JP2016104554A - Print device and sheet winding method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a print device, simply structured, which has a sheet winding mechanism.SOLUTION: The print device comprises a print portion which performs printing on a sheet, a drive portion which imparts rotation force to a rotatably held roll member and a pressing portion which imparts pressing force to an outer peripheral face of a roll sheet wound around the roll member, where the pressing portion varies the pressing force in a sequence in which the drive portion imparts the rotation force to the roll member so as to wind up the sheet passing through the print portion.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a printing apparatus having a sheet winding function for winding a sheet-like print medium (hereinafter also simply referred to as a sheet) into a roll sheet.

  2. Description of the Related Art Conventionally, there has been known a printing apparatus capable of winding a printed sheet into a roll sheet while continuing a printing operation. Patent Document 1 discloses a printing apparatus that has a plurality of roll sheet holding units, and can use one holding unit for both the supply of a sheet to the printing unit and the winding of the sheet from the printing unit. doing.

JP 2013-116561 A

  However, in the configuration of Patent Document 1, when the holding unit is used for winding, the user manually holds the sheet in order to apply tension to the sheet when fixing the leading end of the sheet to the roll member for winding the sheet. It may be a burden that needs to be held down. In addition, when the sheet has been wound up, it may be necessary for the user to manually hold the rear end of the sheet in order to prevent unwinding.

  The present invention has been made in view of the above problems, and an object thereof is to provide a printing apparatus and a sheet winding method having a sheet winding function in which a user load during sheet winding is reduced.

  In order to solve the above problems, a printing apparatus of the present invention includes a printing unit that prints on a sheet, a driving unit that applies a rotational force to a roll member that is rotatably held, and a roll sheet that is wound around the roll member. A pressing unit that applies a pressing force to the outer peripheral surface of the sheet, and a driving unit applies a rotational force to the roll member, and the pressing unit changes the pressing force in a sequence of winding the sheet via the printing unit. It is characterized by.

  According to the above configuration, when the leading end of the sheet is fixed to the roll member for winding the sheet, a pressing force can be applied to the sheet by the pressing unit, and tension is applied to the sheet without a user's hand. be able to. Further, when the sheet is wound up to the rear end, a pressing force can be applied to the sheet by the pressing portion, and unwinding can be prevented. Therefore, a printing apparatus having a sheet winding function with reduced user load is realized.

It is a figure which shows the structure of the printing apparatus of the 1st usage pattern which concerns on embodiment. It is a figure which shows the movable structure of the sheet | seat discharge part of the printing apparatus which concerns on embodiment. It is a figure which shows the spool member of the 1st usage pattern, and its attaching part. It is a figure which shows the sheet | seat supply auxiliary mechanism / winding auxiliary mechanism which concerns on embodiment. It is a flow which shows the operation | movement sequence at the time of the sheet | seat supply which concerns on 1st Embodiment. It is a flow which shows the operation | movement sequence at the time of printing of a 1st usage pattern. It is a flow which shows the operation | movement sequence at the time of sheet rewinding. FIG. 3 is a perspective view of the printing apparatus as viewed from the sheet discharge unit side. It is a figure which shows the structure of the printing apparatus of a 2nd usage pattern. It is a figure which shows the spool member of a 2nd usage pattern. It is a front view of the spool member of the 1st usage pattern and the 2nd usage pattern. It is a figure which shows the structure of the printing apparatus of a 2nd usage pattern. It is a flow which shows the operation | movement sequence at the time of paper tube attachment of the 2nd usage pattern. It is a flow which shows the operation | movement sequence at the time of the printing of a 2nd usage pattern. It is an operation | movement sequence flow at the time of the termination | terminus process of a 2nd form. It is a block diagram which shows the example of a control system. It is an operation | movement sequence flow at the time of supply of the 1st usage type which concerns on 2nd Embodiment. It is a rewind operation | movement sequence flow of a 1st usage pattern. It is an operation | movement sequence flow at the time of the paper tube attachment of the 2nd usage pattern. It is an operation | movement sequence flow at the time of printing of a 2nd usage pattern. It is an operation | movement sequence flow at the time of the termination | terminus process of a 2nd usage pattern. It is a figure which shows the structure of the printing apparatus of the 2nd usage type which concerns on 3rd Embodiment. It is an operation | movement sequence flow at the time of the printing of the 2nd usage type which concerns on 4th Embodiment. It is an operation | movement sequence flow at the time of the drive motor OFF of the 2nd usage type which concerns on 5th Embodiment.

[First Embodiment]
The present invention can be applied to various types of image forming apparatuses such as printing apparatuses, copying machines, and facsimiles. An embodiment of the present invention will be described with reference to the drawings, using an inkjet printing apparatus (hereinafter also simply referred to as a printing apparatus) as an image forming apparatus to which the present invention is applicable.

(Printing device)
The printing apparatus shown in FIG. 1 includes two conveyance units 70 arranged in two upper and lower stages, a sheet conveyance unit 300, a print unit 400, and a sheet discharge unit 500. A sheet 1 is used as a print medium, and is attached to the transport unit 70 in a form in which a long continuous sheet is wound in a roll shape. Hereinafter, in the present specification, a form in which a continuous sheet is wound in a roll shape is also referred to as a roll sheet 1.

  The conveyance unit 70 functions as a supply unit that pulls out and supplies the sheet 1 from the roll-shaped portion of the attached roll sheet 1 and a winding unit that winds the sheet 1 printed by the printing unit 400 into a roll. These functions can be switched.

  Hereinafter, in the present specification, the usage pattern when both the upper and lower transport units 70 are used as the supply unit is referred to as a first usage pattern. In addition, a usage pattern when one of the upper and lower transport units 70 is used as a supply unit and the other is used as a winding unit is referred to as a second usage pattern.

(First usage pattern)
First, a usage pattern (first usage pattern) when both the upper and lower transport units 70 are used as supply units will be described.

  In FIG. 1, a spool member (roll member) 2 is inserted into a paper tube of the roll sheet 1 and is pivotally supported by a holding unit of the transport unit 70. The spool member 2 pivotally supported by the holding unit of the transport unit 70 is rotated in both forward and reverse directions by being applied with a rotational force by a roll drive motor (drive unit). A plurality of auxiliary mechanisms 200 are provided in the sheet width direction, and have rollers 6 and 7 arranged in the sheet supply direction, respectively, and function as a sheet supply auxiliary mechanism when the transport unit 70 is used as a supply unit. . The conveyance guide 8 guides the sheet 1 supplied from the conveyance unit 70 to the printing unit 400 while guiding the front and back of the sheet 1.

  The transport roller 10 can be rotated in both forward and reverse directions by a transport roller driving motor. The conveyance pinch roller 11 can be driven to rotate with respect to the rotation of the conveyance roller 10, and a conveyance pinch roller separation motor (not shown) switches between a separated state and a contact state with respect to the conveyance roller 10, and The nip pressure (pressing force) in the contact state can be changed.

  The sheet leading edge detection sensors 12 and 301 detect the leading edge of the sheet 1 supplied from the transport unit 70. The detection of the leading edge of the sheet 1 serves as a trigger for rotation control of the above-described roll drive motor, transport roller drive motor, and transport pinch roller separation motor, and is used for detection of a paper jam (jam). The platen 13 sucks the back surface of the sheet 1 by the negative pressure generated by the suction fan 14 so that the print head 15 can print with high accuracy.

  The sheet discharge unit 500 cuts the sheet 1 with the cutter 16 at the end of printing, and stores the cut printed sheet 1 in the basket 62.

  The paper discharge guide 61 supports and guides the back side of the printed sheet 1. The paper discharge guide 61 is rotatable about a rotation center 61a. When the roll sheet 1 is attached to the upper conveyance unit 70, the paper discharge guide 61 is rotated in the clockwise direction around the rotation center 61a from the state shown in FIG. It is possible to open the space and to attach the roll sheet 1 therefrom.

