JP5772449B2 - Printing device - Google Patents

Description

  The present invention relates to a printing apparatus that forms a desired print on a print-receiving tape.

  As a printing apparatus that performs printing on a print-receiving tape, for example, there is a tape printing apparatus described in Patent Document 1. In this prior art, a conveying means (platen roller) to which a driving force is applied by a drive motor conveys a print-receiving tape (printing tape), and the printing means (thermal head) is applied to the conveyed print-receiving tape. A print object such as a desired text character or image is formed.

JP 2005-216071 A

  For example, a tape on which design objects such as logos, marks, and animation characters are formed in advance may be used as the print-receiving tape. In this case, when the printing unit forms the print object on the design object, the design object and the print object appear to overlap each other visually in the finished printed matter, and in some cases, the visibility is inferior, which is inconvenient. there were.

  An object of the present invention is to provide a printing apparatus that can improve the convenience of the user by separating the print object from the design object for easy viewing even when using a tape on which the design object is formed in advance.

To achieve the above object, the present invention provides a tape cartridge capable of supplying a print-receiving tape having a design object area in which a design object is formed in advance and a non-design object area in which the design object is not formed. A cartridge holder that can be attached and detached, a transport means for transporting the print-receiving tape supplied from the tape cartridge mounted on the cartridge holder, and a print-receiving tape for the print-receiving tape transported by the transport means. A printing unit that forms a desired print object, a detection unit that is provided upstream of the printing unit in the conveyance direction of the conveyance unit and that detects the design object area conveyed by the conveyance unit, and the detection Based on the detection result of the means, the design of Wherein without the formation of the printing object-object region as the non-design object area effect formation of said print object, and control means for controlling said conveying means and said printing means, said receiving tape by said conveying means One of the design objects is provided on the downstream side of the printing unit along the conveyance path, and cuts the print-receiving tape based on the control of the control unit so that the cut portion becomes an upstream end in the conveyance direction. Cutting means capable of sequentially generating a first printed material, a second printed material following the first printed material, and a third printed material following the second printed material, each having a region at the downstream end in the transport direction; And the control means includes the design object area included in the area to be the third printed matter of the print-receiving tape. In response to the detection by the detection means, the transport of the print-receiving tape is stopped, and the transport of the print-receiving tape is cut at a portion which is an upstream end in the transport direction of the first printed matter. The design object area included in the area to be the third printed matter of the print-receiving tape is detected by the detection means, and the conveyance of the print-receiving tape is stopped. In some cases, the design object region included in the region to be the second printed matter is positioned between a portion cut by the cutting unit and a portion facing the printing unit in the print-receiving tape. It is characterized by.

  In the present invention, the print-receiving tape is supplied from the tape cartridge mounted on the cartridge holder, and the supplied print-receiving tape is transported by the transport means. A desired printed matter such as a print label is formed by forming a print object such as a text character or an image on the transported print-receiving tape by the printing means.

  At this time, in the present invention, a detection unit is provided on the upstream side in the transport direction from the printing unit, and the control unit controls driving of the printing unit based on the detection result of the detection unit. Thus, the printing unit is controlled so that the print object is not formed in the design object area but in the non-design object area. As a result, the printed object is not visually overlapped with the design object in the finished printed matter, and the printed object is separated from the design object and can be easily seen. As a result, user convenience can be improved.

  According to the present invention, even when a tape on which a design object is formed in advance is used, the print object is separated from the design object for easy viewing, and the convenience for the user can be improved.

1 is a perspective view illustrating an overall configuration of a print label producing apparatus according to an embodiment of the present invention. It is a perspective view showing the internal structure of the print label producing apparatus in a state where the detachable cover is removed and the cartridge and the dry battery are removed from the cartridge holder and the battery storage unit. It is a top view showing the internal structure of a cartridge with a roller holder, a rib, a heat sink, a thermal head, etc. It is a block diagram which shows the functional structure of the control system in a label production apparatus. It is explanatory drawing showing the comparative example used as the state where the design object and the printing object overlapped. It is a figure showing the external appearance of the to-be-printed tape provided with the design object area | region and the non-design object area | region. It is a circuit diagram showing the detection circuit structure of an object sensor. It is explanatory drawing showing the mode of the detection of the design object of the to-be-printed tape by an object sensor. It is explanatory drawing showing the state by which the printing object was isolate | separated from the design object by the method of embodiment. FIG. 10 is an explanatory diagram illustrating another comparative example in which a design object and a print object overlap each other. It is explanatory drawing showing the state which isolate | separated in the form by which the design object is inserted | pinched in the middle of the printing object by the method of embodiment. It is a flowchart showing the control procedure performed by a control part. It is explanatory drawing showing an example of the produced printing label. It is explanatory drawing showing the modification which resizes a printing object so that it may be settled between two design objects. It is a flowchart showing the control procedure performed by a control part. It is explanatory drawing showing the comparative example with respect to the modification which shifts a printing object to a tape width direction, and avoids a design object. It is explanatory drawing showing the modification which shifts a printing object to a tape width direction and avoids a design object. It is explanatory drawing showing another aspect of the modification which shifts a printing object to a tape width direction and avoids a design object. It is explanatory drawing explaining that a useless non-printing area arises in the conveyance direction downstream part of each printing label regarding the modification provided with the cutting mechanism which performs automatic cutting. It is explanatory drawing showing conveyance and the cutting | disconnection behavior of the modification which provided the cutting mechanism which performs automatic cutting | disconnection. It is a flowchart showing the control procedure which a control part performs.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the following figures, if there are notes of “front”, “rear”, “left”, “right”, “upper”, “lower”, in the description in the specification, the front, rear, left, right Up, down refers to the noted direction.

