JP2016028983A - Control method for recording apparatus, and recording apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control method for a recording apparatus, which enables a long target transported while being supported along a transport route to be securely put into a stretched state along the transport route, and to provide a recording apparatus.SOLUTION: There is provided a control method for a recording apparatus including support means for supporting a target, recording means, a first drive roller around which the target is wound, a second drive roller around which the target is wound. When the target is transported, the first drive roller is driven by rotation amount control, the second drive roller is driven by torque control based on first through fourth management torque values, the fourth management torque values T1, T2, T3,and T4 are set to be lower than the first management torque value T1 applied when transportation of the target is stopped, the second management torque value T2 is set to be higher than the first management torque value T1, and the third management torque value T3 is set to be higher than the first management torque value T1 and lower than the second management torque value T2.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a recording apparatus control method and a recording apparatus.

  In general, an ink jet printer (hereinafter also referred to as “printer”) is widely known as a recording apparatus that performs a recording process on a target. Further, in recent years, by using such a printer, a large number of unit images that are later cut out and used as labels are continuously printed on a long continuous paper (target), for example, on a wrap film of fresh food. A technique for printing a label to be worn in a small lot has been proposed (see, for example, Patent Document 1).

  The printer described in Patent Document 1 includes a platen that supports an area on a continuous sheet where a recording process is performed along a conveyance path along the length direction of the continuous sheet, and an upstream of the continuous sheet in the conveyance direction of the continuous sheet. A transport roller unit disposed on the side and in the vicinity of the platen, and an auxiliary transport roller unit disposed on the downstream side of the platen in the transport direction of the continuous paper and in the vicinity of the platen. ing. The two conveying roller units are connected to each other via an endless belt, and are connected to each other on the basis of a driving force transmitted from the belt power transmission mechanism to the endless belt in a state where continuous paper is wound around each end position. It is designed to rotate in synchronization.

  The auxiliary transport roller unit is configured to have a smaller rotation diameter than the transport roller unit. Therefore, in this printer, when the continuous paper is transported for the recording process, the auxiliary transport roller unit is rotationally driven so as to have a slightly higher speed than the transport roller unit. As a result, tension is applied to the continuous paper supported on the platen.

JP 2007-313663 A

  By the way, in the printer described in Patent Document 1, tension is applied to the continuous paper from both the transport roller units by providing a speed difference between the rotational speeds of the both transport roller units. However, since this printer does not monitor the tension applied to the continuous paper from both transport roller units, it can be determined how much tension is actually applied to the continuous paper from both transport roller units. I couldn't figure it out. For this reason, in this printer, for example, there is a possibility that the continuous paper transported while being supported on the platen cannot be reliably stretched along the transport path due to differences in temperature conditions.

  The present invention has been made in view of such circumstances, and has been made in view of such circumstances. The object of the present invention is a long shape that is conveyed while being supported along a conveyance path. It is an object of the present invention to provide a recording apparatus control method and a recording apparatus that can reliably place a target along a conveyance path.

  In order to solve the above-described problems, a control method for a recording apparatus according to the present invention includes: a support unit that supports a long target along a conveyance path along a length direction of the target; and the support unit supports the long target. A recording unit that performs a recording process on the target in a state in which the target is placed; a first drive roller that winds the target at a position in the vicinity of the upstream end of the support unit on the transport path; and the first drive A first transport motor for driving the roller; a second drive roller for winding the target at a position near the downstream end of the support means on the transport path; and a second transport motor for driving the second drive roller. A method of controlling the recording apparatus, wherein the first drive roller is moved to the first transport motor when the target is transported. And using the second transport motor to drive the second driving roller with a management torque value based on the first, second, third, and fourth torque management values, Is a management torque value corresponding to when the target is not transported, and the second management torque value is an acceleration period in which the first transport motor performs an acceleration operation up to a predetermined speed when the target transport operation is started. The third management torque value corresponds to a management torque value corresponding to a constant speed rotation period during which the first transfer motor rotates at a constant speed during the target transfer operation, The management torque value is a management torque value corresponding to a deceleration period in which the first conveyance motor performs a deceleration operation when the conveyance operation of the target is finished, and the fourth The management torque value is set lower than the first management torque value, the second management torque value is set higher than the first management torque value, and the third management torque value is It is set higher than the first management torque value and lower than the second management torque value, and the non-conveyance time includes a printing operation time.

  According to the control method of the recording apparatus of the present invention, the tension applied to the target conveyed on the conveyance path by controlling the driving of the second drive roller based on the first to fourth management torque values. It is possible to appropriately adjust the size of. Therefore, the long target conveyed while being supported along the conveyance path can be in a state of being stretched with a predetermined tension along the conveyance path. In addition, since the target is transported in a state where a predetermined tension is applied, no load is applied to the target, and it is possible to prevent slippage or the like from being generated between the driving roller and the target. Can be accurately controlled.