  The guide member 68 is a movable guide member that extends downward from the front end of the paper discharge guide 61 and is attached to the paper discharge guide 61 so as to be rotatable about a fulcrum 68a. The movable guide member 68 can be stored in the paper discharge guide 61 by rotating counterclockwise around the fulcrum 68a from the state shown in FIG. A position detection sensor 69 for detecting that the movable guide member 68 is stored in the paper discharge guide 61 is provided in the paper discharge guide 61.

  The basket unit 62 includes rods 63a to 63d as structures (framework), and a bag-like cloth 64 that stores the discharged sheet 1. Further, the basket unit 62 can rotate around the rotation center 65. When the roll sheet 1 is attached to the lower conveyance unit 70, the basket unit 62 is rotated counterclockwise around the rotation center 65 from the state shown in FIG. It makes it possible to open the space and mount the roll sheet 1 therefrom.

  The position detection sensor 67 of the basket unit 62 is ON when the basket unit 62 is in the set state shown in FIG. 1, and when the basket unit 62 is not in the state of FIG. 1 after being rotated, for example, FIG. The state shown in 2 (c) is detected as OFF.

  The user inputs the type of roll sheet 1 and the like on the operation panel 20.

(Configuration for setting the roll sheet)
With reference to FIG. 3, the configuration and procedure for setting the roll sheet 1 in the printing apparatus will be described. FIG. 3A is a front view of the spool member 2 in an exploded state, and FIG. 3B is a front view of the spool member 2 in an assembled state. FIG. 3C is a schematic cross-sectional view of the attachment portion of the roll sheet 1 on the printing apparatus main body side.

  3A, the spool member 2 includes a spool shaft 21, a friction member 22, a reference side spool flange 23, a non-reference side spool flange 24, a spool gear 25, and a supply flange attachment 26.

  The supply flange attachment 26 is detachably attached to the reference side spool flange 23 and the non-reference side spool flange 24 by a hook having a spring property. In the first usage pattern in which the transport unit 70 continues to be used as the supply unit, it is not necessary to remove the supply flange attachment 26 from the reference side spool flange 23 and the non-reference side spool flange 24, and these can be handled integrally. . As will be described later, when the transport unit 70 is used as a winding unit in the second usage pattern, it is necessary to remove the supply flange attachment 26.

  The non-reference side spool flange 24 and the supply flange attachment 26 fitted to the spool shaft 21 are integrally removed, and the spool shaft 21 is inserted into the paper tube of the roll sheet 1. At this time, since there is a sufficient gap between the inner diameter of the paper tube of the roll sheet 1 and the outer diameter of the spool shaft 21, the user can fit the roll sheet 1 with a slight force. When the end of the roll sheet 1 comes into contact with the supply flange attachment 26 on the reference side spool flange 23 side, the friction member 22 provided on the inner side in the usage posture of the reference side spool flange 23 is a paper tube of the roll sheet 1. Touch the inner surface.

  The removed non-reference side spool flange 24 and the supply flange attachment 26 are integrally passed through the spool shaft 21, and the friction member 22 provided on the inner surface side in the use posture of the non-reference side spool flange 24 is used as the roll sheet 1. Contact the inner surface of the paper tube. This locks the roll sheet 1 to prevent relative movement of the paper tube with respect to the spool member. As a result, the state shown in FIG. 3B is obtained, and the spool member 2 on which the roll sheet 1 is mounted is set in the printing apparatus main body. The reflective sensor 28 is provided in the printing apparatus main body and determines whether the supply flange attachment 26 is attached or not attached.

  In FIG. 3C, the spool holders 31 are provided on the reference side and the non-reference side of the printing apparatus main body, and have a U-shaped cross-sectional shape. The spool member 2 can be fitted and taken out from the U-shaped opening side of the spool holder 31, and the U-shaped curved portion has a diameter that fits with the spool shaft 21. A spool driving unit 30 on the main body side of the printing apparatus is connected to a spool gear 25 provided to rotate the spool member 2, and the drive is transmitted. The rotation operation of the spool member 2 enables the roll sheet 1 to be supplied or taken up. With the spool presence / absence detection sensor 32, the printing apparatus can detect the presence / absence of the spool member 2.

(Auxiliary mechanism)
With reference to the schematic diagram shown in FIG. 4, the detailed structure of the auxiliary mechanism 200 according to the present embodiment will be described. 4A shows a cross section of the auxiliary mechanism 200 taken along the sheet feeding direction of the printing apparatus, and FIG. 4B shows a side surface of the auxiliary mechanism 200 viewed from the downstream side in the sheet feeding direction.

  The rotation shaft 3 is rotatably engaged with the printing apparatus main body and is a rotation shaft of the auxiliary mechanism 200 as a whole. The auxiliary mechanism 200 rotates about the rotation shaft 3. The rotating shaft 3 is rotatably engaged with the portion 4a of the arm portion 4, and both ends of the rotating shaft 3 are constrained in the thrust direction by ring members (not shown). The arm portion 4 is slidably engaged with the shaft member 41 in the portion 4b, and is positioned by urging the rotating cam 42 by its own weight of the auxiliary mechanism 200. The rotating cam 42 is rotatably engaged with the shaft member 43, is in contact with the surface of the arm member 4, and is rotated by driving from a driving mechanism (pressure driving motor) to change the position of the arm member 4.

  The swing member 5 is rotatably engaged with the shaft member 41 at the engaging portion 5a, and both ends of the shaft member 41 are constrained in the thrust direction by ring members (not shown). On the upper part of the swing member 5, there are a driven rotating roller 6 and a sheet pressing roller 7. The rollers 6 and 7 are pressed against the roll sheet 1. The roll outer diameter detection sensor 5 c is disposed on the swing member 5 at the center between the driven rotation roller 6 and the sheet pressing roller 7 and detects the distance from the roll sheet 1. The driven rotating roller 6 and the sheet pressing roller 7 are rotatably engaged with the shaft member 47, and both ends are constrained in the thrust direction by ring members (not shown).

  The shaft member 47 is fitted into the upper hole of the swing member 5 and has a protrusion 47a. The compression spring 46 is fitted into and restrained by the protrusion 47a of the shaft member 47 and the protrusion 5b of the swinging member 5, and urges the rotation shaft 47 upward. The two rollers 6 and 7 are arranged at an equal distance with respect to the center position of the swing member 5, and swing and rotate about the shaft member 41, thereby equalizing each pressing force on the roll sheet 1. By providing a plurality of rollers in the outer peripheral direction of the roll sheet 1, it is possible to effectively press the bulge of the diameter of the roll-shaped portion of the roll sheet 1 and the loosening (winding loosening). In a state where the rollers 6 and 7 are pressed against the outer peripheral surface of the roll sheet 1, the roll sheet 1 is rotated via the spool member 2, whereby the sheet 1 is conveyed by the frictional force of the roll sheet 1 itself. The auxiliary mechanism 200 pressurizes the sheet from below the horizontal plane passing through the center of the roll sheet 1, that is, from below the roll sheet 1 in the vertical direction.

  According to the configuration of the auxiliary mechanism 200 described above, the deflection of the roll sheet 1 supported at both ends by the spool member 2 can be corrected, and higher conveyance accuracy during sheet supply can be obtained.

  The operation region of the auxiliary mechanism 200 serving as a pressurizing mechanism for the roll sheet 1 is downward in the vertical direction with respect to the roll sheet 1. Therefore, it is possible to secure a sheet setting space when setting a heavy roll sheet, and the auxiliary mechanism 200 does not hinder the setting operation.

  In addition, while the conveyance path of the sheet conveyance unit 300 has a U-turn shape from below, it is possible to resist the curl of the roll sheet 1 by adopting a method in which the conveyance unit 70 pressurizes the roll sheet 1 from below. The sheet 1 can be supplied without any problems. Thereby, the conveyance resistance at the time of supply can be minimized, and scratches on the sheet surface can be prevented.

(Sheet discharge part)
A detailed configuration of the sheet discharge unit 500 will be described with reference to a schematic cross-sectional view of the printing apparatus illustrated in FIGS. 2A to 2C and a perspective view of the printing apparatus illustrated in FIG.

