing the conveyance direction (a direction orthogonal to the paper surface). Further, the dot head 12 a reciprocates along the length direction of the dot head 12 a, that is, in a direction crossing the transport direction of the first transport path 21. And it prints on the printing page of the passbook located on the platen 12b.

  The thermal printer 14 used as the second printer unit is disposed on the back side when viewed from the insertion port 11. As described above, the thermal printer 14 takes in the paper from the paper supply unit 15 from the right side in the figure, performs predetermined printing, and conveys it to the left side in the figure. A second transport path 25 is installed on the discharge side of the thermal printer 14. The second transport path 25 also has a transport roller composed of a drive roller 22 and a pinch roller 23, and transports the paper printed by the thermal printer 14 diagonally downward to the left in the figure. It merges downstream (right side in the figure) from the printer 12. The printed form paper merged in the first conveyance path 21 is conveyed (back-feeded) to the insertion port 11 at the left end in the drawing by the first conveyance path 21 and discharged.

  A collection unit (hereinafter referred to as a capture bin) 26 is installed at the downstream end of the first conveyance path 21, that is, on the downstream side (right side in the drawing) from the junction with the second conveyance path 25. As will be described later, the capture bin 26 is used to collect a passbook or form sheet that has been forgotten at the insertion slot 11.

  Further, as shown in FIG. 3, a flapper 27 can be switched at the junction between the first conveyance path 21 and the second conveyance path 25. The flapper 27 is configured to be rotatable about the right side in the figure. Then, in a state where the paper sheet is rotated counterclockwise by its own weight, a combined flow path for guiding the form paper printed by the thermal printer 14 from the second transport path 25 onto the first transport path 21 is formed. On the other hand, in a state where the actuator is rotated clockwise by an actuator (not shown), a recovery path connecting the first transport path 21 and the capture bin 26 is formed as shown. The collection path guides the passbook or paper conveyed by the first conveyance path 21 to the capture bin 26 in order to collect the forgotten passbook and form paper remaining in the insertion slot 11. In other words, the flapper 27 is provided at the junction between the first conveyance path 21 and the second conveyance path 25 and is switched to form the above-described merge path or recovery path.

  Here, between the passbook printed by the dot printer 12 and the form paper printed by the thermal printer 14, the width of the form paper is larger. These passbooks and form papers are conveyed to the passbook insertion slot 11 by backfeeding the first conveyance path 21 after printing. Therefore, the first transport path 21 transports the passbook and form paper having different sizes, and the width dimension in the transport direction is set according to the large form paper.

  By the way, as described above, the dot printer 21 that prints the passbook moves the dot head 12a back and forth in the direction crossing the first transport path 21, and prints on the passbook print page located on the platen 12b. . The movement width (printing width) of the dot head 12 is set to the maximum width of the passbook to be printed and differs depending on the size of the passbook, but the print start point needs to be adjusted to a certain point. For this reason, at the alignment position, the passbook is moved by the alignment rollers 32 and 33 in the direction orthogonal to the conveying direction, the side portions of the passbook are brought into contact with the alignment portion and aligned, and the printing start point of the dot head 12 is set. Align.

  Here, in order to simplify the structure at the alignment position, the alignment unit is fixedly installed at one end of the first conveyance path 21, and the side portions of the passbook are brought into contact with the alignment unit by the alignment rollers 32 and 33. It is conceivable to align them. However, with such a configuration, a wasteful space is created on the side of the first transport path 21, and the entire apparatus cannot be reduced in size.

  In other words, the dot head 12a performs printing by reciprocating in the direction crossing the first conveyance path 21, and for each reciprocation, an acceleration / deceleration area is generated at both ends of the moving area, and printing is performed during this period. Performed in the constant speed range. For this reason, when the one side end of the first transport path 21 is used as the alignment section as described above, the printing start point (the end of the constant speed region) by the dot head 12a is the one side end of the first transport path 21. A space for an acceleration / deceleration area must be provided on the side of the first conveyance path 21 at a point corresponding to the portion.

  Therefore, in the present invention, as shown in FIG. 2, on the first conveyance path 21, the alignment shutter 31 is moved from the one side end indicated by the thick line A to a position inside the predetermined interval indicated by the thick dashed line B. Arranged along. The printing start point (the end of the constant speed region) by the dot head 12a with respect to the bankbook aligned by the alignment shutter 31 has moved into the first transport path 21 by the predetermined interval. That is, since the acceleration / deceleration region of the dot head 12a is included in the first transport path 21, it is necessary to provide a large space for the acceleration / deceleration region of the dot head 12a on the side of the first transport path 21. Will disappear.