<Appearance outline structure of the device>
As shown in FIG. 1, a print label producing apparatus 1 (printing apparatus) is a handy type print label producing apparatus that is gripped by a user's hand. The casing 6 of the print label producing apparatus 1 is composed of a front cover 6A that constitutes the front face of the apparatus and a rear cover 6B that constitutes the rear face of the apparatus. Further, the rear cover 6B includes a rear cover body 6B1 incorporating various mechanisms, and a removable cover that can be removed from the rear cover body 6B1 when a cartridge 31 (see FIG. 2 described later) or a dry battery (not shown) is attached or detached. 6B2.

  A display unit 550 (see FIG. 4 described later) for displaying various setting screens and the like is provided on the upper side of the front cover 6A. The front surface of the display unit 550 is covered with a cover panel 2A that is, for example, a transparent acrylic plate. An operation unit 3 for operating the print label producing apparatus 1 is provided below the display unit 550. The operation unit 3 includes character keys such as characters, symbols, and numbers, various function keys, appropriate buttons, and the like. When the user inputs the content to be formed as a print object (described later) on the print label L (see FIG. 13 described later) based on the operation of the operation unit 3, corresponding print data is generated, and the content is displayed on the display unit. Is displayed at 550. A cut lever 4 for cutting the printed label tape 80 (see FIG. 3 described later) is provided at the upper right end of the rear cover body 6B1.

<Internal structure of the device>
The internal structure of the print label producing apparatus will be described with reference to FIG. As shown in FIG. 2, a frame 13 made of resin, for example, is disposed inside the front cover 6A and the rear cover body 6B1. The cartridge holder 7 having a rectangular shape in plan view formed in a concave shape for attaching and detaching the cartridge 31 is provided on the upper rear side of the frame 13.

  Below the cartridge holder 7 is provided a motor storage portion 5 for storing a drive motor (not shown). A battery storage 9 for storing the dry battery is provided further below the motor storage 5.

  A tape discharge slit 24 for discharging the printed label tape 80 (see FIG. 3 to be described later) to the outside is formed in the upper portion of the frame 13. A roller holder 17 is provided on the upper right side of the frame 13. On the rear side of the roller holder 17, a plate portion 25 made of synthetic resin having a plate shape is provided so as to cover the roller holder 17. On the upper portion of the plate portion 25, a protruding portion insertion port 10 that is an opening portion is provided. Further, the upper end portion of the rear cover body 6B1 is provided with a lock hole 11, and the lower end portion is provided with two lock holes 12.

  A gear recess 26 formed in a concave shape is provided at a substantially central portion of the frame 13. The gear recess 26 is provided with a gear (not shown), and the gear tooth portion is covered with the concealing umbrella portion 114 and is not exposed. A ribbon take-up shaft 14 for taking up an ink ribbon 55 (see FIG. 3 to be described later) is erected on the rear side of the gear.

  A rib 30 is provided upright on the right side of the ribbon take-up shaft 14. A heat sink 15 which is a rectangular heat sink is provided on the right side surface of the rib 30. A roller shaft 20 is erected between the rib 30 and the tape discharge slit 24. A convex portion 27 is erected on the left side of the roller shaft 20. The convex portion 27 is inserted into a concave portion (not shown) of the cartridge 31 to position the cartridge 31 in the front-rear direction.

  Further, a guide holder 40 that accommodates a cutter holder (not shown) having a cutter blade is provided in the frame 13 in the vicinity of the tape discharge slit 24.

  A rib 42 is formed integrally with the frame 13 in the vicinity of the tape discharge slit 24. The rib 42 formed on the right side of the tape discharge slit 24 is erected vertically with respect to the planar rear surface portion 25A of the plate portion 25.

<Internal structure of cartridge>
The internal structure of the cartridge 31 (tape cartridge) will be described with reference to FIG. As shown in FIG. 3, a ribbon spool 56 around which an ink ribbon 55 is wound is rotatably disposed at the lower left side in the cartridge case 33. The ink ribbon 55 fed out from the ribbon spool 56 is guided toward the cartridge opening 371.

  A ribbon take-up spool 57 is rotatably disposed on the side of the ribbon spool 56 adjacent to the upper right side. The ribbon take-up spool 57 pulls out the ink ribbon 55 from the ribbon spool 56 and winds up the ink ribbon 55 consumed by printing a print object such as a character or an image. Further, on the upper right side of the cartridge 31, there is a print-receiving tape roll 53 (which is originally a spiral shape but is simplified and illustrated as a simple circle). The print-receiving tape roll 53 is obtained by winding the print-receiving tape 101 around a tape reel portion (a reel member having an axis perpendicular to the tape longitudinal direction) 54 to form a roll.

  In this example, the print-receiving tape 101 has a three-layer structure (see a partially enlarged view in FIG. 3), from the side wound inside the tape reel portion 54 toward the opposite side (attachment side), The image receiving layer 101a, the tape layer 101b, and the adhesive layer 101c are laminated in this order. The image receiving layer 101a is formed as a transparent film of a material to be printed on which printing is performed by thermal transfer of ink by being superimposed on the ink ribbon 55. The tape layer 101b is made of an appropriate base material, for example, a synthetic resin such as PET. The adhesive layer 101c is composed of an appropriate adhesive. As a feature of this embodiment, a design object 64 (see FIG. 5 and FIG. 9 described later) such as a logo or a mark is formed in advance on the print-receiving tape 101.

  Further, the cartridge holder 31 has an object sensor 60 (detection means) for optically detecting the design object 64 such as the logo or mark of the print-receiving tape 101 at a portion near the feeding position of the print-receiving tape roll 53. Is provided. In this example, the object sensor 60 includes a projector 60a and a light receiver 60b. The light projector 60 a and the light receiver 60 b are arranged at a position perpendicular to the surface direction of the print-receiving tape 101 across the conveyance path of the print-receiving tape 101 fed out from the print-receiving tape roll 53. In this example, the light projector 60 a is located on the image receiving layer 101 a side of the print-receiving tape 101, and the light receiver 60 b is located on the adhesive layer 101 c side of the print-receiving tape 101.