In the control method of the recording apparatus, the second management torque value corresponds to an acceleration period in which the rotation speed of the first drive roller is increased when starting the conveyance of the target. In the period, it is preferable to start the rotation of the second driving roller earlier than the timing at which the first driving roller starts to rotate.
According to this configuration, since the second driving roller starts rotating earlier than the timing at which the first driving roller starts rotating, torque generated by the length of the support means between the first driving roller and the second driving roller. Transmission delay can be eliminated. Therefore, the feeding operation by the first driving roller can be performed in a state where the torque of the second driving roller is transmitted to the target. Therefore, it is possible to prevent the target from becoming slack at the start of conveyance.

In the control method of the recording apparatus, the fourth management torque value corresponds to a deceleration period in which the rotation speed of the first drive roller is decreased when the conveyance of the target is finished. In the period, it is preferable that the first drive roller starts decelerating earlier than the timing at which the second drive roller switches from the third management torque value to the rotational drive by the fourth management torque value.
According to this configuration, since the first drive roller starts the deceleration operation earlier than the timing at which the second drive roller switches from the third management torque value to the rotational drive by the fourth management torque value, It is possible to prevent the conveyance speed difference from occurring between the second drive roller and the target, and to terminate the conveyance operation without causing the target to be slack.

  The recording apparatus of the present invention includes a supporting unit that supports a long target along a conveyance path along a length direction of the target, and a recording process for the target that is supported by the supporting unit. Recording means for applying, a first drive roller for winding the target at a position in the vicinity of the upstream end of the support means on the transport path, a first transport motor for driving the first drive roller, and the transport A recording apparatus comprising: a second drive roller that winds the target at a position near a downstream end of the support means on the path; and a second transport motor that drives the second drive roller, When the recording apparatus transports the target, the recording apparatus drives the first driving roller by rotation amount control using the first transport motor. And a drive control unit that drives the second drive roller with a management torque value based on the first, second, third, and fourth torque management values using the second transport motor, and the first management torque The value corresponds to a management torque value corresponding to the time when the target is not transported, and the second management torque value corresponds to an acceleration period in which the first transport motor performs an acceleration operation up to a predetermined speed when the target transport operation is started. The management torque value and the third management torque value are a management torque value and a fourth management torque value corresponding to a constant speed rotation period in which the first transfer motor rotates at a constant speed during the target transfer operation. Is a management torque value corresponding to a deceleration period during which the first transport motor performs a deceleration operation when the target transport operation ends, and the fourth management torque value The second management torque value is set to be lower than the first management torque value, the second management torque value is set to be higher than the first management torque value, and the third management torque value is set to the first management torque value. It is set higher than the torque value and lower than the second management torque value, and the non-conveyance time includes a printing operation time.

  According to the recording apparatus of the present invention, the control unit controls the driving of the second drive roller based on the first to fourth management torque values, so that the tension applied to the target transported on the transport path. It is possible to appropriately adjust the size of. Therefore, similarly to the above control method, it is possible to prevent a positional deviation such as a slip between the driving roller and the target without applying a load to the target, and to accurately perform the position control based on the transport amount of the target. it can.

1 is a schematic front view of a printer according to an embodiment. Sectional drawing of the platen of this embodiment. FIG. 3 is a block diagram of a control configuration of the printer according to the embodiment. 5 is a flowchart illustrating a processing routine related to printing processing and conveyance processing. The flowchart which shows the process routine regarding a conveyance process. The figure which shows the timing chart of a 1st drive roller and a 2nd drive roller.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, an embodiment in which a recording apparatus of the invention is embodied in an ink jet printer (hereinafter referred to as a “printer”) will be described with reference to the drawings. 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.

  As shown in FIG. 1, a printer 11 as a recording apparatus according to the present embodiment sequentially prints on a continuous paper 12 fed out from a long continuous paper 12 as a target, and the continuous paper 12 fed out from the feeding part 13. And a winding unit 15 that winds the continuous paper 12 that has been printed (recorded) by the main body unit 14. The main body 14 includes a rectangular parallelepiped main body case 16. A feeding unit 13 is disposed on the left side of the main body case 16 on the upstream side in the conveyance direction of the continuous paper 12. A winding unit 15 is disposed on the right side of the main body case 16 on the downstream side in the conveyance direction of the continuous paper 12.

  The feeding portion 13 includes a support plate 17 that extends leftward from the lower end portion of the left surface of the main body case 16. A winding shaft 18 extending toward the front (the front side in the direction orthogonal to the paper surface in FIG. 1) is supported at the left end portion of the support plate 17 so as to be rotatable with respect to the support plate 17. Further, the continuous paper 12 previously wound in a roll shape is supported on the winding shaft 18 so as to be rotatable integrally with the winding shaft 18.