  FIGS. 2A and 8 show a state where the basket unit 62 is set to be usable in the sheet discharge unit 500. FIG. 2B shows a state where the movable guide member 68 is accommodated in the paper discharge guide 61 and the basket portion of the basket unit 62 is closed. FIG. 2C shows a state in which the basket unit 62 is stored in the lower part of the lower conveyance unit 70.

  In this example, the paper discharge guide 61 is a molded part in which a guide is formed in the entire sheet width direction. The movable guide member 68 is formed by forming and bending a wire, and has two positions: a position in which the wire is suspended by its own weight in a vertical direction, and a position in which the movable guide member 68 is stored in the paper discharge guide 61. Further, the paper discharge guide 61 is provided with a position detection sensor 69 for detecting that the movable guide member 68 is stored. The position detection sensor 69 is turned off when the movable guide member 68 is suspended by its own weight as shown in FIG. 2 (a), and is housed as shown in FIGS. 2 (b) and 2 (c). When it is in the state, it is detected as ON.

  The basket unit 62 includes rods 63a to 63d as structures (framework) and a bag-like cloth 64 that stores discharged sheets.

  The thrust direction (axial direction) of the rods 63a and 63b is the same as the sheet width direction. One end of each of the two rods 63c is disposed at each end of the rod 63a. In addition, one end of each of the two rods 63d is disposed at each end of the rod 63b. The other end of the rod 63d is connected to the rod 63c. The other end of the rod 63c is attached so as to be rotatable with respect to the rotation center 65 provided in the stand, and the rod 63c can be rotated to a position that is substantially horizontal as shown in FIG. Further, the rod 63c is movable in the thrust direction from that state, and can be stored in the lower part of the lower conveyance unit 70 as shown in FIG. 2 (c).

  The position detection sensor 67 for detecting the state of the basket unit 62 is ON when the basket unit 62 is set as shown in FIG. 2 (a), as shown in FIG. 2 (b) and FIG. 2 (c). If it is not set as shown, it is detected as OFF.

  In the set state shown in FIG. 2A, the bag-like cloth 64 includes a front-side portion 64a, a floor-side portion 64b, and a portion 64c that becomes the back side of the discharged sheet. Including. The discharged sheet is received mainly by the portions 64a and 64b, and the printed surface is prevented from being soiled by being grounded to the floor. The portion 64c has a function of guiding the back side of the sheet being printed or discharged, and the discharged sheet is conveyed by guiding the sheet with continuity from the discharge guide 61 and the movable guide member 68. The unit 70 is prevented from entering. If the discharged sheet enters the conveyance unit 70 side, a jam (paper jam) may occur. For this reason, the operation panel 20 warns the user if any of the position detection sensor 67 for detecting the state of the basket unit 62 or the position detection sensor 69 for detecting the state of the movable guide member 68 is OFF. Prompt. This is the case of the first usage pattern in which the sheet is discharged to the basket using the transport unit 70 as a supply unit. The case of the second usage pattern in which the transport unit 70 is used as a winding unit will be described later.

(Control system)
A control system according to the present embodiment will be described with reference to FIG. FIG. 16 is a block diagram showing a configuration of a control system in the present embodiment. The CPU 201 controls the transport unit 70 and the printing unit 400 according to the control program stored in the ROM 204. Application selection information indicating whether the transport unit 70 is used for supply or winding is input from the operation panel 20 via the input interface 202 to the CPU 201. The input usage selection information is written in the RAM 203 and read from the RAM 203.

  The CPU 201 receives the detection results of the spool presence / absence detection sensor 32 and the sheet leading edge detection sensors 12 and 301, and ON / OFF signals from the position detection sensors 67 and 69 of the basket unit 62 and the movable guide member 68. Further, the CPU 201 receives a trigger signal accompanied by a user operation from the operation panel 20. Based on the received detection result and signal, the CPU 201 executes processing related to each operation sequence described later in accordance with a predetermined control program stored in the ROM 204.

  Specifically, the CPU 201 sends a rotation control signal to the pressure drive motor 33 of the upper and lower transport units 70 to drive the pressure drive motor 33. The auxiliary mechanism 200 rotates with the operation of the pressure drive motor 33. A signal from the roll outer diameter detection sensor 5c is received, and the driving and stopping of the pressure driving motor 33 are controlled.

  The CPU 201 further outputs a rotation control signal to the roll drive motor 34 and the transport roller drive motor 35 of the upper and lower transport units 70. The CPU 201 receives signals from the drive amount detection encoders 36 and 37 of each motor in accordance with the operations of the roll drive motor 34 and the transport roller drive motor 35, and performs rotation control of the motors 34 and 35. Note that the control programs for the motors arranged in the upper and lower transport units 70 are different depending on whether they are used for supply or used for winding, which will be described later. One of the controls is performed by sequentially referring to the selection information.

(Operation sequence during sheet supply)
With reference to FIG. 5, the flow of the operation sequence at the time of sheet supply according to the first embodiment will be described. In the following description, the symbols in parentheses are the numbers of the steps in the flow shown in the figure. Hereinafter, the rotation in the sheet supply direction is defined as normal rotation, and the rotation in the direction opposite to the normal rotation is defined as reverse rotation.

  The spool member 2 is inserted into the paper tube of the roll sheet 1 and set in the transport unit 70 (S1). The spool presence / absence detection sensor 32 installed in the spool holder 31 detects the presence of the spool member 2 (S2). Along with the detection that the spool member 2 is present, an announcement to that effect is made on the operation panel. When the user inserts the leading end 9 of the sheet 1 into the conveyance guide 8, the sheet leading end detection sensor 301 detects the leading end 9 of the sheet 1 (S3). Next, the auxiliary mechanism 200 is rotated by the pressure drive motor 33 to press the roll sheet 1 (S4).

  Here, when the pressure driving motor 33 is driven in the forward direction, the auxiliary mechanism 200 operates in a direction approaching the roll sheet 1, and when the pressure driving motor 33 is driven in the reverse direction, the auxiliary mechanism 200 is separated from the roll sheet 1. To work. The roll outer diameter detection sensor 5c detects the distance between the surface of the roll sheet 1 and the auxiliary mechanism 200 as a pressure mechanism, and the pressure drive motor 33 stops at an appropriate pressing position. By controlling the direction and amount of driving of the pressure drive motor 33, the pressing force of the auxiliary mechanism 200 on the roll sheet 1 can be changed. That is, the auxiliary mechanism 200 can be brought into contact with or separated from the tall sheet 1, and the pressing force at the time of contact can be set to various magnitudes. These pressing states can be arbitrarily changed during the sequence according to the scene.

  Thereafter, the printing apparatus performs a sheet conveying operation. Specifically, the roll drive motor 34 and the conveyance roller drive motor 35 are driven in the forward rotation direction to start sheet conveyance (S5). The sheet leading edge detection sensor 12 detects the leading edge 9 of the sheet 1 pulled out from the roll-shaped portion of the roll sheet 1 (S6). The sheet 1 is fed from there by a predetermined amount and passed to the end of the conveying roller 10 (S7). Next, the auxiliary mechanism 200 is separated from the roll sheet 1, and at the same time, the nip pressure of the transport pinch roller 11 with respect to the transport roller 10 is set to a weak nip pressure that is weaker than the normal nip pressure that is the nip pressure used during printing (S8). . Thereafter, the back feed and the feed of the sheet 1 are repeated to correct the skew of the sheet 1 (S9).

  In this specification, feed refers to conveyance in the sheet conveyance direction (corresponding to the supply direction) during execution of printing on a sheet, and back feed refers to the sheet conveyance direction during execution of printing on a sheet. The conveyance in the reverse direction (corresponding to the rewinding direction) shall be said.

  Next, the position of the leading end 9 of the sheet 1 is read by a sensor (not shown) while back feeding the sheet 1 to detect the skew feeding amount (S10), so that the leading end 9 of the sheet 1 comes to a standby position before starting printing. The sheet 1 is stopped (S11). Next, the nip pressure of the conveyance pinch roller 11 with respect to the conveyance roller 10 is returned to the normal nip pressure (S12), and the supply operation is terminated (S13).

