JP2013035678A - Strip-shaped medium conveying device, and control method of strip-shaped medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To execute proper proportional control corresponding to a deviation degree from a reference position in the width direction, of the position where a strip-shaped medium is located.SOLUTION: This strip-shaped medium conveying device includes: a conveying portion for conveying the strip-shaped medium; an acquiring portion for acquiring the position in the width direction for positioning the strip-shaped medium; a steering portion for changing the position in the width direction of the strip-shaped medium by turning; and a controller for executing the proportional control of a turning angle of the steering portion per unit conveying quantity of the strip-shaped media corresponding to the deviation degree from the reference position in the width direction.

Description

  The present invention relates to a belt-shaped medium conveyance device and a belt-shaped medium control method.

  A belt-shaped medium transport apparatus having a transporting section for transporting a belt-shaped medium such as roll paper is already well known. Examples of such a belt-shaped medium transport device include an image recording device that records an image on roll paper.

  The belt-shaped medium transport device includes an acquisition unit that acquires a position in the width direction where the band-shaped medium is located, and a steering unit that changes the position in the width direction of the band-shaped medium by rotating. As the control of the belt-like medium, proportional control is performed in which the steering unit is operated according to the degree of deviation of the position in the width direction from the reference position.

JP 2009-73590 A

  Conventionally, as proportional control for operating the steering unit, proportional control of the rotation speed of the steering unit according to the degree of deviation has been performed, but the control has an insufficient aspect.

  The present invention has been made in view of such problems, and an object of the present invention is to perform appropriate proportional control according to the degree of deviation from the reference position of the width direction position where the belt-like medium is located. .

The main present invention includes a transport unit that transports a belt-shaped medium;
An acquisition unit for acquiring a position in the width direction where the belt-like medium is located;
A steering unit that changes the position in the width direction of the belt-like medium by rotating;
A controller that performs proportional control of the rotation angle of the steering unit per unit transport amount of the belt-shaped medium according to the degree of deviation from the reference position of the width direction position;
It is a strip | belt-shaped medium conveying apparatus characterized by having.
Other features of the present invention will become apparent from the description of the present specification and the accompanying drawings.

1 is a schematic diagram illustrating a configuration of an image recording apparatus 1. FIG. 1 is a block diagram illustrating a configuration of an image recording apparatus 1. FIG. It is a perspective view of the steering unit 20a. It is a top view of the steering unit 20a. It is a rear view of the steering unit 20a. It is a side view of the steering unit 20a. It is a figure for demonstrating the operation example of the steering unit 20a. FIG. 6 is a diagram schematically showing how the paper edge position detection sensor 50a detects the paper edge position in the width direction of the roll paper 2; It is a block diagram showing control concerning this embodiment. It is a block diagram showing control concerning a comparative example.

  At least the following will be made clear by the description of the present specification and the accompanying drawings.

A transport unit for transporting a belt-shaped medium;
An acquisition unit for acquiring a position in the width direction where the belt-like medium is located;
A steering unit that changes the position in the width direction of the belt-like medium by rotating;
A controller that performs proportional control of the rotation angle of the steering unit per unit transport amount of the belt-shaped medium according to the degree of deviation from the reference position of the width direction position;
A belt-shaped medium transporting device characterized by comprising:
According to such a belt-shaped medium transport device, it is possible to perform appropriate proportional control in accordance with the degree of deviation from the reference position of the width direction position where the belt-shaped medium is located.

The controller may change a proportional gain of the proportional control according to a type of the belt-like medium.
In such a case, it becomes possible to perform more appropriate proportional control according to the degree of deviation from the reference position of the width direction position where the belt-like medium is located.

Next, obtaining the width direction position where the belt-like medium is located,
Proportional control of the rotation angle of the steering unit that changes the position in the width direction of the band-shaped medium by rotating per unit transport amount of the band-shaped medium according to the degree of deviation from the reference position of the width direction position. And doing
A method for controlling a belt-like medium, comprising:
According to such a belt-shaped medium control method, it is possible to perform appropriate proportional control according to the degree of deviation from the reference position of the width direction position where the belt-shaped medium is located.

=== About Configuration Example of Image Recording Apparatus 1 ===
A configuration example of the image recording apparatus 1 as an example of the belt-shaped medium conveyance device will be described with reference to FIGS. 1 and 2. FIG. 1 is a schematic sectional view of the image recording apparatus 1. FIG. 2 is a block diagram of the image recording apparatus 1.
In the following description, when referring to “up and down direction” and “left and right direction”, the direction indicated by the arrow in FIG. 1 is used as a reference. In addition, the “front-rear direction” refers to a direction orthogonal to the paper surface in FIG.
Also, in the present embodiment, as an example of a belt-like medium on which the image recording apparatus 1 records an image, a sheet wound in a roll shape (hereinafter referred to as roll paper (continuous paper)) will be described.

  As shown in FIGS. 1 and 2, the image recording apparatus 1 according to the present embodiment includes a transport unit 20 as an example of a transport unit, and a transport path through which the transport unit 20 transports the roll paper 2 (FIG. 1). 2, the conveyance path is represented by a portion where the roll paper 2 is positioned between the winding shaft 18 and the winding drive shaft 92), along the feeding unit 10, the platen 29, and the winding unit 90. And a head unit 30 as an example of an image recording unit for discharging an ink as an example of a liquid in the image recording region R on the transport path, a carriage unit 40, and a heater A unit 70, a blower unit 80 for sending air to the roll paper 2 on the platen 29, and a controller 6 for controlling these units and controlling the operation as the image recording apparatus 1. When, and a detector group 50, a.