  Further, the feeding portion 13 includes a flat plate-like feeding stand 19 that extends horizontally from the center of the left surface of the main body case 16 toward the left. A relay roller 20 for rotating the continuous paper 12 fed from the winding shaft 18 and guiding it to the upper surface of the feeding table 19 is rotatably provided at the leading end of the feeding table 19. Then, the continuous paper 12 is conveyed toward the right side (main body part 14 side) along the upper surface of the feeding table 19.

  A flat plate-like base 21 that divides the inside of the main body case 16 vertically is provided at a position slightly above the central portion in the vertical direction in the main body case 16 of the main body portion 14. An area above the base 21 in the main body case 16 is a printing chamber 22 for printing on the continuous paper 12.

  On the left wall of the main body case 16, an unillustrated entrance for carrying the continuous paper 12 into the main body case 16 from the upper surface of the feeding table 19 is provided. And the relay roller 23 is rotatably provided in the main-body part 14 so that it may oppose the said carrying-in port in the vicinity position.

  A relay roller 24 is rotatably provided in the main body case 16 at an obliquely lower right side of the relay roller 23. Then, after the continuous paper 12 is carried into the main body case 16, the continuous paper 12 is wound around the relay roller 24 from the upper left side and conveyed toward the position near the left end of the printing chamber 22.

  A first transport roller pair 25 that sandwiches the continuous paper 12 and applies transport force is provided at a position near the left end of the printing chamber 22. The first transport roller pair 25 is connected to a first drive roller 25a connected to a first transport motor (see FIG. 3) so as to be able to transmit power, and the continuous paper 12 is sandwiched between the first drive roller 25a. It is comprised by the 1st driven roller 25b arrange | positioned so that it may oppose. Then, the continuous paper 12 wound around the first drive roller 25a from the lower left is conveyed horizontally in the printing chamber 22 from the first conveyance roller pair 25 in the right direction as the first drive roller 25a is driven to rotate. It has come to be. Further, a platen (supporting means) 28 is provided in a region on the right side of the first conveying roller pair 25 in the printing chamber 22. That is, the first transport roller pair 25 is provided in the vicinity of the upstream end of the platen 28.

  As shown in FIG. 2, the platen 28 is provided in a state where a support base 28 a having a substantially box shape with a bottom having an open top surface is supported by the base 21. Then, above the support base 28a, a short plate-like mounting plate 28b is brought into contact with the continuous paper 12 so as to close the opening on the upper side of the support base 28a. Is provided.

  The mounting plate 28b is formed with a number of through holes 5 (only five are shown in FIG. 1) penetrating the mounting plate 28b in the vertical direction (the thickness direction of the mounting plate 28b). An exhaust port 6 is formed in the left side wall portion of the support base 28a, and a suction fan 29 as a suction means is connected through the exhaust port 6. When the suction fan 29 is rotationally driven in accordance with the rotational drive of the suction fan motor (see FIG. 3), the air in the space enclosed between the support base 28a and the mounting plate 28b is The air is exhausted outside through the suction fan 29. That is, the space surrounded between the support base 28 a and the mounting plate 28 b is a negative pressure chamber 31 that generates a negative pressure based on the driving of the suction fan 29.

  Further, when a negative pressure is generated in the negative pressure chamber 31 as the suction fan 29 is driven, the negative pressure is similarly applied to the through hole 5 of the mounting plate 28 b communicating with the negative pressure chamber 31. . Therefore, the through-hole 5 of the mounting plate 28b functions as a suction hole that applies an adsorption force to the continuous paper 12 conveyed on the support surface PL of the platen 28. The negative pressure chamber 31 is provided with a pressure detection sensor 32 that detects a pressure change in the negative pressure chamber 31 due to the rotational drive of the suction fan 29.

Further, as shown in FIG. 1, a second conveyance roller pair 33 that sandwiches the continuous paper 12 and applies a conveyance force is provided in a region on the right side of the platen 28 in the printing chamber 22. That is, the second transport roller pair 33 is provided in the vicinity of the downstream end of the platen 28.
The second transport roller pair 33 includes a second drive roller 33a connected to a second transport motor (see FIG. 3) 34 so that power can be transmitted, and the continuous paper 12 sandwiched between the second drive roller 33a. It is comprised by the 2nd driven roller 33b arrange | positioned so that it may oppose.

  The continuous paper 12 conveyed in the horizontal right direction on the support surface PL of the platen 28 from the first conveying roller pair 25 is wound around the second driving roller 33a from the upper left side. The transport direction of the continuous paper 12 is changed from the horizontal right direction to the vertical downward direction. Further, the continuous paper 12 is conveyed vertically downward through an insertion hole (not shown) provided in the base 21 after the conveyance direction is changed vertically downward by the second drive roller 33a. The upper surface of the second drive roller 33a is flush with the upper surface of the first drive roller 25a and the support surface PL of the platen 28. In addition, the second driven roller 33 b is configured to abut only on the edge portion in the width direction (front-rear direction) on the printing surface of the continuous paper 12.