(Operation sequence during printing in the first usage pattern)
Next, with reference to FIG. 6, the flow of the operation sequence during printing in the first usage pattern according to the first embodiment will be described. In the following description, the symbols in parentheses are the numbers of the steps in the flow shown in the figure. Since the sequence starts from the above-described operation end state (S13 in FIG. 5) at the time of sheet supply, the auxiliary mechanism 200 is separated from the roll sheet 1 and the nip pressure of the conveyance pinch roller 11 with respect to the conveyance roller 10 is reached. Is usually the nip pressure.

  When print data from a personal computer or the like is received (S14), the conveyance roller drive motor 35 starts to be driven in the forward rotation direction and sheet conveyance is started (S15). The leading edge 9 of the sheet at the standby position is fed to the position immediately below the print head 15 (S16). Thereafter, the print head 15 discharges ink while scanning in the width direction of the sheet, and printing is performed (S17).

  Specifically, after the print head 15 scans in the forward direction and prints one line, the conveyance roller 10 feeds the sheet 1 by a predetermined amount, and then the print head 15 scans in the backward direction to scan one line. Print minutes. In this manner, the reciprocating operation of the print head 15 and the feeding operation of the conveying roller 10 are repeated, and printing is performed while the sheet 1 is conveyed downstream. At this time, the roll drive motor 34 (drive unit) is controlled to drive in the reverse rotation direction in accordance with the feed operation by the transport roller 10. In the control for the roll drive motor 34, the sheet 1 is pulled by the conveying roller 10 with a force greater than the drive force in order to suppress the drive force with current limitation. The reason why such control is performed is that an appropriate back tension is applied to the roll sheet 1 to realize stable conveyance without occurrence of slack.

  When printing is completed (S18), the conveyance roller 10 feeds the sheet 1 until the trailing end of the printed portion reaches the cutting position of the cutter 16 (S19), and a cutter driving motor (not shown) operates the cutter 16. Cutting is performed (S20). The cut printed matter is stored in the basket unit 62. The sheet 1 left on the printing apparatus side is back-feeded by a predetermined amount by the conveying roller 10 (S21), and the leading edge 9 of the new sheet 1 generated by the cutting is returned to the print start standby position, and enters a standby state ( S22).

(Operation sequence when rewinding the sheet)
With reference to FIG. 7, the example of the flow of the operation | movement sequence which rewinds the sheet | seat 1 is demonstrated. In the following description, the symbols in parentheses are the numbers of the steps in the flow shown in the figure. In this specification, the rewinding means that the leading edge 9 of the sheet 1 is moved from a state where the leading edge 9 of the sheet 1 is in the vicinity of the conveying roller 10 (for example, the standby state described in S13 of FIG. 5 or S22 of FIG. 6). The operation of backfeeding until the vicinity of the supply port of the transport unit 70 is assumed.

  First, the auxiliary mechanism 200 is pressed against the roll sheet 1 (S23). This is for preventing the roll sheet 1 from being loosened in the transport unit 70 as a supply unit. In this state, the roll drive motor 34 and the conveyance roller drive motor 35 are simultaneously driven in the reverse rotation direction (S24), and the sheet 1 is fed back. After a while, since the leading end 9 of the sheet 1 passes the detection position of the sheet leading end detection sensor 12 (S25), the driving of the conveying roller drive motor 35 is stopped (S26). When the roll drive motor 34 continues to be driven and the sheet 1 is further back-fed, the leading end 9 of the sheet 1 now passes the detection position of the sheet detection sensor 301 (S27). Thereafter, the roll drive motor 34 is stopped, and the rewinding operation is finished (S28).

  When the sheet 1 is wound up to the end for the purpose of replacing the roll sheet, the roll drive motor continues to move for a while after passing through the detection position of the sheet detection sensor 301 so that the leading end 9 of the sheet 1 is conveyed to the conveyance guide 8. Back feed the sheet 1 until it comes out of the area.

  On the other hand, when the roll sheet used for printing is switched between the upper stage and the lower stage, the sheet 1 may not be wound up to the end. For example, immediately after the leading edge 9 of the sheet 1 passes the detection position of the sheet detection sensor 301, the roll drive motor 34 is stopped immediately and the leading edge 9 of the sheet 1 is made to stand by in the vicinity of the sheet detection sensor 301. At that time, the auxiliary mechanism 200 maintains a pressed state against the roll sheet 1 to prevent the sheet 1 from falling off the conveyance guide 8 by its own weight.

  The pressing force of the auxiliary mechanism 200 for preventing the roll sheet 1 from unwinding, preventing the sheet 1 from dropping from the conveyance guide 8 and for supplying the sheet may be the same or different. For example, by setting the pressing force for preventing unraveling and slipping out to be greater than the pressing force at the time of sheet supply, it is possible to remove the sheet without affecting the accuracy of sheet conveyance at the time of feeding and damage to the roll sheet surface. The prevention effect can be enhanced.

  The above is the description of the first usage pattern in which both the upper and lower transport units 70 are used as supply units. Next, the case of the second usage pattern in which any one of the transport units 70 is used as a winding unit will be described.

(Second usage pattern)
With reference to the drawings, a case where the upper transport unit 70 is used as a supply unit and the lower transport unit 70 is used as a winding unit (second usage pattern) will be described. In addition, description is abbreviate | omitted about the same structure and operation | movement as the 1st usage pattern mentioned above.

  In FIG. 9, when the lower conveyance unit 70 is used as a winding unit, a paper tube 17 for winding a sheet is attached to the spool member 2, and the leading end 9 of the sheet 1 is fixed to the paper tube 17 with a tape or the like. Then, the conveyed sheet 1 is taken up. Therefore, since the movable guide member 68 and the basket unit 62 are in the state as shown in FIG. 2A, they are used in the stored positions. That is, in the second usage pattern, the position detection sensor 69 of the movable guide member 68 is ON, and the position detection sensor 67 of the basket unit 62 is OFF.

  Here, when the transport unit 70 is used as a supply unit, the auxiliary mechanism 200 functions as a sheet supply auxiliary mechanism that assists in sheet supply. On the other hand, when the transport unit 70 is used as a winding unit, the sheet is pressed or separated from the surface of the sheet 1 to be wound when the sheet is set on the paper tube, at the time of printing, or at the time of termination processing. It functions as a sheet winding assist mechanism that assists in winding. In the present specification, the auxiliary mechanism 200 is also referred to as a supply auxiliary mechanism 200 or a winding auxiliary mechanism 200 depending on the use of the transport unit 70, that is, depending on the usage pattern.

(Configuration for setting paper tube)
With reference to FIG. 10 and FIG. 11, a configuration for setting the sheet winding paper tube 17 in the printing apparatus will be described.

  FIG. 10A is a front view of the spool member 2 in an exploded state, and FIG. 10B is a front view of the spool member 2 in an assembled state. The configuration of the spool member 2 at the time of supply described with reference to FIG. 3 is that the configuration of the spool member 2 for winding does not have the supply flange attachment 26. That is, as described above, the supply flange attachment 26 can be detached from the reference side spool flange 23 and the non-reference side spool flange 24, and therefore is removed for winding purposes.

  FIG. 11A and FIG. 11B compare the spool members 2 at the time of supply and at the time of winding up and down.

  As shown in FIG. 11 (a), a supply flange attachment 26 is attached to the supply flange. The end surface of the supply flange attachment 26 is a flat surface, and the end of the roll sheet 1 to be set is abutted to determine the position in the width direction. The non-reference side spool flange 24 side is not necessarily a flat surface, and the supply flange attachment 26 may be removed and used.

  On the other hand, as shown in FIG. 11 (b), the flanges at the time of winding, that is, the end surfaces of the reference side spool flange 23 and the non-reference side spool flange 24 are arranged with a gap wider than the width of the seat 1. And has a tapered shape. Therefore, the skew of the sheet 1 wound around the paper tube 17 can be allowed to some extent. The configuration other than this point is the same as the configuration at the time of supply described with reference to FIG.