  On the left side of the cartridge 31 mounted on the cartridge holder 7, an arm-shaped roller holder 17 having a platen roller unit 18 and a discharge roller unit 19 can swing in the left-right direction around the shaft support portion 171. Is provided. When the detachable cover 6B2 is attached, the roller holder 17 is moved toward the cartridge 31 by a projection (not shown). As a result, the discharge roller unit 19 and the platen roller unit 18 provided in the roller holder 17 are moved to the printing position (position shown in FIG. 3).

  The platen roller unit 18 is disposed on the left side of the heat sink 15. The platen roller unit 18 is provided with a platen roller 182 (conveying means) and a platen roller gear (not shown). The platen roller 182 is disposed at a position facing the thermal head 16 (printing means) provided on the left side surface of the heat sink 15. The thermal head 16 includes a plurality of heating elements, and is provided downstream of the object sensor 60 along the tape transport direction. The thermal head 16 forms a desired print object (see FIG. 9 and the like described later) on the print-receiving tape 101 conveyed along the conveyance path by the discharge roller 192, the platen roller 182 and the like. The platen roller gear is meshed with a gear (not shown) provided on the front side of the frame 13, and the platen roller gear 182 is rotated by the rotation of the platen roller gear to which power is transmitted from the drive motor. . Thus, when the platen roller unit 18 moves to the printing position, the platen roller 182 presses the print-receiving tape 101 and the ink ribbon 55 against the thermal head 16 and rotates the print-receiving tape 101 by the rotation. It is conveyed in the direction of the discharge roller unit 19.

  The discharge roller unit 19 is provided with a discharge roller 192 and a discharge roller gear (not shown). The discharge roller 192 is disposed at a position facing the roller shaft 20 and transports the printed label tape 80 along a transport path (see arrows A, A, and C) toward the tape discharge slit 24. The roller shaft 20 includes a cylindrical portion 201 formed in a cylindrical shape and six ribs 202 formed radially from the outer periphery of the cylindrical portion 201 to the outside. The roller shaft 20 is inserted into a shaft hole 391 of a tape transport roller 39 provided in the cartridge 31, and rotatably supports the tape transport roller 39.

  The discharge roller gear is meshed with a gear (not shown) provided on the front side of the frame 13, and the discharge roller 192 is rotated by rotation of the discharge roller gear to which power is transmitted from the drive motor. To do. Thus, when the discharge roller unit 19 moves to the printing position, the discharge roller 192 presses the print-receiving tape 101 against the tape transport roller 39 that is rotatably supported by the roller shaft 20. As a result, the printed tape 101 on which printing has been performed is discharged from the label tape discharge port 59 as the printed label tape 80. The subsequent transport path of the printed label tape 80 is transported by the discharge roller 192 or the like, guided to the tape discharge slit 24, and discharged from the tape discharge slit 24 to the outside of the print label producing apparatus 1. Thereafter, when the user operates the cut lever 4, the printed label tape 80 is cut by the cutter blade.

<Functional structure of control system>
FIG. 4 shows a functional configuration of the control system in the print label producing apparatus 1.

  In FIG. 4, the print label producing apparatus 1 is provided with a control unit 530 including, for example, a microprocessor. The controller 530 includes a drive system 540 including a motor drive circuit (not shown) that controls the drive of the drive motor, a thermal head drive circuit (not shown) that controls energization of the thermal head 16, and the like. The object sensor 60, the display unit 550, and the operation unit 3 are connected via an input / output interface 560.

<Basic operation of printed label production device>
Next, the basic operation of the print label producing apparatus 1 having the above configuration will be described.

  First, in FIG. 3 described above, when the cartridge 31 is mounted on the cartridge holder 7, the print-receiving tape 101 fed out from the print-receiving tape roll 53 passes through the cartridge opening 371 from the object sensor 60, and the thermal head 16 and the platen roller. It is arranged to pass between 182. The ink ribbon 55 fed out from the ribbon spool 56 is overlapped with the print-receiving tape 101 through the cartridge opening 371 while being guided and regulated by a regulating projection (not shown) of the cartridge 31, and the thermal head 16 and the platen roller 182 are left as they are. It becomes the arrangement which passes between.

  For example, when an operation input for label creation is made by the user in the operation unit 3, a corresponding instruction signal is input to the control unit 530 via the input / output interface 560, and label production is started under the control of the control unit 530. Is done.

  When the label production is started, the platen holder 17 is rotated clockwise in FIG. 3, and the platen roller 182 is pressed toward the thermal head 16 so as to sandwich the print-receiving tape 101 and the ink ribbon 55. The At the same time, the platen roller 182 is rotationally driven by the motor driving circuit, and conveys the print-receiving tape 101 and the ink ribbon 55 to the downstream side (see the upper side in FIG. 3, arrow a).

  Simultaneously with the pressure conveyance by the platen roller 182, the heating element is driven by the thermal head driving circuit, and the ink ribbon 55 is applied to the image receiving layer 101a on the surface of the print-receiving tape 101 on the thermal head 16 side (ink ribbon 55 side). The ink is thermally transferred to form a desired print object (see FIG. 9 and the like described later).

  Thereafter, the ink ribbon 55 sent to the downstream side of the thermal head 16 is separated from the print-receiving tape 101 via a separating member (not shown), and then taken up by the ribbon take-up spool 57. Then, the print-receiving tape 101 sent to the downstream side of the thermal head 16 and separated from the ink ribbon 55 becomes the printed label tape 80 and is discharged from the label tape discharge port 59 to the outside of the cartridge 31. It passes through a cutter blade (not shown) and is sent out in the direction of arrow A in FIG.

  When the printed label tape 80 advances by a predetermined distance, the conveyance of the printed label tape 80 and the print-receiving tape 101 is stopped. Thereafter, the cutter blade is actuated to cut the printed label tape 80, whereby a printed label L (see FIG. 13 described later) as a printed matter having a predetermined length is obtained.