  Guide rails 35 (indicated by a two-dot chain line in FIG. 1) extending in the left-right direction are provided on both the front and rear sides of the platen 28 in the printing chamber 22 so as to form a pair. Note that the upper surface of the guide rail 35 is higher than the support surface PL of the platen 28. A short plate-like carriage 35 a is supported on the upper surfaces of both guide rails 35 so as to be capable of reciprocating in the left-right direction along both guide rails 35.

  A recording head 36 as recording means is supported on the lower surface of the carriage 35a. A large number of ink discharge nozzles (not shown) are arranged in the front-rear direction on the lower surface of the recording head 36. A valve unit 37 for temporarily storing ink is provided on the upper wall of the main body case 16 in the printing chamber 22. The valve unit 37 is connected to the recording head 36 via an ink supply tube (not shown). The recording head 36 performs printing by ejecting the ink supplied from the valve unit 37 toward the surface of the continuous paper 12 that has been transported from the ink discharge nozzle onto the platen 28 and stopped. It has become.

  Therefore, an area from the left end to the right end of the platen 28 in the middle of the conveyance path of the continuous paper 12 is a printing area R in which printing is performed on the continuous paper 12 by ink ejection from the ink discharge nozzles. Yes. The continuous paper 12 is intermittently transported along the transport path in units of areas corresponding to the print areas R.

  The continuous paper 12 wound around the second drive roller 33a and conveyed vertically downward is a reversing roller rotatably disposed at a position below the second drive roller 33a in the main body case 16. 38 is wound from above the left side and conveyed slightly diagonally upward to the right. Then, the continuous paper 12 conveyed from the reversing roller 38 is wound around the relay roller 39 provided to be rotated to the right of the reversing roller 38 in the main body case 16 from the lower left side, and the main body case 16 is passed through the main body case 16. It is conveyed upward along the right wall of 16. The continuous paper 12 that has been printed in the printing region R is naturally dried in the process of being conveyed through the main body case 16.

  In addition, an unillustrated unloading port for unloading the continuous paper 12 toward the take-up unit 15 is provided at a position near the base 21 on the right wall of the main body case 16. Further, a delivery roller 40 is rotatably provided at a position facing the carry-out port in the vicinity of the carry-out port in the main body case 16. The feed roller 40 feeds the continuous paper 12 to the take-up portion 15 side through the carry-in port.

  The winding unit 15 includes a rectangular parallelepiped winding frame 41. A relay roller 42 is rotatably provided at the upper end of the winding frame 41. Then, the continuous paper 12 sent out from the carry-in port is wound around the relay roller 42 from the upper left side and is conveyed obliquely downward to the right.

  A winding drive shaft 43 extending toward the front is supported on the winding frame 41 so as to be rotatable with respect to the winding frame 41. The continuous paper 12 conveyed from the relay roller 42 toward the lower right is wound around the winding drive shaft 43. The continuous paper 12 is wound up sequentially as the winding drive shaft 43 rotates.

Next, a control configuration in the printer 11 of the present embodiment will be described.
As shown in FIG. 3, the printer 11 is provided with a controller (drive control unit) 44 that controls the drive state of the entire apparatus. The controller 44 includes a CPU 45, a ROM 46, and a RAM 47 serving as a central processing unit. The ROM 46 stores processing routine programs and the like related to the printing process and the conveyance process shown in the flowcharts of FIGS. The RAM 47 temporarily stores the calculation result of the CPU 45 or temporarily stores print data input from the external input device 48.

  The controller 44 is connected to the recording head 36 via a head driver 49. The controller 44 reads out the print data input from the external input device 48 from the RAM 47 and transmits the read print data to the head driver 49. The head driver 49 ejects ink droplets from the ink ejection nozzles of the recording head 36 based on the print data received from the controller 44.

  The controller 44 controls driving of the first transport motor 26 via the first transport motor driver 50. Then, the first drive roller 25a moves the continuous paper 12 downstream in the transport direction until the predetermined transport amount based on the rotation amount of the first transport motor 26 is reached as the first transport motor 26 rotates. It is designed to be transported towards.

  The controller 44 is connected to a rotation amount detection sensor 51 that detects the rotation amount of the first transport motor 26. Then, the controller 44 feedback-controls the rotation amount of the first transport motor 26 via the first transport motor driver 50 based on the detection result of the rotation amount of the first transport motor 26 received from the rotation amount detection sensor 51. It has become. That is, the first transport motor 26 functions as a first drive unit that drives the first drive roller 25a by controlling the rotation amount. In the present embodiment, a rotary potentiometer that detects the rotation angle of the first transport motor 26 is used as the rotation amount detection sensor 51.

  Further, the controller 44 drives and controls the second transport motor 34 via the second transport motor driver 52. The second drive roller 33 a is configured to apply a predetermined tension based on the torque of the second transport motor 34 to the continuous paper 12 as the second transport motor 34 rotates.