(Operation flow when setting paper tube)
With reference to FIG. 12 and FIG. 13, an operation for attaching the leading end 9 of the sheet 1 to the paper tube 17 for winding the sheet will be described. FIG. 12 is a schematic diagram of a printing apparatus according to the second usage pattern, and FIG. 13 is a flow of an operation sequence when a paper tube for winding a sheet is set in the printing apparatus. In the following description, the symbols in parentheses are the numbers of the steps in the flow shown in the figure. The description starts from a standby state in which the sheet 1 is supplied from the upper supply unit 70 along steps S1 to S13 of the flow described with reference to FIG.

  The spool member 2 is inserted into the paper tube 17 and set in the lower conveyance unit 70 (R1). The spool presence / absence detection sensor 32 installed in the spool holder 31 detects the spool member 2 (R2). The pressure drive motor 33 is driven in the reverse direction to separate the winding assist mechanism 200 from the spool member 2 (R3). Thereafter, the printing apparatus performs the conveying operation of the sheet 1 supplied from the roll sheet 1 of the upper conveyance unit 70. The conveyance roller drive motor 35 is driven in the forward rotation direction (R4), and the sheet 1 is fed by a predetermined amount by the conveyance roller 10 and reaches the vicinity of the paper tube 17 attached to the lower conveyance unit 70 (R5). Then, with the user operation, the leading end 9 of the sheet 1 is inserted between the paper tube 17 and the winding assist mechanism 200 spaced from the paper tube 17 (R6).

  Thereafter, when a trigger is generated by the operation of the operation panel 20 by the user, the pressure driving motor 33 of the lower conveyance unit 70 is driven in the forward direction, and the winding assist mechanism 200 moves the leading end 9 of the sheet 1 to the paper tube 17. Press (R7). In this state, the conveyance roller drive motor 35 is driven in the reverse rotation direction, and at the same time, the roll drive motor 34 of the lower conveyance unit 70 is driven in the normal rotation direction (R8).

  That is, at this time, the two motors of the transport roller drive motor 35 and the roll drive motor 34 of the lower transport unit 70 rotate in opposite directions. Since the frictional force generated between the conveyance roller 10 and the sheet 1 is set sufficiently higher than the frictional force generated between the paper tube 17 and the sheet 1, the reverse rotation of the conveyance roller 10 occurs. Then, the sheet 1 is back-fed by a predetermined amount (R9).

  The reason why the lower roll drive motor 34 is driven in the forward rotation direction is to apply tension to the sheet 1 by rotating the paper tube 17 in response to the back feed operation by the conveying roller 10. By back-feeding the sheet 1 in a state where tension is applied, the sheet 1 to be wound around the paper tube 17 is free from bending, and skew is corrected.

  In this state, the leading end 9 of the sheet 1 is fixed to the paper tube 17 with a tape or the like (R10).

  Here, the conventional winding device does not have the winding assist mechanism 200 of the present embodiment. Therefore, when the user fixes the leading end 9 of the sheet 1 to the paper tube 17, it is necessary to take care to apply tension to the sheet by the user's own hand and to be straightened depending on the sense. That is, in this embodiment, it can be said that the winding assist mechanism 200 helps to reduce the inconvenience of the conventional operation flow and reduce the user load.

  Thus, the operation for attaching the leading end 9 of the sheet 1 to the paper tube 17 for winding the sheet (paper tube setting operation) is completed, and a standby state is entered (R11).

(Operation sequence during printing in the second usage pattern)
With reference to FIG. 14, a flow of an operation sequence at the time of printing in the second usage pattern according to the first embodiment, that is, at the time of winding while performing printing will be described. In the following description, the symbols in parentheses are the numbers of the steps in the flow shown in the figure.

  When print data from a personal computer or the like is received (R12), the conveyance roller drive motor 35 and the roll drive motor 34 of the lower conveyance unit 70 are both driven in the forward rotation direction (R13), and the sheet 1 is conveyed. To start. The print start position of the sheet 1 that was in the standby position is fed to just below the print head 15 (R14). Thereafter, the pressure driving motor 33 of the lower transport unit 70 is driven in the reverse direction to separate the winding assist mechanism 200 (R15). Then, printing is performed by discharging ink while the print head 15 scans in the width direction of the sheet (R16).

  Regarding printing, the operation of the print head 15, the operation of the conveyance roller 10, and the back tension applying operation of the roll drive motor 34 of the upper conveyance unit 70 that supplies the sheet 1 are as described in step S <b> 17 in FIG. 6. .

  Regarding winding, the roll drive motor 34 of the lower conveyance unit 70 that winds the sheet 1 via the printing unit operates together with the conveyance roller 10. When the leading edge of the printed sheet 1 is conveyed to the position of the lower conveyance unit 70, the user stops the operation of the lower roll drive motor 34 with a pause button (not shown) or the like. At that time, the printing operation continues without being stopped. With the winding operation stopped, the user fixes the leading end of the sheet 1 to the paper tube with tape or the like (R17), and after the paper tube setting operation is completed, the user performs the winding operation of the lower roll drive motor 34, Restart by pressing the pause button again. At this time, the roll drive motor 34 is controlled so that the current is limited and the sheet 1 is not pulled more than a predetermined torque (tension). This is because if the tension is more than necessary, the conveyance accuracy is affected. By this control, stable conveyance is realized.

  When the printing is completed, when winding is used thereafter, the standby state is maintained as it is (R18).

(Operation sequence of sheet end processing)
With reference to FIG. 15, the flow of the operation sequence of the sheet termination process during winding according to the first embodiment will be described. In the following description, the symbols in parentheses are the numbers of the steps in the flow shown in the figure.

  When a termination trigger is generated with the operation of the operation panel 20 by the user, the transport roller drive motor 35 and the roll drive motor 34 of the lower transport unit 70 are driven in the forward rotation direction (R19). A fixed amount feed is performed (R20). Thereafter, the pressure drive motor 33 of the lower transport unit 70 is driven in the forward direction to press the winding assist mechanism 200 against the surface of the sheet (roll sheet) 1 wound in a roll shape (R21).

  At this time, if the rollers 6 and 7 of the winding assist mechanism 200 are in contact with the printed portion, there is a risk of ink transfer or the like. Therefore, in the feed operation performed in step R20, it is desirable to wind up and convey the sheet 1 until the printed portion comes downstream where it does not contact the rollers 6 and 7. Alternatively, if the printed part is in contact with the rollers 6 and 7, there is also a means of pressing after a sufficient drying time or a means for preventing transfer such as fluorine coating on the surface of the roller. .

  In any case, the sheet 16 is cut by operating the cutter 16 with a cutter driving motor (not shown) in a state where the winding assist mechanism 200 is pressed against the surface of the sheet (roll sheet) 1 wound in a roll shape. (R22). At the time of cutting, the user holds the rear end of the sheet (roll sheet) 1 on the side wound by the conveyance unit 70 as a winding unit by hand, and after cutting, the sheet starts from the roll-shaped portion of the roll sheet. It is normal to prevent the rear end of the camera from falling.

  After that, the rear end portion of the sheet 1 on the take-up unit side is taken up along with operation of the operation panel 20 and buttons by the user (R23). The rear end of the sheet 1 is fixed to the roll-shaped portion of the wound roll sheet 1 with a tape or the like, and the termination process ends (R24).

  As described above, in the first embodiment, the winding assist mechanism 200 presses the surface of the roll sheet 1 after step R21. Therefore, during the operations of steps R22 to R24, the sheet 1 is wound even though there is a slack between the rear end portion of the sheet 1 held by the user and the pressing portion by the winding assist mechanism 200. There is no worry about the roll sheet 1 unwinding.

  There is no conventional winding unit like the winding assist mechanism 200. Therefore, if the roll sheet 1 taken up after cutting is not carefully held so as not to be loosened, the roll sheet 1 taken up may be unwound. When the roll sheet 1 is unwound, the printed surface may be rubbed and scratched when the roll sheet 1 is subsequently tightened. That is, in the first embodiment, it can be said that the winding assist mechanism 200 has improved the inconvenience of operation in the conventional operation sequence, and at the same time, has helped to improve the print quality.