  The feeding unit 10 feeds the roll paper 2 to the transport unit 20. The feeding unit 10 includes a winding shaft 18 around which the roll paper 2 is wound and rotatably supported, a relay roller 19 for winding the roll paper 2 fed from the winding shaft 18 and guiding the roll paper 2 to the transport unit 20; have.

  The transport unit 20 transports the roll paper 2 sent by the feeding unit 10 along a preset transport path. As shown in FIG. 1, the transport unit 20 includes a relay roller 21 that is positioned horizontally to the right of the relay roller 19, a relay roller 22 that is positioned obliquely downward to the right when viewed from the relay roller 21, and the relay roller 22. Steering unit as an example of a steering unit located between the first conveying roller 23 located on the right upper side when viewed from the upstream side (upstream side in the conveying direction when viewed from the platen 29) and the relay roller 22 and the first conveying roller 23 (Steering unit) 20a, a second transport roller 24 located on the right side (the downstream side in the transport direction as viewed from the platen 29) as viewed from the first transport roller 23, and a vertically lower position as viewed from the second transport roller 24 The reversing roller 25, the relay roller 26 located on the right side when viewed from the reversing roller 25, and the upper side when viewed from the relay roller 26. That feed has a roller 27, a. The steering unit 20a will be described in detail later.

The relay roller 21 is a roller that winds the roll paper 2 sent from the relay roller 19 from the left side and loosens it downward.
The relay roller 22 is a roller that winds the roll paper 2 sent from the relay roller 21 from the left side and conveys it obliquely upward to the right.

  The first transport roller 23 includes a first drive roller 23a driven by a motor (not shown), and a first driven roller 23b arranged to face the first drive roller 23a with the roll paper 2 interposed therebetween. have. The first transport roller 23 is a roller that pulls up the roll paper 2 slacked downward and transports it to the image recording region R facing the platen 29. The first conveyance roller 23 temporarily stops conveyance during a period in which image printing is performed on the portion of the roll paper 2 on the image recording region R. In addition, the conveyance amount of the roll paper 2 positioned on the platen 29 is adjusted by rotating the first driven roller 23b in accordance with the rotational drive of the first drive roller 23a by the drive control of the controller 60.

  As described above, the transport unit 20 has a mechanism for transporting the portion of the roll paper 2 wound between the relay rollers 21 and 22 and the first transport roller 23 by slacking it downward. The slackness of the roll paper 2 is monitored by the controller 60 based on a detection signal from a slack detection sensor (not shown). Specifically, when a portion of the roll paper 2 slackened between the relay rollers 21 and 22 and the first transport roller 23 is detected by the slack detection sensor, a tension of an appropriate magnitude is applied to the portion. Therefore, the transport unit 20 can transport the roll paper 2 in a relaxed state. On the other hand, when the portion of the roll paper 2 that has been loosened is not detected by the slack detection sensor, an excessive amount of tension is applied to the portion, so that the roll paper 2 is transported by the transport unit 20. It is temporarily stopped and the tension is adjusted to an appropriate magnitude.

  The second transport roller 24 includes a second drive roller 24a driven by a motor (not shown), and a second driven roller 24b disposed so as to face the second drive roller 24a with the roll paper 2 interposed therebetween. have. The second transport roller 24 is a roller that transports the portion of the roll paper 2 on which the image is recorded by the head unit 30 in the horizontal right direction along the support surface of the platen 29 and then transports it vertically downward. Thereby, the conveyance direction of the roll paper 2 is changed. The second driven roller 24b rotates as the second drive roller 24a is driven to rotate by the drive control of the controller 60, whereby a predetermined amount given to the portion of the roll paper 2 located on the platen 29 is obtained. Tension is adjusted.

The reversing roller 25 is a roller that wraps the roll paper 2 sent from the second conveying roller 24 from the upper left side and conveys it diagonally upward to the right.
The relay roller 26 is a roller that winds the roll paper 2 sent from the reversing roller 25 from the lower left side and conveys it upward.
The delivery roller 27 winds the roll paper 2 sent from the relay roller 26 from the lower left side and sends it to the take-up unit 90.

  As described above, the roll paper 2 moves sequentially through the rollers, whereby a transport path for transporting the roll paper 2 is formed. The roll paper 2 is intermittently transported along the transport path by the transport unit 20 in units of regions corresponding to the image recording regions R.

  The head unit 30 is for recording an image on a portion of the roll paper 2 located in the image recording region R on the transport path. That is, the head unit 30 forms an image by ejecting ink onto a portion of the roll paper 2 that has been fed into the image recording region R (on the platen 29) on the transport path by the transport unit 20. The head unit 30 has a head 31 and a valve unit 34.

  The head 31 has a nozzle row in which nozzles are arranged in the row direction on the lower surface thereof. In the present embodiment, each of the colors such as yellow (Y), magenta (M), cyan (C), and black (K) has a nozzle row composed of a plurality of nozzles # 1 to #N. The nozzles # 1 to #N in each nozzle row are linearly arranged in a crossing direction that intersects the transport direction of the roll paper 2 (that is, the crossing direction is the above-described row direction). Each nozzle row is arranged in parallel with a space between each other along the transport direction.