  The controller 44 is connected to a torque detection sensor 53 that detects the torque of the second transport motor 34. The controller 44 feedback-controls the torque of the second transport motor 34 via the second transport motor driver 52 based on the torque detection result of the second transport motor 34 received from the torque detection sensor 53. Yes. That is, the second transport motor 34 functions as a second drive unit that drives the second drive roller 33a by torque control.

  In general, since a motor has a substantially proportional relationship between torque and current, the magnitude of the current is determined according to the load of the motor if the rotation speed of the motor is constant. That is, the magnitude of the current required for driving the motor is determined according to the load applied to the roller. Therefore, the magnitude of the load applied to the motor can be detected by detecting the magnitude of the current flowing through the motor. Therefore, in the present embodiment, a current sensor that detects the magnitude of the current flowing through the second transport motor 34 is used as the torque detection sensor 53.

  Further, the controller 44 drives and controls the suction fan motor 30 via the suction fan motor driver 54. As the suction fan motor 30 rotates, the suction fan 29 depressurizes the negative pressure chamber 31 with a predetermined suction force based on the rotation speed of the suction fan motor 30. As a result, the negative pressure in the negative pressure chamber 31 acts on the continuous paper 12 as an adsorption force with respect to the support surface PL of the platen 28 through the through hole 5 of the mounting plate 28b.

  Next, conveyance control and printing control in the printer 11 configured as described above will be described with reference to FIGS. The controller 44 performs conveyance control and print control in the printer 11 by reading a program of a processing routine related to the conveyance process and the printing process from the ROM 46 and executing the program. In this embodiment, print data for the continuous paper 12 by the recording head 36 is input in advance from the external input device 48 to the RAM 47 before the controller 44 executes the processing routine program relating to the conveyance process and the print process. It shall be.

  As shown in FIG. 4, first, in step S10, the controller 44 sets the suction force in the negative pressure chamber 31 by the suction fan 29 to F1 by setting the rotation speed of the suction fan motor 30.

  Next, in step S <b> 11, the controller 44 transmits a control command signal to the suction fan motor driver 54. Then, the suction fan 29 starts to rotate with the rotation of the suction fan motor 30, thereby generating a negative pressure in the negative pressure chamber 31. As a result, an attracting force acts on the continuous paper 12 on the support surface PL of the platen 28 from the inside of the negative pressure chamber 31 through the through hole 5 of the mounting plate 28b. In this case, the continuous paper 12 is sucked onto the support surface PL of the platen 28 with a second suction force that is substantially equal to the suction force F1 of the suction fan 29.

  The suction force of the suction fan 29 is such that the continuous paper 12 does not stick firmly to the support surface PL of the platen 28 so as not to hinder the conveyance of the continuous paper 12 by the first drive roller 25a. Is set to the size of Therefore, the tension is surely applied to the continuous paper 12 on the support surface PL of the platen 28 from the second drive roller 33a. Therefore, the second drive roller 33a is a tension that acts on the continuous paper 12 as described later. Can be adjusted with high accuracy. Further, since the attractive force acting on the continuous paper 12 from the support surface PL of the platen 28 becomes low, the driving loads of the first transport motor 26 and the second transport motor 34 when the continuous paper 12 is transported may be excessive. It is to be avoided.

  Subsequently, in step S <b> 12, the controller 44 sucks the pressure in the negative pressure chamber 31 as the suction fan 29 is driven based on the detection signal from the pressure detection sensor 32 provided in the negative pressure chamber 31. It is determined whether or not the pressure has been reduced to a pressure value substantially equal to the suction force F1 of the fan 29.

  If the determination result in step S12 is affirmative (pressure in the negative pressure chamber 31 = F1), the controller 44 reduces the pressure by the suction fan 29 until the pressure in the negative pressure chamber 31 reaches a desired pressure value. It is determined that the transfer has been completed, and the process proceeds to the transport operation (step S13).

  On the other hand, when the determination result in step S <b> 12 is negative (pressure in the negative pressure chamber 31 ≠ F <b> 1), the controller 44 determines that the pressure reduction in the negative pressure chamber 31 by the suction fan 29 is not completed. Then, the controller 44 continues the pressure reduction in the negative pressure chamber 31 by the suction fan 29 so that the pressure in the negative pressure chamber 31 is reduced to a desired pressure value.

  The transport operation (step S13) includes steps S21 to S27 as shown in FIG. In the present embodiment, when the continuous paper 12 is transported, the controller 44 drives the first drive roller 25a by the rotation amount control using the first transport motor 26 and the second drive using the second transport motor 34. Management torque value (first management torque value) T1, management torque value (second management torque value) T2, management torque value (third management torque value) T3, management torque value (fourth) The control torque value) is driven by torque control based on T4.

  The management torque value T1 is the magnitude of the tension that the second transport motor 34 acts on the continuous paper 12 when the transport operation is not performed. In this case, the second drive roller 33a is not performing the rotation operation. The management torque values T2 and T3 are set higher than the management torque value T1, and the management torque value T2 is set higher than the management torque value T3. The management torque value T4 is set lower than the management torque value T1. In the period corresponding to the management torque values T2 to T4, the second drive roller 33a is rotating.