  According to the configuration described above, it is possible to provide a printing apparatus having a sheet winding function with reduced user load.

[Second Embodiment]
In the first embodiment described above, the supply assist mechanism 200 and the winding assist mechanism 200 automatically perform the separation and contact operations. On the other hand, in the second embodiment, the supply assist mechanism 200 and the take-up assist mechanism 200 do not perform the separation operation, and maintain the contact state with the outer periphery of the roll sheet 1 (or the paper tube 17). The flow of the operation sequence of the second embodiment will be described below. The description of the same configuration and operation as those of the first embodiment described above is omitted.

(First usage pattern)
First, a case where the upper and lower transport units 70 are both used as a supply unit in the second embodiment (first usage pattern according to the second embodiment) will be described.

(Operation sequence at the time of sheet supply according to the second embodiment)
FIG. 17 shows an example of a flow of an operation sequence at the time of sheet supply according to the second embodiment. Differences from the flow of the first embodiment shown in FIG. 5 will be described. The steps indicated by the same symbols in both figures have the same contents, and will not be described.

  A series of steps (S1 to S3) of sheet setting by the user in the second embodiment are the same as those in the first embodiment described with reference to FIG.

  In the first embodiment, subsequently, the auxiliary mechanism 200 is rotated by the pressure drive motor 33 to press the roll sheet 1 (S4). In contrast, the second embodiment does not include a step corresponding to step S4. Specifically, the supply assist mechanism 200 and the roll sheet 1 come into contact with each other when the roll sheet 1 is set in the transport unit 70 in step S1, but in the second embodiment, this contact is made in steps after step S1. Maintain state.

  The essence of the present embodiment is that the supply assist mechanism 200 and the roll sheet 1 are not separated in a series of steps. Thereby, unwinding of a roll can be prevented and a user load is reduced. Therefore, in the second embodiment, the pressing force on the roll sheet can be changed by rotating the auxiliary mechanism 200 by the pressure driving motor 33 while maintaining the contact state. It can be carried out.

  A series of steps from the sheet conveyance start (S5) by the roll drive motor 34 and the conveyance roller drive motor 35 to the sheet leading edge detection (S6) and the sheet passing (S7) in the second embodiment are shown in FIG. This is the same as that of the first embodiment described in the above.

  In the first embodiment, after the sheet is passed (S7), the pressing of the roll sheet 1 by the supply assist mechanism 200 is released by separation, and then the nip pressure of the transport pinch roller 11 with respect to the transport roller 10 is used during printing. The nip pressure was weaker than the nip pressure (S8). On the other hand, in the second embodiment, the nip pressure is reduced to a weak nip pressure without being accompanied by the release of pressure due to the separation of the supply assist mechanism 200 from the sheet 1 (S35). That is, as described above, in the second embodiment, the contact state between the supply assist mechanism 200 and the roll sheet 1 is maintained.

  In the second embodiment, from the subsequent skew correction (S9), the skew amount detection (S10), the stop at the standby position (S11), the change of the nip pressure to the normal nip pressure (S12), and the end of the supply operation A series of steps up to (S13) is the same as that of the first embodiment described in FIG.

(Operation sequence during printing in the first usage pattern according to the second embodiment)
The flow of the first embodiment shown in FIG. 6 can be directly applied to the flow of the operation sequence at the time of printing in the first usage pattern according to the second embodiment. Also in the second embodiment, as in the first embodiment, the operation sequence at the time of printing is started from the above-described operation end state at the time of supply (step S13). The nip pressure for the transport roller 10 is a normal nip pressure. On the other hand, unlike the first embodiment, the second embodiment does not include a step of releasing the pressing of the roll sheet 1 by the supply assist mechanism 200, and thus the printing operation is performed in a pressed state.

(Operation sequence at the time of sheet rewinding according to the second embodiment)
FIG. 18 shows a flow of an operation sequence for rewinding the leading end 9 of the sheet 1 according to the second embodiment. Differences from the flow of the first embodiment shown in FIG. 7 will be described. The steps indicated by the same symbols in both figures have the same contents, and will not be described.

  In the first embodiment shown in FIG. 7, when starting the rewinding operation, first, the auxiliary mechanism 200 is pressed against the roll sheet 1 (S23). This is for preventing the roll sheet 1 from being loosened in the transport unit 70 as a supply unit.

  On the other hand, the flow of the second embodiment shown in FIG. 18 does not include a step corresponding to step S23. As described above, in the second embodiment, the printing operation is performed in a state in which the roll sheet 1 is pressed by the supply assist mechanism 200 and is not accompanied by a releasing operation. Therefore, the pressing state is maintained at the start of rewinding. It is because it is leaning. Therefore, also in 2nd Embodiment, the unwinding of the roll sheet 1 in the conveyance unit 70 as a supply unit is prevented in the rewinding operation.

  Subsequent steps (S24 to S28) in the second embodiment are the same as those in the first embodiment described in FIG.

  The above is the description of the first usage pattern of the second embodiment in which both the upper and lower transport units 70 are used as supply units. Next, the case of the second usage pattern in which any one of the transport units 70 is used as a winding unit will be described.

(Second usage pattern)
Subsequently, a case where the upper transport unit 70 is used as a supply unit and the lower transport unit 70 is used as a winding unit in the second embodiment (second usage pattern according to the second embodiment) will be described. In addition, description is abbreviate | omitted about the same structure and operation | movement as the 1st usage form of the above-mentioned 1st Embodiment and 2nd Embodiment.

(Operation flow at the time of paper tube setting in the second usage pattern according to the second embodiment)
FIG. 12 and FIG. 19 are diagrams for explaining an operation when the leading end 9 of the sheet 1 is attached to the sheet winding paper tube 17 in the second usage pattern according to the second embodiment. FIG. 12 is a schematic diagram of a printing apparatus according to the second usage pattern, and FIG. 19 is an operation flow when a paper tube for winding a sheet is set in the printing apparatus. The operation flow at the time of setting the paper tube starts from a standby state in which the sheet 1 is supplied from the upper supply unit 70 along steps S1 to S13 of the operation sequence at the time of sheet supply shown in FIG.

  The difference between the flow of the second embodiment shown in FIG. 19 and the flow of the first embodiment shown in FIG. 13 will be described. The steps indicated by the same symbols in both figures have the same contents, and will not be described.

  A series of steps from the paper tube set (R1) to the spool detection (R2) in the second embodiment is the same as that in the first embodiment described in FIG.

  After detecting that there is a spool (R2), in the first embodiment, the winding assist mechanism 200 is separated from the paper tube 17 (R3). On the other hand, the second embodiment does not include a separation step corresponding to step R3. Therefore, in the second embodiment, the contact state of the winding assist mechanism 200 with the paper tube 17 is maintained.

  In the second embodiment, the subsequent conveyance roller is driven (R4), the sheet is fed by a predetermined amount (R5), and the leading end of the sheet is inserted between the paper tube and the winding assist mechanism (R6). The steps are the same as those in the first embodiment described in FIG.

  Next, in the first embodiment, the winding assist mechanism 200 is pressed against the paper tube 17 (and thus the sheet 1) (R7). In contrast, the second embodiment does not include a separation step corresponding to step R7. This is because in the second embodiment, since the contact state of the winding assist mechanism 200 with the paper tube 17 is maintained, an operation of pressing again is unnecessary.

  In the second embodiment, the drive motors 34 and 25 are driven (R8), the sheet 1 is back-feeded by a predetermined amount (R9), the leading end of the sheet is fixed to the paper tube 17 (R10), and the mounting operation is completed. A series of subsequent steps to enter the standby state (R11) are the same as in the first embodiment.