  If the distance from one side end of the first transport path 21 to the alignment shutter 31 is set to a value equal to or greater than the acceleration / deceleration distance of the dot head 12a, the side of the first transport path 21 Space for the acceleration / deceleration area of the dot head 12a can be eliminated. However, it is not always necessary to set the interval to be greater than the acceleration / deceleration distance of the dot head 12a. Even when the interval shorter than the acceleration / deceleration distance of the dot head 12a is set, the printing start point (the end of the constant speed region) by the dot head 12a moves into the first transport path 21 by the interval, so The space for the acceleration / deceleration area of the dot head 12a on the side of one transport path 21 can be reduced, which is effective in reducing the size of the entire apparatus.

  As described above, since the alignment shutter 31 is arranged along the transport direction at a position inside the predetermined interval from one side end of the first transport path 21, the dot head 12 a on the side of the first transport path 21 is arranged. The space for the acceleration / deceleration area can be eliminated or reduced, and the entire apparatus can be miniaturized.

  However, the alignment shutter 31 becomes an obstacle to the conveyance of the form paper printed by the thermal printer 14 to the insertion slot 11 of the passbook, and therefore can be retracted from the first conveyance path 21. Configure as follows. Specifically, it is configured such that it can be moved up and down by an operating mechanism (not shown), and is configured to retreat upward from the first transport path 21.

  In the above configuration, when a passbook is inserted into the insertion slot 11, it is first determined whether or not the passbook is correct by a paper width detection sensor (not shown). As a result, when the passbook is recognized and a paper insertion sensor (not shown) detects the passbook, the shutter 24 is opened and the drive roller 22 and the pinch roller 23 start conveying the paper. At this time, the alignment shutter 31 is lowered to the alignment position on the first conveyance path 21, and the alignment reference in the first conveyance path 21 is a passbook position that enters a predetermined interval inside from one side end thereof.

  When the passbook reaches the alignment position, the length of the passbook is detected by a paper length sensor (not shown), and the alignment rollers 32 and 33 stop the passbook at a position determined for each paper length. Then, the passbook is moved in the width direction orthogonal to the conveyance direction by the alignment rollers 32 and 33, and one side of the passbook is brought into contact with the side surface of the alignment shutter 31 to be aligned. That is, the passbook print page is aligned with the print start position by the dot head 12a.

  When the passbook is correctly aligned, the print position is detected by a passbook line detection mechanism (not shown), the print portion of the passbook is conveyed onto the platen 12b, and printing is performed by operating the dot head 12a.

  When printing on the passbook is completed, the passbook is back-fed through the first conveyance path 21 and discharged from the insertion roll 11. If the customer forgets to take this passbook, it is transported again downstream by the first transport path 21 after a predetermined time has elapsed. At this time, the flapper 27 provided at the junction with the second transport path 25 is rotated clockwise around a fulcrum on the right side of the drawing to collect the first transport path 21 and the capture bin 26. Form a path. For this reason, the passbook that has been transported in the downstream direction by the first transport path 21 is recovered to the cap pin 26 through the junction where the recovery path is formed by the flapper 27.

  When printing a form such as a calculation document, the paper is supplied from the paper supply unit 15 to the thermal printer 14, printed by the thermal printer 14, then cut by a rotary cutter (not shown), and the second transport path 25. The form paper printed by is conveyed diagonally downward to the left in the figure. At this time, the flapper 27 is rotated counterclockwise around a fulcrum on the right side of the drawing to form a combined flow path leading from the second transport path 25 to the first transport path 21. Further, the alignment shutter 31 on the first transport path 21 is raised and retracted from the first transport path 21.

  In such a state, the form paper printed by the thermal printer 14 is merged from the second conveyance path 25 onto the first conveyance path 21 via a merge section where a merge path is formed by the flapper 27. . The first conveyance path 21 back-feeds the merged form paper and discharges it from the insertion roll 11 on the front side (the left side in the figure) of the apparatus main body 10. At this time, as described above, since the alignment shutter 31 is retracted from the first transport path, there is no obstacle such as the back-fed form paper being caught.

  If the customer forgets to remove the form paper discharged to the passbook insertion slot 11, as with the passbook, after a certain period of time, it is transported downstream again by the first transport path 21, and the flapper 27 forms a collection path. The cap pin 26 is made to recover through the joining portion. At this time as well, the alignment shutter 31 remains retracted from the first conveyance path, so that it does not suffer from trouble such as catching the form sheet conveyed in the downstream direction.