  FIG. 6 is a timing chart of the first driving roller 25a driven by the rotation amount control and the second driving roller 33a driven by the torque control. The horizontal axis in FIG. 6 represents the time axis, and the vertical axis in FIG. The axis represents the change in the rotation speed of the first drive roller 25a and the change in the management torque value of the second drive roller 33a. An area indicated by A in FIG. 6 indicates an acceleration period in which the first transport motor 26 performs an acceleration operation to a predetermined speed when the transport operation of the continuous paper 12 is started. Further, an area indicated by B in the figure indicates a deceleration period during which the first transport motor 26 performs a deceleration operation when the transport operation of the continuous paper 12 is finished. Note that, during the acceleration period A and the deceleration period B, a constant speed rotation period C in which the first transport motor 26 rotates at a constant speed during the transport operation of the continuous paper 12 is set.

  First, in step S21, the controller 44 sets the magnitude of the tension applied to the continuous paper 12 from the second drive roller 33a by setting the management torque value of the second transport motor 34 from T1 to T2. The management torque value T2 corresponds to an acceleration period in which the rotation speed of the first transport motor 26 is increased when the transport operation of the continuous paper 12 is started as will be described later. The management torque value T2 of the second transport motor 34 is such that the magnitude of the tension that the second drive roller 33a applies to the continuous paper 12 on the platen 28 based on the torque of the second transport motor 34 is continuous during transport. The size is set so as to sufficiently suppress the flapping of the paper 12.

  After setting the management torque value of the second transport motor 34 to T2 and rotating the second drive roller 33a, the controller 44 starts an acceleration operation for increasing the rotational speed of the first transport motor 26 in step S22. (Acceleration period A). The controller 44 can detect the rotation amount of the first conveyance motor 26 based on the detection signal from the rotation amount detection sensor 51 and detect the rotation speed of the first conveyance motor 26. As a result, the controller 44 continues to accelerate the first transport motor 26 until the rotational speed reaches a predetermined value as shown in FIG.

  In the present embodiment, as shown in FIG. 6, in the acceleration period A, the second drive roller 33a starts to rotate by ΔA earlier than the timing at which the first drive roller 25a starts to rotate. Specifically, the rotation of the second drive roller 33a is started as ΔA earlier by several milliseconds (for example, 3 to 5 milliseconds).

  According to this configuration, it is possible to eliminate a delay in torque transmission that occurs by the length of the platen 28 between the first drive roller 25a and the second drive roller 33a. Therefore, the feeding operation by the first drive roller 25a can be performed in a state where the torque of the second drive roller 33a is transmitted to the continuous paper 12. Therefore, it is possible to prevent the continuous paper 12 from being slackened during the transport operation.

  When the rotational speed of the first transport motor 26 reaches a predetermined value, the controller 44 rotates the first transport motor 26 at a low speed and sets the management torque value of the second transport motor 34 from T2 to T3 in step S23. The magnitude of tension applied to the continuous paper 12 from the second drive roller 33a is reduced. Furthermore, the controller 44 switches to constant speed rotation in which the rotation speed of the first transport motor 26 is kept constant (constant speed rotation period C). The management torque value T3 is set lower than the management torque value T2 during the acceleration period A and higher than the management torque value T1 when the continuous paper 12 is not transported as described above. It is possible to prevent a load from being applied to the continuous paper 12 due to excessive tension applied to the paper 12.

  In the present embodiment, when the continuous paper 12 is transported, the controller 44 monitors the rotation amount of the first drive roller 25 a as needed based on the detection signal from the rotation amount detection sensor 51 and detects the detection signal from the torque detection sensor 53. The magnitude of the tension acting on the continuous paper 12 from the second drive roller 33a is monitored as needed, and further, the negative pressure associated with the rotational drive of the suction fan 29 based on the detection signal from the pressure detection sensor 32. The pressure change in the chamber 31 is monitored as needed.

  And the controller 44 is based on the control signal which the drive state (rotation amount, tension | tensile_strength, suction | attraction force) of the 1st drive roller 25a, the 2nd drive roller 33a, and the suction fan 29 is transmitted from each driver 50, 52, 54. When a deviation occurs with respect to the driving conditions specified in the above, error notification is performed. That is, the controller 44 monitors from time to time whether the first drive roller 25a, the second drive roller 33a, and the suction fan 29 are operating normally based on control signals transmitted from the drivers 50, 52, and 54. Therefore, the reliability of the operation of the apparatus can be improved.