(Operation sequence during printing in the second usage pattern according to the second embodiment)
FIG. 20 shows an example of a flow of an operation sequence at the time of printing in the second usage pattern according to the second embodiment, that is, when printing is performed while winding. Differences from the flow of the first embodiment shown in FIG. 14 will be described. The steps indicated by the same symbols in both figures have the same contents, and will not be described.

  A series of steps from reception of print data (R12) to driving of drive motors 35 and 34 (R13) and feeding of a predetermined amount of sheet 1 (R14) in the second embodiment are the same as those described in FIG. This is the same as the first embodiment.

  After the sheet is fed by a predetermined amount (R14), in the first embodiment, the winding assist mechanism 200 is separated from the paper tube 17 (and thus the sheet 1) (R15). On the other hand, the second embodiment does not include a separation step corresponding to step R3. Therefore, in the second embodiment, the contact state of the winding assist mechanism 200 with the paper tube 17 (sheet 1) is low. Maintained.

  In the second embodiment, subsequent printing is performed (R16), the leading edge of the sheet is fixed to the paper tube (R17), and the series of steps from the end of printing to the standby state (R17) is shown in FIG. This is the same as that of the first embodiment described in the above.

(Operation sequence of sheet end processing in the second usage pattern according to the second embodiment)
FIG. 21 shows an example of the flow of the operation sequence of the sheet end processing according to the second embodiment. Differences from the flow of the first embodiment shown in FIG. 15 will be described. The steps indicated by the same symbols in both figures have the same contents, and will not be described.

  The difference between the first embodiment and the second embodiment is that before the step (R22) of cutting the sheet 1 by operating the cutter 16 by the cutter driving motor, the winding assist mechanism 200 is moved to the roll sheet 1. Whether or not a step (R21) of pressing is included. The first embodiment shown in FIG. 15 includes a pressing step (R21), whereas the second embodiment shown in FIG. 21 does not include such a step (R21). This is because, in the second embodiment, since the winding assist mechanism 200 is in contact with and pressed against the roll sheet 1 from the time of setting the paper tube 17, the pressing step (R21). This is because it is not necessary to carry out again.

  As described above, in the present embodiment, the supply assist mechanism 200 and the take-up assist mechanism 200 maintain the contact state without being separated from the roll sheet 1 (or the outer periphery of the paper tube 17). Each operation can be performed without problems.

  According to the configuration described above, it is possible to provide a printing apparatus having a sheet winding function with reduced user load.

[Third Embodiment]
In the first embodiment described above, the supply assist mechanism 200 and the winding assist mechanism 200 automatically perform the separation and contact operations. In the second embodiment described above, the supply assist mechanism 200 and the take-up assist mechanism 200 are kept away from the roll sheet 1 or the paper tube 17 and kept in contact with each other. On the other hand, in the third embodiment, the supply assist mechanism 200 and the winding assist mechanism 200 are not automatically separated and abutted, but are manually separated and abutted by a user. This will be described below. The description of the same configuration and operation as those described in the first and second embodiments is omitted.

(Second usage pattern according to the third embodiment)
FIG. 22 is a diagram illustrating a configuration of a printing apparatus according to the second usage pattern according to the third embodiment. In FIG. 23, the lever 71 manually separates or abuts (releases) the supply assist mechanism 200 and the take-up assist mechanism 200 from the outer peripheral side with respect to the roll sheet 1 or the sheet winding paper tube 17. It is a lever that can be brought into contact. Although not shown, the sensor has a sensor that can detect the state of separation (for example, pressing force), and if the power of the printing apparatus main body is turned on, the auxiliary mechanism 200 can be identified in which state. It has become.

  When the user performs an operation (changing the pressing force) to change the separation state of the auxiliary mechanism 200, the operation of the printing apparatus main body is temporarily stopped, and a message prompting the operation is displayed on the operation panel 20. When the user views the display and changes the state of the lever 71, a sensor (not shown) detects the state change, and the printing apparatus main body proceeds to the next operation.

  The configuration of the present embodiment can also provide a printing apparatus having a sheet winding function with reduced user load.

  As described above, in the first embodiment, each operation sequence in the case where the supply assist mechanism 200 and the winding assist mechanism 200 automatically perform the separation and contact operations has been described. In the second embodiment, each operation sequence in the case where the supply assist mechanism 200 and the winding assist mechanism 200 maintain the contact state without performing the separation operation has been described. In the present invention, the supply assist mechanism 200 and the take-up assist mechanism 200 have no functional problem even if they remain in contact. In addition, during operation such as feeding, printing, rewinding, setting a roll sheet or take-up paper tube, and termination processing, an operation to change the connection / disconnection state is performed automatically or manually as necessary. There is no limitation.

  In the present invention, the pressing force of the auxiliary mechanism 200 against the roll sheet 1 (separation and contact state, and the pressing force in the contact state) can be arbitrarily set according to the scene.

  For example, after feeding the leading edge of the sheet pulled out from the roll sheet through the nip of the transport roller in front of the printing unit, the feeding unit uses a pressing force that is weaker than the pressing force for pulling out the leading edge of the sheet. The line can be corrected appropriately.

  In addition, by using a relatively weak pressing force in the supply and winding unit during printing, stable conveyance can be realized without causing unnecessary tension on the sheet. Damage can be reduced. Further, by separating the auxiliary mechanism at this time, ink transfer or the like from the wound sheet to the auxiliary mechanism is prevented.

  Further, by using a relatively strong pressing force when cutting the sheet, it is possible to prevent the sheet from being bent or the roll sheet from being loosened due to the release of the tension caused by the cutting. Further, by using a relatively weak pressing force at the time of back feed for fixing and attaching the leading end of the sheet to the winding paper tube in the winding unit, it is possible to suitably correct the skew of the sheet.

  The pressing force may be set at two levels of strength or weakness, but may be set at three or more levels in order to obtain a suitable effect according to the scene. Further, the pressing force of the supply assist mechanism and the winding assist mechanism can be set independently of each other, and these pressing forces may be the same or different.

  In this embodiment, the printing apparatus includes two transport units. However, the present invention can also be applied to a printing apparatus including three or more transport units. The present invention is not limited to a printing apparatus, and can be applied to any winding apparatus that winds up a sheet-shaped article.

[Fourth Embodiment]
In the first embodiment described above, the supply assist mechanism 200 and the winding assist mechanism 200 automatically perform the separation and contact operations. In the second embodiment described above, the supply assist mechanism 200 and the take-up assist mechanism 200 are kept away from the roll sheet 1 or the paper tube 17 and kept in contact with each other. In the above-described third embodiment, the supply assist mechanism 200 and the winding assist mechanism 200 do not automatically perform the separation and contact operations, but are manually operated by the user to perform the separation and contact operations.

  In the operation sequence at the time of printing in the fourth usage pattern, the auxiliary mechanism 200 is switched automatically or manually according to at least one of the sheet type (paper type) and the winding direction. This will be described below.

  For example, in the case of an inner winding roll sheet wound with a high rigidity so that the printed surface is on the inside, the roll is wound in the opposite direction to the roll winding roll in addition to the high rigidity. In winding, there is a problem that unwinding occurs and scratches are generated. In order to solve this, it is necessary to wind the sheet with the winding tension greatly increased. However, if the sheet 1 is pulled at a predetermined tension or more during winding, the conveyance accuracy is affected. , Stable conveyance is not realized. On the other hand, the rotational load can be reduced by making the pressing portion a rotating body such as a roller while preventing the loosening by bringing the auxiliary mechanism 200 into contact with the winding. As described above, the winding without loosening can be performed without increasing the winding tension. With this configuration, normal winding can be performed without affecting the conveyance accuracy and suppressing an increase in the cost of the motor.

  In addition, since the low-rigidity sheet has a small curl wrinkle, no loose winding occurs. In addition, when the auxiliary mechanism 200 is brought into contact with the auxiliary mechanism 200, an impression mark may be generated due to the roller pressure contact. In this case, the auxiliary mechanism 200 is used separately.