  Each nozzle # 1 to #N is provided with a piezo element (not shown) as a drive element for ejecting ink droplets. When a voltage having a predetermined time width is applied between the electrodes provided at both ends of the piezoelectric element, the piezoelectric element expands according to the voltage application time and deforms the side wall of the ink flow path. As a result, the volume of the ink flow path contracts according to the expansion and contraction of the piezo element, and the ink corresponding to the contraction is ejected from the nozzles # 1 to #N of the respective colors as ink droplets.

  The valve unit 34 is for temporarily storing ink, and is connected to the head 31 via an ink supply tube (not shown). For this reason, the head 31 can perform image recording by discharging the ink supplied from the valve unit 34 toward the portion of the roll paper 2 that has been transported from the nozzle onto the platen 29 and stopped. .

  The carriage unit 40 is for moving the head 31. The carriage unit 40 is supported by a carriage guide rail 41 (indicated by a two-dot chain line in FIG. 1) extending in the transport direction (left-right direction) and reciprocally movable along the carriage guide rail 41 in the transport direction (left-right direction). A carriage 42 and a motor (not shown).

  The carriage 42 is configured to move in the transport direction (left-right direction) together with the head 31 by driving a motor (not shown).

  The cleaning unit (not shown) is for cleaning the head 31. The cleaning unit is provided at a home position (hereinafter referred to as HP, see FIG. 1), and includes a cap, a suction pump, and the like. When the head 31 (carriage 42) moves in the transport direction (left-right direction) and is positioned on the HP, a cap (not shown) comes into close contact with the lower surface (nozzle surface) of the head 31. When the suction pump operates in such a state that the cap is in close contact, the ink in the head 31 is sucked together with the thickened ink and paper dust. In this way, the clogged nozzle recovers from the non-ejection state, thereby completing the head cleaning.

  A flushing unit 35 is provided between the HP and the platen 29 in the transport direction (left-right direction), and the head 31 (carriage 42) moves in the transport direction (left-right direction) and faces the flushing unit 35. When the head 31 is positioned, the head 31 performs a flushing operation for performing flushing by ejecting ink from each nozzle belonging to the nozzle row.

  The platen 29 supports the part of the roll paper 2 located in the image recording region R on the conveyance path and heats the part. As shown in FIG. 1, the platen 29 is provided corresponding to the image recording area R on the conveyance path, and is an area along the conveyance path between the first conveyance roller 23 and the second conveyance roller 24. Is arranged. The platen 29 can heat the portion of the roll paper 2 by receiving supply of heat generated by the heater unit 70.

  The heater unit 70 is for heating the roll paper 2 and has a heater (not shown). This heater has a nichrome wire, and the nichrome wire is arranged inside the platen 29 so as to be at a fixed distance from the support surface of the platen 29. For this reason, when the heater is energized, the nichrome wire itself generates heat, and heat can be conducted to the portion of the roll paper 2 located on the support surface of the platen 29. Since this heater is configured by incorporating a nichrome wire in the entire area of the platen 29, heat can be uniformly conducted to the portion of the roll paper 2 on the platen 29. In the present embodiment, the portion of the roll paper 2 is uniformly heated so that the temperature of the portion of the roll paper 2 on the platen is 45 ° C. Thereby, the ink landed on the part of the roll paper 2 can be dried.

  The blower unit 80 is for sending wind to the roll paper 2 on the platen 29. The blower unit 80 includes a fan 81 and a motor (not shown) that rotates the fan 81. The fan 81 rotates to send wind to the roll paper 2 on the platen 29 and dry the ink landed on the roll paper 2. As shown in FIG. 1, a plurality of fans 81 are provided on an openable / closable cover (not shown) provided on the main body. Each fan 81 is positioned above the platen 29 when the cover is closed, and faces the support surface of the platen 29 (the roll paper 2 on the platen 29).

  The take-up unit 90 is for taking up the roll paper 2 (roll paper on which an image has been recorded) sent by the transport unit 20. This take-up unit 90 is fed from the relay roller 91 that is rotatably supported by the relay roller 91 for winding the roll paper 2 sent from the feed roller 27 from the upper left side and conveying it to the lower right side. And a take-up drive shaft 92 for taking up the roll paper 2.

  The controller 60 is a control unit for controlling the image recording apparatus 1. As shown in FIG. 2, the controller 60 includes an interface unit 61, a CPU 62, a memory 63, and a unit control circuit 64. The interface unit 61 is for transmitting and receiving data between the host computer 110 as an external device and the image recording apparatus 1. The CPU 62 is an arithmetic processing device for controlling the entire image recording apparatus 1. The memory 63 is for securing an area for storing a program of the CPU 62, a work area, and the like. The CPU 62 controls each unit by a unit control circuit 64 according to a program stored in the memory 63.

  The detector group 50 is for monitoring the situation in the image recording apparatus 1. For example, a rotary encoder that is attached to the above-described slack detection sensor and the conveyance roller and is used for controlling the conveyance of the roll paper 2. A paper detection sensor for detecting the presence or absence of the roll paper 2 being conveyed, a linear encoder for detecting the position of the carriage 42 (or head 31) in the conveyance direction (left and right direction), and the paper edge in the width direction of the roll paper 2 There is a paper edge position detection sensor 50a (see FIGS. 1 and 8 for detecting the (edge) position. The paper edge position detection sensor 50a will be described later).