  In the present embodiment, the suction force F1 of the suction fan 29 and the management torque values T1 to T4 of the second transport motor 34 are arbitrarily changed based on data input to the controller 44 from the external input device 48. It is possible. Therefore, by setting the suction force F1 of the suction fan 29 to be smaller, the management torque values T2, 3 of the second transport motor 34 are set to be smaller within a range in which the flapping of the continuous paper 12 during transport can be suppressed. Is possible. Then, by setting the management torque values T2 and T3 of the second transport motor 34 to be smaller, the driving load of the second transport motor 34 is reduced, so that the second transport motor 34 can be prevented from being overheated. At the same time, it becomes possible to save energy of the entire apparatus.

  In step S24, the controller 44 detects the rotation amount of the first conveyance motor 26 based on the detection signal from the rotation amount detection sensor 51, and determines the conveyance amount of the continuous paper 12 by the first drive roller 25a from this rotation amount. To detect. Then, it is determined whether or not the rotation amount of the first transport motor 26 has reached a predetermined value.

  If the determination result in step S16 is negative (rotation amount of the first transport motor ≠ predetermined value), the controller 44 determines to continue transporting the continuous paper 12 by the first drive roller 25a. And the controller 44 continues conveyance of the continuous paper 12 by the 1st drive roller 25a until the conveyance amount of the continuous paper 12 by the 1st drive roller 25a becomes a predetermined conveyance amount.

  On the other hand, if the determination result in step S16 is affirmative (rotation amount of the first transport motor 26 = predetermined value), the controller 44 proceeds to step S26. In step S25, the controller 44 starts a decelerating operation for decelerating the first transport motor 26 that rotates at a constant speed.

  After starting the deceleration operation of the first transport motor 26, in step S26, the controller 44 sets the management torque value of the second transport motor 34 from T3 to T4 corresponding to the deceleration period B, whereby the second drive roller The magnitude of the tension applied to the continuous paper 12 from 33a is set. The management torque value T4 of the second transport motor 34 is such that the magnitude of the tension that the second drive roller 33a acts on the continuous paper 12 on the platen 28 based on the torque of the second transport motor 34 is continuous during the transport. The size is set so as to sufficiently suppress the flapping of the paper 12.

  In the present embodiment, as shown in FIG. 6, during the deceleration period B, the deceleration operation of the first drive roller 25a is performed by ΔB rather than the timing at which the second drive roller 33a switches the management torque value from T3 to T4. I try to start early. Specifically, as ΔB, the deceleration operation of the first drive roller 25a is started as early as several milliseconds (for example, 3 to 5 milliseconds).

  According to this configuration, it is possible to prevent the conveyance speed difference from occurring in the continuous paper 12 between the first drive roller 25a and the second drive roller 33a, and to terminate the conveyance operation without causing slack in the target. Can do.

  The controller 44 detects the rotation speed of the first transport motor 26 based on the detection signal from the rotation amount detection sensor 51, and confirms the rotation stop of the first drive roller 25a. Then, the process proceeds to step S27. In step S27, after detecting that the rotation of the first drive roller 25a has stopped, that is, the conveyance operation of the continuous paper 12 has been completed, the controller 44 sets the management torque value of the second conveyance motor 34 from T4 to T1, The magnitude of the tension applied to the continuous paper 12 from the second drive roller 33a is reduced. Thereby, it is possible to prevent the continuous paper 12 from being excessively tensioned and being loaded. In addition, the driving load of the second transport motor 34 that rotationally drives the second drive roller 33a is reduced, and energy saving of the entire apparatus can be achieved.

  The transport operation (step S13) is completed through steps S21 to S27. After the conveyance operation is completed, the process proceeds to step S14, and a printing process described later is performed.

  In step S <b> 14, the controller 44 sets the rotation speed of the suction fan motor 30 to change the suction force for sucking the negative pressure chamber 31 by the suction fan 29 to F <b> 2. Note that the suction force F2 of the suction fan 29 is set to be larger than the suction force F1 of the suction fan 29 set in step S10. The continuous paper 12 is sucked onto the support surface PL of the platen 28 with a first suction force substantially equal to the suction force F2 of the suction fan 29. That is, the suction fan 29 adsorbs the continuous paper 12 to the support surface PL of the platen 28 with a first adsorbing force when the printing process is executed, and has a second adsorbing force smaller than the first adsorbing when the carrying process is executed. The continuous paper 12 is attracted to the support surface PL of the platen 28.

  Next, in step S <b> 15, the controller 44 transmits a control command signal to the suction fan motor driver 54. Then, by changing the rotation speed of the suction fan motor 30, the negative pressure generated in the negative pressure chamber 31 changes as the suction fan 29 is driven. As a result, the continuous paper 12 on the support surface PL of the platen 28 is attracted onto the support surface PL of the platen 28 with an adsorption force substantially equal to the suction force F2 of the suction fan 29. In this case, the continuous paper 12 in a state where the conveyance is stopped is subjected to a relatively large adsorption force on the support surface PL of the platen 28, so that the continuous paper 12 is displaced on the support surface PL of the platen 28. Almost never.