<Features of this embodiment>
In the above basic configuration, the greatest feature of the present embodiment is that, based on the detection result of the object sensor 60, the thermal head 16 prints text characters, graphics, etc. while avoiding the design object 64 of the print-receiving tape 101. The object is to form. Hereinafter, the details will be described in order.

  As described above, the print object tape 101 used in the present embodiment is preliminarily formed with design objects 64 such as logos, marks, and animation characters. In this case, if the print formation is performed by the thermal head 16 without taking the arrangement of the design object 64 into consideration, the design object 64 of the design object 64 is shown as a comparative example in FIGS. 5A and 5B, for example. When the print object 65 (in this example, the character “ROCK-I”) is formed so as to overlap, the design object 64 and the print object 65 appear to overlap each other visually, and in some cases, the visibility is inferior. Inconvenient.

  Therefore, in the present embodiment, as described above, the object sensor 60 is provided on the upstream side in the transport direction from the thermal head 16, and the thermal head 16 avoids the design object 64 based on the detection result of the object sensor 60. A print object 65 is formed on the print-receiving tape 101. That is, as shown in FIG. 6, in this embodiment, the design object areas Q including the design objects 64 printed in advance at predetermined intervals are discretely arranged with a predetermined pitch p on the print-receiving tape 101. . The design object 64 may be formed on the image receiving layer 101a or may be formed on the tape layer 101b. A print object area R (non-design object area) for the thermal head 16 to form a print object 65 such as a text character or an image is formed between two adjacent design object areas Q and Q. Yes. When the print-receiving tape 101 is conveyed as described above, the design object 64 is sequentially detected by the object sensor 60 installed in the vicinity of the feeding position of the print-receiving tape 101 of the print-receiving tape roll 53. .

<Object sensor>
Detailed functions of the object sensor 60 will be described with reference to FIGS. As shown in FIG. 7, a light projector 60a (for example, a light emitting diode) and a light receiver 60b (for example, a phototransistor) of the object sensor 60 are connected in parallel between power supply voltage input terminals 66a and 66b. Further, the current limiting resistor R1 is inserted in series on the ground side (the cathode side of the light emitting diode) of the projector 60a, and the load resistor R2 is inserted in series on the ground side (the emitter side of the phototransistor) of the light receiver 60b. The detection voltage value V (sensor output of the object sensor 60) is extracted from the output terminal 67 between the light receiver 60b and the load resistor R2. For example, + 3.3V is used as the power supply voltage Vcc. The detected voltage value V from the object sensor 60 is input to the control unit 530. In the configuration shown in the figure, the detected voltage value V from the object sensor 60 increases as the amount of received light increases, but the detected voltage value V from the object sensor 60 decreases as the opposite polarity and received light amount increase. You may make it give such a characteristic.

  FIG. 8 schematically shows how the object sensor 60 detects the design object 64 of the print-receiving tape 101.

  In FIG. 8, the print-receiving tape 101 is fed out from the print-receiving tape roll 53 in the direction of the arrow and conveyed. For example, when the design object area Q including the design object 64 on the print-receiving tape 101 passes on the optical path λ of the light emitted from the light projector 60a of the object sensor 60 to the light receiver 60b, the light is emitted from the light projector 60a. The amount of light received by the light receiver 64b is reduced by light, and the sensor output voltage (corresponding to the detected voltage value V. The same applies hereinafter) output from the light receiver 64b decreases corresponding to the amount of received light.

  Thereafter, it is assumed that the print object region R (the print object 65 is not yet formed) at the upstream side in the transport direction subsequent to the design object region Q is positioned on the optical path λ. In this case, the light emitted from the projector 60a is not shielded, the amount of light received by the light receiver 64b is increased, and the sensor output voltage output from the light receiver 64b is increased corresponding to the amount of received light. The control unit 530 can identify the design object 64 based on the difference in the sensor output voltage of the object sensor 60 between the design object 64 in the design object area Q and the print object area R.

  The object sensor 60 may be a reflective sensor instead of the so-called transmissive sensor as described above. In this case, both the light projector and the light receiver are provided on the image receiving layer 101 a side of the print-receiving tape 101. Then, the projector projects light toward the print-receiving tape 101, the light receiver receives the reflected light reflected from the print-receiving tape 101 after being emitted from the projector, and outputs a voltage corresponding to the received light quantity. .

<Specific example of the method of this embodiment>
In response to the detection of the design object by the object sensor 60 executed as described above, the control unit 530 controls the thermal head 16 to form the print object 65 on the print-receiving tape 101 so as to avoid the design object 64. . Thus, unlike the comparative example shown in FIG. 5 described above, in this embodiment, as shown in FIGS. 9A and 9B, the thermal head 16 has a print object in the design object area Q. Control is performed so that 65 is not performed but is performed on the print object region R. Specifically, as shown in FIG. 9B, the print object 65 is formed in the print object region R adjacent to the detected design object region Q on the upstream side in the transport direction. In particular, in the example of FIG. 9B, when the design object region Q is detected at the transport direction position that is the formation start position of the print object 65 in the print-receiving tape 101, the design object region Q is transported upstream in the transport direction. In the example, the formation of the print object 65 is started from the print object region R adjacent to the side.

  Further, when the design object region Q is detected at the transport direction position in the middle of forming the print object 65 in the print object region R of the print-receiving tape 101, the design object region Q is left as it is in FIGS. 10 (a) and 10 (b). As shown as a comparative example, the design object 64 overlaps the middle of the print object 65, which is inconvenient as described above. In the illustrated example, the “CD” portion overlaps the design object 64 and is difficult to see.

  Therefore, in this embodiment, based on the control of the control unit 530, in such a case, the thermal head 16 reaches the upstream end in the conveyance direction of one print object region R (in other words, as shown in FIG. 11). The formation of the print object 65 is interrupted once (before the design object area Q). In the example shown in the drawing, printing is suspended until “July 2011”. Thereafter, the formation of the print object is resumed from the new print object region R adjacent to the upstream side of the design object region Q in the transport direction. In the illustrated example, “CD” is printed after restarting.