=== About the Steering Unit 20a ===
<<< Configuration Example of Steering Unit 20a >>>
Next, the steering unit 20a will be described with reference to FIGS. FIG. 3 is a perspective view of the steering unit 20a. FIG. 4 is a plan view of the steering unit 20a. FIG. 5 is a rear view of the steering unit 20a. FIG. 6 is a side view of the steering unit 20a. The coil spring 209 in the present embodiment is formed by spirally winding a metal wire having a predetermined wire diameter by a predetermined number of turns. In FIGS. 3 to 6, for convenience, the coil spring 209 is formed. The external appearance shape is simplified and illustrated.

  As shown in FIG. 1, the steering unit 20a is positioned on the transport path in an inclined state and rotates (specifically, as will be described later, the base member 203 of the steering unit 20a rotates). This is for changing the position in the width direction of the roll paper 2 (the position where the roll paper 2 is positioned in the width direction (the front-rear direction shown in FIG. 1)). That is, when the roll paper 2 is conveyed along the conveyance path, the tension applied to the roll paper 2 fluctuates due to an axial deviation or an assembly error of a relay roller or the like. The position may be displaced. The steering unit 20 a is for adjusting the position in the width direction of the roll paper 2.

  The steering unit 20a includes a first roller 201 and a second roller 202, and a first roller 201 and a second roller 202 for conveying the roll paper 2 in the conveying direction, as shown in FIGS. A base member 203 is rotatably supported around the central shafts 201a and 202a, an eccentric cam 204 for rotating the base member 203 around the rotation shaft 203a, and a motor 205.

The first roller 201 and the second roller 202 are configured to be rotatable around the respective central axes 201a and 202a, and are juxtaposed in the transport direction as shown in FIG.
As shown in FIG. 1, the first roller 201 is located on the upstream side of the second roller 202 in the transport direction, and rolls the roll paper 2 sent from the relay roller 22 from above and below the second roller 202. It is the roller which conveys toward.
As shown in FIG. 1, the second roller 202 is positioned downstream in the transport direction from the first roller 201, and rolls the roll paper 2 sent from the first roller 201 from below, It is a roller that conveys toward one conveyance roller 23.

  As shown in FIGS. 5 and 6, the base member 203 is centered on the rotation shaft 203 a above the base 200 fixed to the image recording apparatus 1 by the rotation shaft 203 a and the two movable support portions 210. And is rotatably supported.

  The rotation shaft 203 a supports the base member 203 so as to be rotatable with respect to the base 200. As shown in FIGS. 4 and 6, the rotation shaft 203 a is located closer to the first roller 201 than the second roller 202, and the central axis 201 a of the first roller 201 and the central axis of the second roller 202. 202a, and is fixed to the base 200 along the normal direction of the virtual plane.

  As shown in FIG. 4, the movable support portion 210 supports the base member 203 while moving along a circle centered on the rotation shaft 203a. As shown in FIGS. 5 and 6, the movable support portion 210 has an L-shaped bracket 210a fixed to the lower surface of the base member 203 and a wheel 210b that is rotatably provided at the tip of the L-shaped bracket 210a. doing. As shown in FIG. 5, the movement of the wheel 210 b in the vertical direction is restricted by the restriction member 211. For this reason, when the base member 203 rotates, vertical vibration can be suppressed.

  The motor 205 is fixed on the base 200 via a bracket and is driven based on a control signal from the controller 60 to rotate the base member 203. The motor 205 has a rotary encoder (not shown) for detecting the rotation angle. As shown in FIG. 4, the drive shaft 205a of the motor 205 is connected to the transmission shaft 205c via a coupling 205b, and a worm (screw gear) 206 is fitted to the transmission shaft 205c. The transmission shaft 205 c is supported at both ends by bearings 205 d fixed to the base 200. As shown in FIG. 4, the worm 206 meshes with a worm wheel (helical gear) 207 that is rotatably supported around a central axis 207a. For this reason, by using the worm 206 and the worm wheel 207 to decelerate, a large torque can be transmitted even if the motor 205 is small.

  As shown in FIG. 4, the worm wheel 207 is integrated with the eccentric cam 204 by the drive force of the motor 205 transmitted via the drive shaft 205 a, the coupling 205 b, the transmission shaft 205 c, and the worm 206. Then, the turning operation is performed. The worm wheel 207 is not positioned on the opposite side of the first roller 201 with the second roller 202 sandwiched in the conveyance direction of the roll paper 2 during the rotation operation, and at least a part of the worm wheel 207 is It faces the second roller 202 in the normal direction of the virtual plane (the virtual plane including the central axes 201a and 202a of the first roller 201 and the second roller 202). That is, as shown in FIG. 4, the worm wheel 207 does not protrude downstream from the second roller 202 in the transport direction, and faces the second roller 202 with the base member 203 interposed therebetween (paper surface). It is positioned so as to overlap the second roller 202 above. For this reason, while avoiding the contact between the worm wheel 207 and the roll paper 2, the driving force acts at the position of the second roller 202 far from the position of the rotation shaft 203 a, so that the positioning accuracy in the width direction of the roll paper Can be increased.