  On the other hand, in the case of an externally wound roll sheet wound with the print surface facing outward, the curl direction of the sheet and the winding direction of the roll coincide with each other so that the winding can be performed without contacting the auxiliary mechanism 200. There is a tendency not to loosen. Further, a sheet with poor print drying performance because the print surface is on the outside may cause adverse effects such as transfer to a roller when the auxiliary mechanism 200 is brought into contact therewith. Also in this case, the auxiliary mechanism 200 is separated to perform winding.

  From the above, it is possible to handle more sheets while maintaining conveyance accuracy by automatically or manually switching the auxiliary mechanism 200 according to conditions such as sheet type (paper type) and winding direction. It is.

  The contact / separation setting of the auxiliary mechanism 200 is set in advance for each sheet in consideration of the curl property of the sheet and the transfer property of the print. It is configured so that it can be fixed.

  FIG. 23 shows a flow of an operation sequence at the time of printing according to the fourth embodiment, that is, when printing is performed while winding (second usage pattern). In the following description, the symbols in parentheses are the numbers of the steps in the flow shown in the figure.

  When print data from a personal computer or the like is received (R12), the conveyance roller drive motor 35 and the roll drive motor 34 of the lower conveyance unit 70 are both driven in the forward rotation direction (R13), and the sheet 1 is conveyed. To start. The leading end 9 of the sheet 1 in the standby position is fed to the position immediately below the print head 15 (R14). Thereafter, the pressure driving motor 33 of the lower conveyance unit 70 is driven in the direction set by at least one of the sheet type (paper type) and the winding direction, and the winding assist mechanism 200 is moved relative to the roll sheet 1. To keep them apart or in contact with each other (R46). Then, printing is performed by discharging ink while the print head 15 scans in the width direction of the sheet (R16).

  Here, FIG. 14, FIG. 20 and FIG. 23 are compared. In the first embodiment shown in FIG. 14, an operation (R15) for separating the auxiliary mechanism 200 is performed between step R14 and step R16. Further, in the second embodiment shown in FIG. 20, the contact state is maintained without performing the operation of separating the auxiliary mechanism 200 between Step R14 and Step R16. In contrast, in the fourth embodiment, as shown in FIG. 23, the contact / separation state of the auxiliary mechanism 200 is switched by setting or manually (R46). This makes it possible to perform more suitable printing and sheet winding according to conditions.

[Fifth Embodiment]
In the first embodiment described above, the supply assist mechanism 200 and the winding assist mechanism 200 automatically perform the separation and contact operations. In the second embodiment described above, the supply assist mechanism 200 and the take-up assist mechanism 200 are kept away from the roll sheet 1 or the paper tube 17 and kept in contact with each other. In the above-described third embodiment, the supply assist mechanism 200 and the winding assist mechanism 200 do not automatically perform the separation and contact operations, but are manually operated by the user to perform the separation and contact operations. In the fourth embodiment described above, in the operation sequence during printing, the auxiliary mechanism 200 is switched automatically or manually according to at least one of the sheet type (paper type) and the winding direction. . In the fifth embodiment, when the drive of the roll drive motor 34 during winding is stopped, the auxiliary mechanism 200 is automatically switched between contact and separation with the roll sheet 1. This will be described below.

  For example, in a winding device that winds a roll sheet as in the present case by driving a roll drive motor 34, the spool shaft 2 is in a freely rotatable state unless the drive motor 34 is excited. Will be loosened and scratches will occur. For this reason, in order to prevent the roll sheet from unwinding, it is necessary to keep the roll drive motor 34 energized at all times even during printing standby after the main body is turned on. However, if the roll drive motor 34 is always energized, the power consumption of the motor increases and the motor temperature rises. Therefore, the roll drive motor 34 is usually de-energized. Also, when the power of the apparatus main body is turned off, the roll drive motor 34 is de-energized and unwinding occurs. For this reason, in such a winding device, it is necessary to prevent the roll sheet from unwinding even when the printer main body is turned on and in the standby state for printing or in the situation where the power source of the main apparatus body is turned off. Therefore, in the fifth embodiment, before the roll drive motor 34 is de-energized, that is, before it is not driven, the winding assist mechanism 200 is automatically brought into contact with the roll sheet to prevent unwinding. Thus, it is possible to minimize the deterioration of the winding quality.

  FIG. 24 shows a flow of an operation sequence during printing according to the fifth embodiment, that is, when printing is performed while winding (second usage pattern). In the following description, symbols in parentheses are numbers of steps in the flow shown in the figure.

  When print data from a personal computer or the like is received (R12), the conveyance roller drive motor 35 and the roll drive motor 34 of the lower conveyance unit 70 are both driven in the forward rotation direction (R13), and the sheet 1 is conveyed. To start. The leading end 9 of the sheet 1 in the standby position is fed to the position immediately below the print head 15 (R14). Thereafter, the print head 15 discharges ink while scanning in the width direction of the sheet, and printing is performed (R16). When the sheet 1 reaches the paper tube 17, the leading end 9 of the sheet 1 is fixed to the paper tube 17 (R17). After the printing is completed (R53), the pressure drive motor 33 of the lower conveyance unit 70 keeps the winding assist mechanism 200 in contact with the wound sheet 1 (R54). Then, the drive of the roll drive motor 34 is stopped (R54) (not driven), and the printer enters a standby state (R55).

1 Print media (sheets, roll sheets)
2 Spool shaft 10 Conveyance roller 12, 301 Sheet leading edge detection sensor 15 Print head 70 Conveyance unit 200 Auxiliary mechanism (supply assist mechanism, take-up assist mechanism)
300 Sheet conveying unit 400 Printing unit 500 Sheet discharging unit

Claims (9)

A print section for printing on a sheet;
A drive unit that applies a rotational force to the roll member that is rotatably held;
A pressing portion for applying a pressing force to the outer peripheral surface of the roll sheet wound around the roll member;
With
The printing apparatus according to claim 1, wherein the pressing unit changes the pressing force in a sequence in which a rotational force is applied to the roll member by the driving unit and the sheet is wound through the printing unit.   The printing apparatus according to claim 1, wherein the pressing unit is configured to apply the pressing force from below in a vertical direction and be separated from an outer peripheral surface of the roll sheet.   The pressing force has a first size when the leading end of the sheet that has passed through the printing unit is attached to the roll member, and a second size that is smaller than the first size when printing by the printing unit. The printing apparatus according to claim 1, wherein the printing apparatus is variable.   4. The printing apparatus according to claim 3, wherein the printing apparatus has a cutter, and the pressing force is changed to a third size larger than the first size when the sheet is cut by the cutter. The printing apparatus as described.   The driving unit can apply a rotational force in a first direction to take out a sheet, and can apply a rotational force in a second direction opposite to the first direction to wind the sheet. Item 5. The printing apparatus according to any one of Items 1 to 4. A first unit and a second unit, each including the driving unit and the pressing unit,
In the first unit, the driving unit applies a rotational force in the first direction to supply the sheet to the printing unit, and at the same time, in the second unit, the driving unit applies a rotational force in the second direction. It is possible to wind up the printed sheet in the printing unit,
6. The print according to claim 5, wherein the pressing portions of the first unit and the second unit are configured to be able to change the pressing force independently of each other. apparatus.   A method for winding a continuous sheet into a roll, wherein the roll is pressed from below by a pressing portion, and the force applied by the pressing portion is changed during the sequence. A print section for printing on a sheet;
A drive unit that applies a rotational force to the roll member that is rotatably held;
A pressing portion for applying a pressing force to the outer peripheral surface of the roll sheet wound around the roll member;
With
In the sequence of applying a rotational force to the roll member by the driving unit and winding the sheet via the printing unit, the pressing unit applies the pressing force according to at least one of the type of sheet and the winding direction. A printing device characterized by changing. A print section for printing on a sheet;
A drive unit that applies a rotational force to the roll member that is rotatably held;
A pressing portion for applying a pressing force to the outer peripheral surface of the roll sheet wound around the roll member;
With
In the sequence of applying a rotational force to the roll member by the driving unit and winding the sheet via the printing unit, the pressing unit applies the pressing force before the driving unit switches from driving to non-driving. A printing device characterized by changing.

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