  As a result, as shown in FIGS. 9B and 11, in this embodiment, the print object 65 does not visually overlap the design object 64, and the print object 65 is separated from the design object 64 and is clean. It becomes easier to see. As a result, user convenience can be improved.

<Control procedure>
The processing procedure executed by the control unit 530 in order to realize the above contents will be described with reference to FIG. When the user inputs a label creation operation by operating the operation unit 3, for example, with the cartridge 31 mounted in the cartridge holder 7 of the print label creating apparatus 1, this flow is started.

  First, in step S5, the control unit 530 outputs a control signal to the motor drive circuit, and rotationally drives the platen roller 182 and the ribbon take-up spool 57. As a result, the conveyance of the print-receiving tape 101 by the platen roller 182 and the conveyance of the ink ribbon 55 by the ribbon take-up spool 57 are started. As a result, the print-receiving tape 101 is conveyed from the platen roller 182 to the head surface of the thermal head 16 via the ink ribbon 55 while being fed from the print-receiving tape roll 53.

  Thereafter, in step S10, the control unit 530, based on the detection result of the object sensor 60, on the print-receiving tape 101, the same position (or upstream) as the transport direction position that is the print start position of the print object 65 based on the print data. It is determined whether or not the design object 64 in the design object area Q has been detected at the position on the side). If the design object 64 is not detected, the determination in step S10 is not satisfied (S10: NO), and the process proceeds to step S20 described later. If the design object 64 is detected, the determination in step S10 is satisfied (S10: YES), and the process proceeds to step S15.

  In step S <b> 15, the control unit 530 shifts the print start position originally set by the print data to the upstream side of the print-receiving tape 101 and resets the print object so as to be on the upstream side of the design object 64. Thereafter, the process proceeds to step S20.

  In step S20, the control unit 530 determines whether or not the print-receiving tape 101 has been transported to the print start position (or print resume position), in other words, the print start position (or print resume position where the thermal head 16 has been reset). ) To determine whether or not the print-receiving tape 101 has reached a position directly facing. In this determination, for example, the number of pulses output from the motor drive circuit that drives the drive motor that is a pulse motor after the timing when the design object 64 is detected in step S10 is counted. It is sufficient to detect whether or not the value is reached. The determination is not satisfied until the print start position (or print resume position) is reached (S20: NO), and the loop waits. When the print start position (or print resume position) is reached, the determination in step S20 is satisfied (S20: YES). Control goes to step S25.

  In step S <b> 25, the control unit 530 outputs a control signal to the thermal head driving circuit and energizes the heating element of the thermal head 16. As a result, the thermal head 16 starts to form the print object 65 corresponding to the print data on the surface of the image receiving layer 101a of the print-receiving tape 101.

  In step S30, the control unit 530 sets the print-receiving tape 101 to the print end position (or print interruption position) based on the print data by an appropriate method such as counting the number of motor pulses of the motor drive circuit described above. In other words, the print-receiving tape 101 has reached the position where the thermal head 16 is directly opposite the print end position (or print interruption position) corresponding to the reset print start position (or print resume position). Whether or not. If the print end position (or print interruption position) has not been reached, the determination in step S30 is not satisfied (S30: NO), and the process proceeds to step S55. If the print end position (or print interruption position) has been reached, the determination in step S30 is satisfied (S30: YES), and the process proceeds to step S35 described later.

  In step S55, the control unit 530, based on the detection result of the object sensor 60, similarly to step S10, the print data (however, if step S15 has been passed, the print start position is reset in step S15). Referring to whether or not the design object 64 of the design object region Q is detected at the same position (or downstream position) as the transport direction position that is the print end position of the print object 65 on the print-receiving tape 101. judge. If the design object 64 is not detected, the determination in step S55 is not satisfied (S55: NO), and the process returns to step S30. If the design object 64 is detected, the determination in step S55 is satisfied (S55: YES), and the process proceeds to step S60.

  In step S60, the control unit 530 changes the setting of the print end position set at this time. In other words, the formation of the print object 65 is temporarily interrupted on the downstream side of the design object 64 position detected in step S55, and the print object 65 is reset so as to resume printing on the upstream side of the design object 65 position. Thereafter, the process returns to step S30.

  In step S <b> 35, the control unit 530 outputs a control signal to the thermal head driving circuit, and stops energization of the heat generating elements of the thermal head 16. As a result, the formation of the print object 65 on the print-receiving tape 101 by the thermal head 16 stops. Thereafter, the process proceeds to step S40.

  In step S40, the control unit 530 determines whether there is an unprinted portion of the print object 65 that has not yet been formed on the print-receiving tape 101. If there is an unprinted portion, the determination in step S40 is satisfied (S40: YES), and the same procedure is repeated by returning to step S20. If there is no unprinted portion, the determination in step S40 is not satisfied (S40: NO), and the process proceeds to step S45.

  In step S45, the control unit 530 refers to the print data (however, the print start position, the print end position, etc. are reset when the process passes through step S15 or step S60), and the print-receiving tape 101 ( In other words, whether the printed label tape 80) has reached the cutting position, in other words, whether the printing tape 101 has reached the position where the cutter blade faces the cutting position of the printing tape 101. , Is determined. Until the cutting position is reached, the determination in step S45 is not satisfied (S45: NO), and a loop is waited. If the cutting position is reached, the determination in step S45 is satisfied (S45: YES), and the process proceeds to step S50.

  In step S50, the control unit 530 outputs a control signal to the motor drive circuit, and stops the rotational drive of the platen roller 182 and the ribbon take-up spool 57. As a result, the conveyance of the print-receiving tape 101 by the platen roller 182 and the conveyance of the ink ribbon 55 by the ribbon take-up spool 57 are stopped. Accordingly, when the user operates the cut lever 4, the cutter blade is operated to cut the printed label tape 80, and a print label L (see FIG. 13 described later) is obtained. Then, this flow ends.