  The eccentric cam 204 is for rotating the base member 203 around the rotation axis 203a by performing a rotation operation around the central axis 204a. As shown in FIGS. 4 and 5, the eccentric cam 204 is in contact with the cam follower 208 provided so as to protrude from the lower surface of the base member 203. The cam follower 208 is always urged in a direction in which the cam follower 208 is pressed against the eccentric cam 204 by the coil spring 209. For this reason, the eccentric cam 204 engages with the cam follower 208 along with the rotating operation when the driving force of the motor 205 is transmitted and the rotating operation is performed coaxially with the worm wheel 207. Thus, the base member 203 can be rotated around the rotation shaft 203a. In addition, the eccentric cam 204 is not located on the opposite side of the first roller 201 with the second roller 202 interposed in the conveyance direction of the roll paper 2 during the rotation operation, and at least a part of the eccentric cam 204. Is opposed to the second roller 202 in the normal direction of the virtual plane (the virtual plane including the central axes 201a and 202a of the first roller 201 and the second roller 202). That is, as shown in FIG. 4, the eccentric cam 204 does not protrude downstream from the second roller 202 in the transport direction, and faces the second roller 202 with the base member 203 interposed therebetween (paper surface). It is positioned so as to overlap the second roller 202 above. Accordingly, since the driving force acts at the position of the second roller 202 far from the position of the rotation shaft 203a while avoiding the contact between the eccentric cam 204 and the roll paper 2, the positioning accuracy in the width direction of the roll paper 2 is achieved. Can be increased.

  As shown in FIG. 5, the coil spring 209 has one end fixed to the base member 203 via the L-shaped bracket 209a and the other end fixed to the base 200 via the L-shaped bracket 209b. It is a spring. Accordingly, the coil spring 209 can be biased in a direction in which the cam follower 208 is pressed against the eccentric cam 204. Further, as shown in FIG. 4, the coil spring 209 is disposed along the tangential direction of a circle centered on the rotation shaft 203a, and therefore, the base member 203 that performs a circular motion about the rotation shaft 203a is provided. On the other hand, the spring force can be transmitted most efficiently. The coil spring 209 is not positioned on the opposite side of the first roller 201 with the second roller 202 sandwiched in the conveyance direction of the roll paper 2, and at least a part of the coil spring 209 is a virtual plane (first roller 201 And the second roller 202 is opposed to the second roller 202 in the normal direction of a virtual plane including the central axes 201a and 202a of the second roller 202. That is, as shown in FIG. 4, the coil spring 209 does not protrude to the downstream side of the second roller 202 in the transport direction and faces the second roller 202 with the base member 203 interposed therebetween (on the paper surface). And so as to overlap the second roller 202). As a result, the biasing force by the coil spring 209 acts at the position of the second roller 202 far from the position of the rotation shaft 203a while avoiding contact between the coil spring 209 and the roll paper 2, and therefore in the width direction of the roll paper 2 Positioning accuracy can be increased.

<<<< Example of Operation of Steering Unit 20a >>>>
Next, an operation example of the steering unit 20a will be described with reference to FIGS. FIG. 7 is a diagram for explaining an operation example of the steering unit 20a.

  First, an operation when the steering unit 20a moves the position of the roll paper 2 in the width direction to the front side in the width direction (see the downward white arrow in FIG. 7) will be described.

In such a case, the drive control of the motor 205 is executed by the controller 60 so that the eccentric cam 204 rotates clockwise in FIG.
When the eccentric cam 204 rotates clockwise, the cam follower 208 pressed against the eccentric cam 204 by the urging force of the coil spring 209 reduces the distance between the centers of the eccentric cam 204 and the circle about the rotation shaft 203a. It moves clockwise along the trajectory (see FIG. 4).

  Then, since the cam follower 208 is attached to the base member 203, the base member 203 also rotates clockwise about the rotation shaft 203a (see the arrow in FIG. 4 and the downward black arrow in FIG. 7). The roll paper 2 tends to be positioned on the front side in the width direction (see the downward white arrow in FIG. 7). Thereby, the position in the width direction of the roll paper 2 moves to the near side.

On the other hand, the operation when the steering unit 20a moves the position in the width direction of the roll paper 2 to the back side in the width direction (see the upward white arrow in FIG. 7) is the reverse of the above operation.
That is, in such a case, the drive control of the motor 205 is executed by the controller 60 so that the eccentric cam 204 rotates counterclockwise in FIG.

  When the eccentric cam 204 rotates counterclockwise, the cam follower 208 pressed against the eccentric cam 204 by the biasing force of the coil spring 209 rotates against the biasing force while increasing the distance between the centers of the eccentric cam 204 and the cam follower 208. It moves counterclockwise along a circular orbit centered on the moving shaft 203a (see FIG. 4).

  Then, since the cam follower 208 is attached to the base member 203, the base member 203 also rotates counterclockwise about the rotation shaft 203a (see the arrow in FIG. 4 and the upward black arrow in FIG. 7). The roll paper 2 tends to be positioned on the back side in the width direction (see the upward white arrow in FIG. 7). Thereby, the position in the width direction of the roll paper moves to the back side.

=== Regarding a control example in which the roll paper 2 is controlled by operating the steering unit 20a ===
Next, a control example in which the roll paper 2 is controlled by operating the steering unit 20a will be described with reference to FIGS. FIG. 9 is a block diagram showing the control according to the present embodiment. FIG. 10 is a block diagram showing control according to the comparative example. Note that FIG. 8 will be described later.

  Various operations described below are mainly realized by the controller 60. In particular, in the present embodiment, it is realized by the CPU 62 or the like processing a program stored in the memory 63. And this program is comprised from the code | cord | chord for performing the various operation | movement demonstrated below.

  The controller 60 according to this embodiment controls the roll paper 2 by operating the steering unit 20a (controls the position in the width direction of the roll paper 2). That is, the controller 60 controls the roll paper 2 by operating the steering unit 20a so that the position in the width direction where the roll paper 2 is located is a desired position (that is, the reference position). As the control of the roll paper 2, proportional control according to the degree of deviation of the position in the width direction from the reference position (that is, proportional control (P control) for operating the steering unit 20a according to the degree of deviation). Executed. This will be specifically described below.