  In this way, the first printer unit 12 for printing a passbook is arranged on the front side and the second printer unit 14 for printing a form is arranged on the back side, and the passbook and the form paper printed thereby are transferred to the apparatus main body 10. Since it is made to discharge in common from the insertion port provided on the front side of the printer, it is more convenient for the user than the conventional printing device in which printers with different printing methods are simply arranged in parallel. Miniaturization becomes possible.

  The first printer unit 12 for passbook printing is a system that performs printing by moving a serial head, such as a dot head 12a, and is a stationary line like the second printer unit 14 for form printing. The print processing speed including the print speed and the conveyance speed of the print target portion is slower than that in which printing is performed by the head. In the present invention, the first printer unit 12 for passbook printing, which has a relatively slow printing processing speed, is arranged on the near side near the insertion slot 11, and the second printer unit 14 for form printing, which has a relatively fast printing processing speed, is provided. Since it is arranged on the back side with respect to the insertion slot 11, it is possible to perform printing efficiently without reducing the overall throughput.

  Further, the first conveyance path 21 is shared by the passbook printed by the first printer unit 12 and the conveyance of the form paper printed by the second printer unit 14. The first printer unit 12 has a serial head (dot head in the above-described embodiment) 12a and performs printing by reciprocating in the direction crossing the first conveyance path 21. For each reciprocation, an acceleration / deceleration region is generated at both ends of the moving region, and printing is performed in a constant speed region during this time.

  In the present invention, since the moving area of the serial head 12a including the acceleration / deceleration area is included in the width dimension of the first conveying path 21, the first conveying path (the width dimension corresponding to the form paper having a large width dimension). The alignment shutter 31 is removably installed at a predetermined interval from one side end of 21), that is, at an inner position at an interval corresponding to the acceleration / deceleration distance of the serial head 12a described above. When the passbook is printed by the first printer unit 21, the alignment shutter 31 is arranged on the first transport path 21, and the printing start point of the passbook is predetermined from one side end of the first transport path 21. It is aligned with the constant speed region start point of the serial head 12a inside the interval. Further, when the form paper printed by the second printer 14 is transported, the alignment shutter 31 is retracted from the first transport path 21 so as not to obstruct the transport of the form paper.

  As a result, the space corresponding to the acceleration / deceleration distance of the serial head 12a on the side of the first conveyance path 21 is eliminated or reduced, so that the entire apparatus can be reduced in size.

DESCRIPTION OF SYMBOLS 11 ... Insertion port 12 ... 1st printer part 14 ... 2nd printer part 21 ... 1st conveyance path 22, 23 ... Conveyance roller 25 ... 2nd conveyance path 26 ... Collection | recovery part 27 ... Flapper 31 ... Alignment shutter 32 33 Alignment rollers

Claims (3)

Insertion slot,
The first print medium inserted from the insertion port is once stopped at a predetermined alignment position, and then conveyed in the downstream direction toward the predetermined print position, and the printed first print medium is moved in the downstream direction. A first transport path for transporting in the opposite direction and discharging from the insertion port;
A first printer unit which is provided at the printing position on the first conveyance path and performs printing on the first print medium by moving a serial head in a transverse direction of the first conveyance path;
The first printer is disposed on the back side when viewed from the insertion port, and is moved to the second print medium having a width that is larger than the first print medium and perpendicular to the transport direction by a stationary line head. A second printer unit for printing;
The second print medium printed by the second printer unit is merged downstream of the first printer unit in the first conveyance path, and discharged from the insertion port by the first conveyance path. A second transport path to be
The first transport path is arranged along the transport direction at a position inside a predetermined interval from one side end of the first transport path, and is configured to be retractable from the first transport path. An alignment shutter that is operated in a retracted state when transporting the second print medium merged from two transport paths ;
An alignment roller that is provided in the first conveyance path, moves the first print medium toward a side surface of the alignment shutter, and abuts one side of the first print medium on the side surface of the alignment shutter; With
The width dimension of the first transport path is set corresponding to the width dimension of the second print medium, and the distance from the one side end to the alignment shutter is the acceleration / deceleration distance of the serial head. Printing device characterized by corresponding spacing .   The printing apparatus according to claim 1, wherein the second printer unit has a higher printing speed than the first printer unit.   The printing apparatus according to claim 1, wherein the first printer unit is a serial printing method, and the second printer unit is a line printing method.

Images