  Note that steps S15 and S60 in the flow shown in FIG. 12 function as transport direction shifting means described in each claim, and each procedure shown in FIG. 12 including them functions as control means.

  As described above, according to the present embodiment, as shown in FIGS. 13A and 13B, in the print label L created as described above, the print object 65 is the design object 64. There is no visual overlap, and the print object 65 is separated from the design object 64 so that it is easy to see clearly. As a result, user convenience can be improved. In particular, in the example shown in FIG. 13B, it is possible to create a print label L in which the print object 65 and the design object 64 are reliably separated so that the design object 64 is sandwiched between the print objects 65. .

  Note that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit and technical idea. Hereinafter, such modifications will be described in order.

(1) When scaling the print object so that it fits between the two design objects In other words, the thermal head 16 starts to form the print object 65 after the print-receiving tape 101 is transported as described above. Before that, there is a design object area Q, a print object area R adjacent to the upstream side in the transport direction of the design object area Q, and another design object area Q adjacent to the upstream side of the print object area R in the transport direction. When detected by the object sensor 60, the control unit 530 can acquire the pitch p, which is the distance between the two design object areas Q and Q.

  Therefore, in this case, the control unit 530 reduces the size of the print object 65 instead of dividing the print object 65 into two print object regions R and R as shown in FIG. The length in the transport direction is set within one print object region R slightly smaller than the pitch p.

  FIG. 14 shows the appearance of this modification. As shown in FIG. 14, the print object 65 of “July 2011 CD” is formed to be reduced so as to fit within one print object region R between the two design objects 64, 64.

  Processing executed by the control unit 530 of this modification will be described with reference to FIG. In the flow shown in FIG. 15, step S20 ′ is provided instead of step S20 in the flow of FIG. 12 of the above embodiment, and step S55 ′ and step S60 ′ are newly provided between step S15 and step S20 ′. In addition, step S30 ′ is provided instead of step S30, and step S40 is omitted. Other than that, it is almost the same as FIG.

  In FIG. 15, the process proceeds to step S55 ′ newly provided through step S5 and step S10 or step S15 similar to FIG.

  In step S55 ′, as in step S55, the control unit 530 determines that the print data is based on the detection result of the object sensor 60 (however, if the process has passed step S15, the print start position is reset in step S15). Referring to FIG. 8, it is determined whether or not the design object 64 in the design object area Q is detected on the downstream side of the transport direction position, which is the print end position of the print object 65, on the print-receiving tape 101. If the design object 64 is not detected, the determination in step S55 ′ is not satisfied (S55 ′: NO), and the process proceeds to step S20 ′ described later. If the design object 64 is detected, the determination at step S55 ′ is satisfied (S55 ′: YES), and the process proceeds to newly provided step S60 ′.

  In step S60 ′, the control unit 530 changes the size of the character or the like of the print object 65 so as to fit between the two design objects 64 and 64 detected in step S10 and step S55 ′, thereby printing. The end position is also reset. Thereafter, the process proceeds to step S20 ′.

  In step S20 ′, as in step S20, the control unit 530 determines whether or not the print-receiving tape 101 has been conveyed to the print start position by an appropriate method such as counting the number of motor pulses of the motor drive circuit described above. judge. The determination is not satisfied until the print start position is reached (S20 ′: NO), and the loop waits. When the print start position is reached, the determination in step S20 ′ is satisfied (S20 ′: YES), and the process proceeds to step S25 similar to the above.

  In step S25, in the same manner as described above, after the formation of the print object 65 (reduced if it has passed through step S60 ') is started, the process proceeds to newly provided step S30'.

  In step S30 ′, the control unit 530 determines whether or not the print-receiving tape 101 has reached the print end position by an appropriate method such as counting the number of motor pulses of the motor drive circuit described above. If the print end position has not been reached, the determination in step S30 'is not satisfied (S30': NO), and the loop waits. If the print end position has been reached, the determination in step S30 'is satisfied (S30': YES), step The process moves to S35.

  Henceforth, since step S35, step S45, and step S50 are the same as that of FIG. 12 of the said embodiment, description is abbreviate | omitted. Note that step S15 and step S60 'in the above flow function as transport direction shifting means described in each claim, and each procedure shown in FIG. 15 including them functions as control means.

  In this modification, two adjacent design object areas Q and Q are detected before the start of formation of the print object 65 (step S10, step S55 '). As a result, the transport direction length of the print object region R located between the two design object regions Q and Q can be calculated. Then, under the control of the control unit 530, the print object 65 is formed while being adjusted so that all of the print objects 65 are accommodated in the print object region R having the length in the transport direction (see step S60 ′). Thus, a print label (not shown) in which the print object 65 and the design object 64 are reliably separated in a form in which the print object 65 is sandwiched between two adjacent design objects 64 and 64 is created. Can do.

(2) When the print object is shifted in the tape width direction to avoid the design object In the above, the print object 65 is shifted in the tape transport direction so as to avoid the design object 64 when it exists. However, it is not limited to this. For example, as shown in FIG. 16, when the print object 65 is formed as usual, the design object 64 and the print object 65 may overlap in the width direction of the print-receiving tape 101. In this case, as shown in FIG. 17, the control unit 530 causes the design object 64 and the print object 65 to be separated in the width direction of the print-receiving tape 101, that is, the print object 65 is shifted downward in the figure of the design object 64. The thermal head 16 may be controlled so as to be formed. Alternatively, as illustrated in FIG. 18, the control unit 530 may control the thermal head 16 so that the print object 65 is formed to be shifted above the design object 64. The function of the control unit 530 at this time corresponds to the width direction shift means described in each claim.

  In the present modification, the print object 65 is shifted to one side in the width direction of the design object area Q. Therefore, the print object 65 is separated to one side in the width direction of the design object 64, and the design object 64 and It can be prevented from overlapping visually.