  First, the controller 60 grasps the position in the width direction of the roll paper 2. In the present embodiment, a paper edge position detection sensor 50a (corresponding to an acquisition unit that acquires the width direction position) is provided to acquire the width direction position.

  Here, the paper edge position detection sensor 50a will be described. As described above, the paper edge position detection sensor 50 a has a function of detecting the paper edge (edge) position in the width direction of the roll paper 2. As shown in FIG. 1, the paper edge position detection sensor 50 a is provided in the vicinity of the first transport roller 23 and upstream of the first transport roller 23 in the transport direction, and includes a light emitting unit 502 and a light receiving sensor unit. 504 is a publicly known optical sensor.

  Attention is now directed to FIG. FIG. 8 is a diagram schematically showing how the paper edge position detection sensor 50 a detects the paper edge position in the width direction of the roll paper 2. FIG. 8 shows three drawings. The center diagram shows how the paper edge position detection sensor 50a detects the paper edge position when the roll paper 2 is located at the reference position. The figure shows how the paper edge position detection sensor 50a detects the paper edge position when the roll paper 2 is shifted from the reference position to the back side in the width direction, and the right figure shows that the roll paper 2 is detected from the reference position. FIG. 4 illustrates how the paper edge position detection sensor 50a detects the paper edge position when it is shifted to the near side in the width direction.

  As shown in FIG. 8, the light emitting unit 502 and the light receiving sensor unit 504 of the paper edge position detection sensor 50 a sandwich the roll paper 2 in the normal direction of the roll paper 2 (direction passing through the paper surface in FIG. 8). , Emit light along the normal direction, and receive the emitted light. Then, the paper edge position detection sensor 50a determines how much the roll paper 2 blocks the light emitted from the light emitting unit 502 depending on where the roll paper 2 is positioned in the width direction (that is, which roll paper 2 is The paper edge position in the width direction of the roll paper 2 is detected by utilizing the fact that the degree of whether the light does not reach the light receiving sensor unit 504 is changed.

  For example, as is apparent from FIG. 8, when the roll paper 2 is shifted from the reference position toward the back side in the width direction (left figure), the roll paper 2 is located at the reference position (center). The amount of light blocked by the roll paper 2 is larger than that in the figure), and when the roll paper 2 is shifted from the reference position toward the front side in the width direction (right figure), the roll paper 2 is at the reference position. The amount of light blocked by the roll paper 2 is less than when positioned (center view). Therefore, when the roll paper 2 is displaced from the reference position toward the back side in the width direction (left figure), the paper edge position is detected more than when the roll paper 2 is located at the reference position (center figure). When the output value of the sensor 50a (voltage value in the present embodiment) is small and the roll paper 2 is shifted from the reference position toward the front side in the width direction (right figure), the roll paper is at the reference position. The output value of the paper edge position detection sensor 50a is larger than when 2 is located (center view). Then, the paper edge position can be detected by the difference in the output values. In the present embodiment, the paper end position detection sensor 50a is positioned so that the paper end position detection sensor 50a outputs a voltage value of 3V when the roll paper 2 is positioned at the reference position. .

  As described above, in the present embodiment, the paper edge position detection sensor 50a detects the paper edge position in the width direction of the roll paper 2 (naturally, this is the position in the width direction where the roll paper 2 is located. The detection result relating to the paper edge position (width direction position) is output (in this embodiment, the voltage value is output in the range of 1 V to 5 V). ). The output of the detection result (voltage value) relating to the paper edge position (width direction position) is the control amount that is the output of the control target (that is, the image recording apparatus 1) in the block diagrams of FIGS. It corresponds to c.

  As described above, the controller 60 receives the detection result (voltage value) from the paper edge position detection sensor 50 a and grasps the width direction position of the roll paper 2. Then, the controller 60 calculates the degree of deviation from the reference position of the width direction position. Specifically, the controller 60 calculates the difference by subtracting the voltage value output by the paper edge position detection sensor 50a from 3V, which is the voltage value when the roll paper 2 is positioned at the reference position.

  In this case, when the roll paper 2 is shifted from the reference position toward the front side in the width direction (the right diagram in FIG. 8), the difference becomes a negative value and the larger the deviation amount, the more The absolute value of a negative value increases. Further, when the roll paper 2 is shifted from the reference position to the back side in the width direction (the left figure in FIG. 8), the difference becomes a positive value, and the larger the deviation amount, the more positive the roll paper 2 is. The value (absolute value) increases. Thus, by calculating the difference, the degree of deviation of the width direction position from the reference position is obtained.

  In the block diagrams of FIGS. 9 and 10, 3V, which is a voltage value when the roll paper 2 is located at the reference position, corresponds to the target value r, and the paper edge position detection sensor 50a is determined from the voltage value 3V. The difference obtained by subtracting the output voltage value corresponds to the deviation e. As will be described below, the difference (deviation e) is set to 0, in other words, when the roll paper 2 is positioned at the reference position of the voltage value output by the paper edge position detection sensor 50a. The proportional control of the roll paper 2 is performed so that the voltage value becomes 3V (that is, the position in the width direction where the roll paper 2 is positioned becomes the reference position).