(3) When a cutting mechanism for performing automatic cutting is provided. That is, in the above, when the print-receiving tape 101 (in other words, the printed label tape 80) reaches a predetermined cutting position, the conveyance is stopped and the user cuts. The tape was manually cut by operating the lever 4. In this modification, a cutting mechanism 615 (cutting means) including a movable blade (not shown) and a fixed blade (not shown) is provided on the downstream side in the transport direction from the thermal head 16. When the tape conveyance is stopped at the predetermined cutting position, the cutting mechanism 615 automatically cuts the tape based on the control of the control unit 530, and the print label L (see FIG. 20D described later) is created. Is done.

  By the way, when the cutting mechanism 615 is provided on the downstream side of the thermal head 16 and automatic cutting is performed as described above, a wasteful non-printing area is necessarily formed on the downstream side (in other words, the leading end side) of each print label L in the transport direction. Arise. This will be described first with reference to FIG.

  As described above, when the cutting mechanism 615 is provided on the downstream side of the thermal head 16 along the transport path, the transport of the print-receiving tape 101 is first started (see FIG. 19A), and printing is performed by the thermal head 16. After the formation of the object 65 is started (see FIG. 19B), the formation of the print object 65 also proceeds as the conveyance proceeds (see FIG. 19C). Then, after the formation to the upstream end (in other words, the rear end) of the print object 65 is finished, the transport is stopped (see FIG. 19D), and the downstream side (rear end side) of the print object 65 in the transport direction. ) Is cut by the cutting mechanism 615, and the print label L is generated (see FIG. 19E). Thereafter, when the next print label L is created, the process returns to the state of FIG.

  As is apparent from the above, when the production of a new print label L is started, the print-receiving tape 101 already existing between the cutting mechanism 615 and the thermal head 16 is inevitably caused by the thermal head 16. This is a non-printing area where printing cannot be performed.

  Therefore, in the present modification, as shown in FIG. 20A, the design object region Q is positioned between the cutting mechanism 615 and the thermal head 16 in a state where the print-receiving tape 101 is stopped. The layout of the design object area Q on the print-receiving tape 101 is set in advance. That is, as described above, the design object area Q is arranged in a portion that is inevitably a non-print area and cannot be printed. Therefore, the length X in the transport direction of the design object region Q is set to be equal to or less than the distance Xo along the transport direction between the cutting mechanism 615 and the thermal head 16.

  At this time, in the present modification, the transport direction from the downstream end portion (in other words, the front end portion) of one design object region Q to the downstream end portion (front end portion) of the subsequent design object region Q in the transport direction. The pitch p, which is the length, is set to be slightly shorter than the distance Yo along the conveying direction from the cutting mechanism 15 to the object sensor 60. Then, the cutting operation by the cutting mechanism 615 is performed in response to the detection of the design object area Q by the object sensor 60.

  That is, similarly to the above, the conveyance of the print-receiving tape 101 is started (see FIG. 20A), and an area (hereinafter referred to as “first print label area”) that becomes one print label (hereinafter referred to as “first print label”). ]) At L01, the thermal head 16 starts to form the print object 65 (see FIG. 20B). However, the design object area Q is present on the downstream side (front end side) in the transport direction from the print object 65 which is started to be formed in the first print label area L01 as described above by the dimension setting as described above. Yes.

  Thereafter, as the conveyance proceeds, the formation of the print object 65 also proceeds (see FIG. 20C). At this time, an area L02 (hereinafter referred to as “second print label area”) which becomes a print label (hereinafter referred to as “second print label”) created in the next order of the first print label is also referred to as the first print label. It is conveyed so as to follow the area L01. In addition, an area L03 (hereinafter referred to as “third print label area”) which becomes a print label (hereinafter referred to as “third print label”) created in the next order of the second print label is also the second print label area. It is conveyed so as to follow L02 (see FIG. 20D described later).

  When the object sensor 60 detects the design object area Q formed on the leading end side of the third print label area L03 subsequent to the second print label area L02 by the above dimension setting, the preceding first The formation has been completed up to the rear end of the print object 65 (in this example, the text character “ABCDEFGHI”) in the one print label region L01, and the conveyance is stopped at the detection timing (see FIG. 20D). In this example, the object region Q is provided with a frame line that surrounds the outer edge so that the object sensor Q can reliably detect the object region Q (the design object 64 other than the frame line itself is illustrated). Omitted). In this example, the conveyance is stopped when the object sensor 60 detects a downstream (front end side) portion of the frame line of the object area Q in the conveyance direction. However, the present invention is not limited to this. The conveyance may be stopped when the upstream side (rear end side) portion of the frame line in the conveyance direction is detected.

  Thereafter, in this transport stop state, the cutting mechanism 615 performs cutting at the cutting line CL at the downstream end portion (rear end portion) in the transport direction of the print object 65 in the first print label region L01, and the print label L ( A first print label L1) is generated (see FIG. 20 (e)). Thereafter, the next second print label L2 (not shown) is created by forming the print object 65 in the second print label area L02, and further, the next second print label 65 is formed by forming the print object 65 in the third print label area L03. In the case of a three-print label L3 (not shown), the process returns to the state of FIG.

  The first printed label L1 corresponds to the first printed matter described in each claim, the second printed label L2 corresponds to the second printed matter, and the third printed label L3 corresponds to the third printed matter.

  FIG. 21 shows a control procedure executed by the control unit 530 of the present modified example in order to realize the above conveyance and cutting mode. In the flow shown in FIG. 21, Step S10, Step S15, Step S55 ′, and Step S60 ′ of the flow of FIG. 15 are omitted, and Step S65 is newly provided after Step S50.

  That is, after the tape conveyance is started in step S5 similar to FIG. 15, the process proceeds to step S20 ′, and the controller 530 determines whether the print-receiving tape 101 has been conveyed to the print start position by an appropriate method. Determine whether. Subsequent steps S25 to S50 are the same as those in FIG. When the tape transport is stopped as described above in step S50, the process proceeds to newly provided step S65.