  Here, the proportional control (this example, FIG. 9) of the roll paper 2 according to the present embodiment will be described in comparison with a comparative example (conventional example, FIG. 10). In both the present example and the comparative example, the controller 60 performs proportional control according to the degree of deviation of the width direction position from the reference position (that is, the deviation e which is the difference). That is, as shown in FIGS. 9 and 10, the steering unit 20 a is adjusted based on the operation amount u obtained by multiplying the deviation e by the proportional gain K (that is, the operation amount u = proportional gain K × deviation e). By operating, the position in the width direction of the roll paper 2 is controlled.

  However, this example and the comparative example differ in which amount relating to the steering unit 20a is the operation amount u. That is, in the comparative example, the controller 60 performs proportional control of the turning angle of the steering unit 20a per unit time (that is, the turning angular velocity of the steering unit 20a) according to the degree of deviation, whereas this case In the example, the controller 60 is proportional to the rotation angle of the steering unit 20a per unit transport amount of the roll paper 2 according to the degree of deviation (hereinafter referred to as the quasi-rotation angular velocity of the steering unit 20a for convenience of explanation). Take control.

  That is, in the comparative example, the rotation angular velocity of the steering unit 20a (more specifically, the rotation angular velocity of the base member 203) is the operation amount u, and the controller 60 responds to the deviation degree (deviation e). Thus, a command is given to the steering unit 20a as to how many the rotational angular velocities are (the unit is [rad (radian) / sec (second)] as shown in FIG. 10). In response to the command, the steering unit 20a (more specifically, the motor 205) operates so that the rotational angular velocity of the base member 203 becomes the commanded value.

  On the other hand, in this example, the quasi-rotational angular velocity of the steering unit 20a (more specifically, the quasi-rotational angular velocity of the base member 203) is the operation amount u, and the controller 60 determines the degree of deviation (deviation e). Accordingly, a command is given to the steering unit 20a as to how much the quasi-rotational angular velocity is to be set (the unit is [rad (radian) / mm (millimeter)] as shown in FIG. 9). In response to the command, the steering unit 20a (more specifically, the motor 205) operates so that the quasi-rotating angular velocity of the base member 203 becomes the commanded value.

  Then, due to the above-described differences from the comparative example of the present example, the present example has the advantages described below. That is, in the comparative example, since the rotation angular velocity (the rotation angle per unit time) becomes the operation amount u, the conveyance (speed) of the roll paper 2 is not considered at all in the control. Therefore, the same control is performed in both cases as long as the deviation e is the same regardless of whether the roll paper 2 is transported fast or transported slowly. However, when the roll paper 2 is conveyed faster, the control according to the comparative example takes into account that it is more appropriate to rotate the steering unit 20a faster (that is, to turn the steering faster). Had an inadequate aspect.

  On the other hand, in this example, proportional control of the rotation angle of the steering unit 20a per unit transport amount of the roll paper 2 is performed according to the degree of deviation. In other words, the steering is performed when the quasi-rotating angular velocity (the rotation angle per unit conveyance amount) is the operation amount u, the conveyance (speed) of the roll paper is appropriately considered in the control, and the roll paper 2 is conveyed faster. An appropriate operation in which the unit 20a rotates faster is realized. Therefore, according to this example, it is possible to perform more appropriate proportional control according to the degree of deviation.

=== Other Embodiments ===
Although the above embodiments are mainly described for the belt-shaped medium transport device, disclosure of a method for controlling the belt-shaped medium is also included. The above-described embodiments are for facilitating understanding of the present invention, and are not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof. In particular, the embodiments described below are also included in the present invention.

  In the above embodiment, the belt-shaped medium transport device is embodied as an image recording device, but the present invention is not limited to this. For example, as long as the apparatus has a function of conveying a belt-like medium, the apparatus may not have an image recording function.

  Further, although the image recording apparatus is embodied as a liquid ejecting apparatus (liquid ejecting apparatus) that performs image recording by ejecting liquid, the present invention is not limited to this. For example, as long as the apparatus has a function of recording an image, the apparatus may not discharge liquid.

  In addition, although the liquid ejecting apparatus (liquid ejecting apparatus) is embodied in an ink jet printer, a liquid ejecting apparatus that ejects or ejects liquid other than ink may be employed. The present invention can be used for various liquid ejecting apparatuses including a liquid ejecting head to be ejected. In addition, a droplet means the state of the liquid discharged from the said liquid ejecting apparatus, and shall also include what pulls a tail in granular shape, tear shape, and thread shape. The liquid here may be any material that can be ejected by the liquid ejecting apparatus. For example, it may be in the state when the substance is in a liquid phase, such as a liquid state with high or low viscosity, sol, gel water, other inorganic solvents, organic solvents, solutions, liquid resins, liquid metals (metal melts ) And a liquid as one state of a substance, as well as a material in which particles of a functional material made of a solid such as a pigment or metal particles are dissolved, dispersed or mixed in a solvent. Further, representative examples of the liquid include ink and liquid crystal as described in the above embodiment. Here, the ink includes general water-based inks and oil-based inks, and various liquid compositions such as gel inks and hot melt inks. As a specific example of the liquid ejecting apparatus, for example, a liquid containing a material such as an electrode material or a color material used for manufacturing a liquid crystal display, an EL (electroluminescence) display, a surface emitting display, a color filter, or the like in a dispersed or dissolved state. It may be a liquid ejecting apparatus for ejecting, a liquid ejecting apparatus for ejecting a bio-organic material used for biochip manufacturing, a liquid ejecting apparatus for ejecting a liquid as a sample used as a precision pipette, a printing apparatus, a microdispenser, or the like. In addition, transparent resin liquids such as UV curable resin to form liquid injection devices that pinpoint lubricant oil onto precision machines such as watches and cameras, and micro hemispherical lenses (optical lenses) used in optical communication elements. A liquid ejecting apparatus that ejects a liquid onto the substrate or a liquid ejecting apparatus that ejects an etching solution such as an acid or an alkali to etch the substrate may be employed. The present invention can be applied to any one of these injection devices.

  Moreover, in the said embodiment, although the roll paper 2 was mentioned as an example and demonstrated as a strip | belt-shaped medium, it is not limited to this, For example, a strip | belt-shaped film and a strip | belt-shaped cloth may be sufficient.

  In the above embodiment, proportional control (P control) is performed as control of the roll paper 2. However, integral control (I control) and differential control (D control) are added to the proportional control (P control). You may combine. As an example, PI control or PID control may be executed as control of the roll paper 2.

  Further, in the above embodiment, the paper edge position detection sensor 50a having a function of detecting the paper edge position in the width direction of the roll paper 2 is taken as an example of the acquisition unit that acquires the width direction position where the roll paper 2 is located. Although described above, the present invention is not limited to this. For example, a sensor that directly detects the position in the width direction where the roll paper 2 is located instead of the paper edge position may be used, or a sensor that directly detects the degree of deviation from the reference position of the position in the width direction where the roll paper 2 is located. There may be.

  Further, the controller 60 may change the proportional gain K according to the type of the roll paper 2 instead of setting the proportional gain K of the proportional control to a fixed value.

  That is, some of the roll paper 2 reacts sensitively to the rotation of the steering unit 20a and changes its position in the width direction, and even if the steering unit 20a rotates (the steering unit 20a of the roll paper 2). Some do not respond sensitively to this rotation (due to slipping, etc.). An example of the former can be a thin and soft paper, and an example of the latter can be a thick and hard paper.

  If the proportional gain K is too large in the control of the roll paper 2 according to the former, the control is not stable due to the occurrence of vibration (that is, vibration), so it is desirable not to increase the proportional gain K too much. On the other hand, if the proportional gain K is too small in the control of the roll paper 2 according to the latter, the followability is poorly controlled. Therefore, there is a situation that it is desirable not to make the proportional gain K too small.

  Therefore, if the proportional gain K is changed in accordance with the type of the roll paper 2, more appropriate proportional control is performed according to the degree of deviation from the reference position of the width direction position where the roll paper 2 is located. It becomes possible.

  An example of a method for realizing the above is as follows. That is, an appropriate proportional gain K is determined in advance for each type of roll paper 2 assumed to be used through experiments. Then, a correspondence table showing the correspondence between the type of the roll paper 2 and the proportional gain K is prepared, and the correspondence table is stored in the memory 63 described above. When the operator of the image recording apparatus 1 inputs information relating to the type of the roll paper 2 to the image recording apparatus 1, the controller 60 that has received the information refers to the correspondence table and inputs the input roll paper 2 The proportional gain K corresponding to the type of the image may be set.

1 image recording device, 2 roll paper, 10 feeding unit,
18 roll axis, 19 relay roller,
20 transport unit, 20a steering unit,
21 relay roller, 22 relay roller,
23 1st conveyance roller, 23a 1st drive roller, 23b 1st driven roller,
24 second conveying roller, 24a second driving roller, 24b second driven roller,
25 reversing roller, 26 relay roller,
27 feed roller, 29 platen, 30 head unit,
31 head, 34 valve unit, 35 flushing unit,
40 carriage unit, 41 guide rail, 42 carriage,
50 detector groups, 50a paper edge position detection sensor,
60 controller, 61 interface, 62 CPU,
63 memory, 64 unit control circuit, 70 heater unit,
80 blower unit, 81 fan, 90 take-up unit,
91 relay roller, 92 winding drive shaft,
110 host computers, 200 bases,
201 first roller, 201a central axis,
202 second roller, 202a central axis,
203 base member, 203a rotating shaft,
204 eccentric cam, 204a central axis,
205 motor, 205a drive shaft, 205b coupling,
205c transmission shaft, 205d bearing, 206 worm,
207 Worm wheel, 207a Central axis, 208 Cam follower,
209 Coil spring, 209a L-shaped bracket, 209b L-shaped bracket,
210 movable support part, 210a L-shaped bracket, 210b wheel,
211 regulating member, 502 light emitting part, 504 light receiving sensor part

Claims (3)

A transport unit for transporting a belt-shaped medium;
An acquisition unit for acquiring a position in the width direction where the belt-like medium is located;
A steering unit that changes the position in the width direction of the belt-like medium by rotating;
A controller that performs proportional control of the rotation angle of the steering unit per unit transport amount of the belt-shaped medium according to the degree of deviation from the reference position of the width direction position;
A belt-shaped medium transporting device characterized by comprising: In the belt-shaped medium conveyance device according to claim 1,
The band-shaped medium transporting apparatus, wherein the controller changes a proportional gain of the proportional control according to a type of the band-shaped medium. Obtaining the position in the width direction where the belt-like medium is located;
Proportional control of the rotation angle of the steering unit that changes the position in the width direction of the band-shaped medium by rotating per unit transport amount of the band-shaped medium according to the degree of deviation from the reference position of the width direction position. And doing
A method for controlling a belt-like medium, comprising:

Images