  In step S65, the control unit 530 outputs a control signal to a drive circuit (not shown) that controls the solenoid that drives the movable blade of the cutting mechanism, and the movable blade is driven by the solenoid to print the label tape that has been printed. The cutting line CL with respect to 80 is formed. Thereafter, this flow is terminated. Each procedure in the flow shown in FIG. 21 functions as a control unit described in each claim.

  Also in this modified example, the print object 65 does not visually overlap the design object 64 in the design object area Q as in the above embodiment, and the convenience for the user can be improved. Further, as described above, the label object L01, L02, L03,... Is placed in advance so that the design object area Q is positioned between the cutting mechanism 615 and the thermal head 16 when the print-receiving tape 101 is stopped. The arrangement of the design object area Q on the printing tape 101 is set. That is, the design object area Q is inevitably disposed in a portion that cannot be printed because it is a non-printing area, so that each print label L1, L2, L3,. It is possible to prevent an unnecessary blank area from being generated and to use the area as a design object area Q in which a design object 64 such as a logo, a mark, or an animation character is arranged.

(4) Others In the above, printing was performed by transferring the ink of the ink ribbon 55 to the image receiving layer 101a provided on the print-receiving tape 101, but the present invention is not limited to this. The present invention is applied to a case where a print-receiving tape (so-called heat-sensitive tape) formed of a heat-sensitive material that develops color when the image receiving layer reaches a predetermined temperature and the design object 64 is formed in advance is used. The print object 65 may not be visually overlapped. Furthermore, in a method in which printing is performed on a base tape and another print-receiving tape, and these are bonded together (a type in which bonding is performed), the design object 64 is preliminarily printed on the print-receiving tape (or base tape). ), The present invention may be applied so that the design object 64 and the print object 65 do not visually overlap.

  In addition, in the above, the arrow shown in FIG. 4 shows an example of the signal flow, and does not limit the signal flow direction.

  In addition, the flowcharts shown in FIGS. 12, 15, and 21 do not limit the present invention to the procedures shown in the above-described flow. Changes may be made.

  In addition to those already described above, the methods according to the above-described embodiments and modifications may be used in appropriate combination.

  In addition, although not illustrated one by one, the present invention is implemented with various modifications within a range not departing from the gist thereof.

1 Print label production device (printing device)
16 Thermal head (printing means)
60 Object sensor (detection means)
80 Printed label tape 101 Printed tape 182 Platen roller (conveying means)
192 discharge roller 530 control unit (control means)

Claims (6)

A cartridge holder in which a tape cartridge capable of supplying a print-receiving tape having a design object area in which a design object is formed in advance and a non-design object area in which the design object is not formed is removable;
Transport means for transporting the print-receiving tape supplied from the tape cartridge mounted on the cartridge holder;
Printing means for forming a desired print object corresponding to print data on the print-receiving tape conveyed by the conveying means;
A detection unit that is provided upstream of the printing unit in the conveyance direction of the conveyance unit and detects the design object region conveyed by the conveyance unit;
Control means for controlling the conveying means and the printing means so as to form the print object in the non-design object area without forming the print object in the design object area based on the detection result of the detection means. When,
Provided on the downstream side of the printing unit along the conveyance path of the print-receiving tape by the conveyance unit, and cutting the print-receiving tape based on the control of the control unit, so that the cut portion is upstream in the conveyance direction. A first printed material, a second printed material following the first printed material, and a third printed material following the second printed material, each having an end portion and one design object region at the downstream end in the transport direction; Cutting means capable of sequentially generating
Have
The control means includes
When the design object area included in the area to be the third printed product of the print-receiving tape is detected by the detection unit, the transport of the print-receiving tape is stopped, and the transport direction of the first print product Controlling the conveying means and the cutting means so as to cut the print-receiving tape at the upstream end portion;
The printing tape is
When the design object area included in the area to be the third printed matter of the print-receiving tape is detected by the detection means and the conveyance of the print-receiving tape is stopped, the cutting means of the print-receiving tape is cut by the cutting means. A printing apparatus, wherein the design object area included in the area to be the second printed matter is positioned between a part and a part facing the printing unit. The printing apparatus according to claim 1.
The control means includes
When the design object area is detected by the detection means at a position in the transport direction of the print target tape that is the formation position of the print object based on the print data, the transport direction of the design object area is detected by the detection means. A printing apparatus comprising: a conveyance direction shift unit that drives and controls the printing unit so that the printing object is formed in a non-design object region that is detected to be adjacent to the upstream side. The printing apparatus according to claim 2, wherein
The transport direction shifting means includes
When the design object area is detected by the detection means at a position in the transport direction of the print target tape that is the formation start position of the print object, the detection means is adjacent to the upstream side of the design object area in the transport direction. A printing apparatus that drives and controls the printing unit so that the formation of the printing object is started from a non-design object area that is detected to be performed. The printing apparatus according to claim 2 or 3,
The transport direction shifting means includes
The design object area is detected by the detection means at a position in the transport direction of the print-receiving tape that is in the process of forming the print object after the start of formation of the print object in the non-design object area detected by the detection means. In this case, the formation of the print object is interrupted up to the upstream end in the transport direction of the non-design object area, and the new non-design object area adjacent to the upstream in the transport direction of the design object area A printing apparatus that drives and controls the printing unit so as to resume the formation of a print object. The printing apparatus according to claim 2, wherein
Before the start of formation of the print object by the printing means, the design object area, the non-design object area adjacent to the upstream side of the design object area in the transport direction, and the upstream side of the non-design object area in the transport direction When another adjacent design object area is detected by the detection means,
The transporting direction shift unit drives and controls the printing unit so that a range from a formation start position to a formation end position of the print object based on the print data is within the non-design object area. . The printing apparatus according to claim 1.
The control means includes
The detection means detects the design object area at a position in the transport direction of the print-receiving tape that is the formation position of the print object based on the print data, and one of the design object areas in the width direction of the print-receiving tape. When the non-design object area is detected adjacent to the side, a width direction shift unit that drives and controls the print unit to form the print object in the non-design object area is provided. Printing device to do.

Images