  In this embodiment, the controller 44 increases the magnitude of the suction force of the suction fan 29 to F2 in step S14, and then decreases the management torque value of the second transport motor 34 to T2 in step S19. That is, since the suction force of the suction fan 29 is increased in a state where the tension applied to the continuous paper 12 from the second drive roller 33a is relatively large, the continuous paper 12 can maintain the platen while maintaining high flatness. Adsorbed on the 28 support surfaces PL. Therefore, even if the magnitude of the tension acting on the continuous paper 12 from the second drive roller 33a is reduced, the continuous paper 12 is firmly adsorbed on the support surface PL of the platen 28. There is almost no displacement on the support surface PL of the platen 28.

  Subsequently, in step S16, the controller 44 performs a printing process. Specifically, the controller 44 reads print data for the continuous paper 12 from the RAM 47 and transmits the read print data to the head driver 49. Then, the head driver 49 starts a printing operation on the continuous paper 12 by ejecting ink from the ink discharge nozzles of the recording head 36 onto the continuous paper 12 supported on the support surface PL of the platen 28. That is, the recording head 36 is configured to execute a printing process on the continuous paper 12 between each rotation operation of the first drive roller 25a intermittently performed by the first transport motor driver 50.

  After the printing operation on the continuous paper 12 by the recording head 36 is completed, the controller 44 proceeds to step S17. The controller 44 determines whether or not to continue the printing process for the continuous paper 12 in step S17. If the controller 44 determines that the printing process for the continuous paper 12 is continued in step S17, the controller 44 proceeds to step S10 and recursively executes the processes from step S10 to step S16. On the other hand, if it is determined in step S17 that the printing process for the continuous paper 12 is not continued, the controller 44 ends the processing routine program relating to the conveyance process and the printing process for the continuous paper 12.

  During the printing operation, the second drive roller 33a continuously applies tension to the continuous paper 12 based on the management torque value T1. That is, the second transport motor driver 52 drives the second drive roller 33a by torque control during the rotation of the first transport motor 26 and during the printing process for the continuous paper 12 by the recording head 36. It is like that. Although the first driving roller 25a is in a state in which the rotation operation is stopped, the first driving roller 25a is continuously in a state in which the continuous paper 12 pulled from the support surface PL of the platen 28 to the downstream side in the transport direction is supported by the second driving roller 33a. A tension is applied to the paper 12. Therefore, during the printing operation, tension is applied from both the upstream side and the downstream side in the conveyance direction of the continuous paper 12 to the continuous paper 12 on the support surface PL of the platen 28 from the first driving roller 25a and the second driving roller 33a. It is supposed to be. Therefore, the recording head 36 can perform a high-quality printing process on the continuous paper 12 in a state where the flatness is maintained.

According to this embodiment, the following effects can be obtained.
(1) In the control method of the printer 11 and the printer 11 according to the above embodiment, the second transport motor 34 drives the second drive roller 33a by torque control based on the first to fourth management torque values T1 to T4. Thus, the magnitude of the tension applied to the continuous paper 12 from the second drive roller 33a can be adjusted. Therefore, the continuous paper 12 conveyed while being supported by the platen 28 can be reliably stretched along the conveyance path. Further, since the continuous paper 12 can be conveyed in a state where a predetermined tension is applied, a load such as a slip between the first and second drive rollers 25a and 33a and the continuous paper 12 is not applied to the continuous paper 12. Misalignment can be prevented and position control when conveying the continuous paper 12 can be performed with high accuracy.

  (2) In the above embodiment, since the second drive roller 33a starts rotating earlier than the timing at which the first drive roller 25a starts rotating, the platen between the first drive roller 25a and the second drive roller 33a. The delay in torque transmission caused by the length of 28 can be eliminated. Therefore, the feeding operation by the first drive roller 25a can be performed in a state where the torque of the second drive roller 33a is transmitted to the continuous paper 12. Therefore, it is possible to prevent the continuous paper 12 from becoming slack at the start of conveyance.

  (3) In the above embodiment, the first drive roller 25a starts the deceleration operation earlier than the timing at which the second drive roller 33a switches from the management torque value T3 to the rotational drive by the management torque value T4. It is possible to prevent the conveyance speed difference from occurring in the continuous paper 12 between the roller 25a and the second drive roller 33a, and to terminate the conveyance operation without causing the continuous paper 12 to be slack.

  (4) In the above-described embodiment, tension is applied to the continuous paper 12 from the second drive roller 33a both when the continuous paper 12 is transported and when the transport is stopped. Therefore, fluttering of the continuous paper 12 is suppressed when the continuous paper 12 is transported, so that the continuous paper 12 can be transported in a stable state, while being transported while being supported by the platen 28 when transporting the continuous paper 12 is stopped. The continuous paper 12 to be stretched can be reliably stretched along the transport path.

  (5) In the above embodiment, when the conveyance of the continuous paper 12 is stopped, tension is applied to the continuous paper 12 from the second drive roller 33a, so that the continuous paper 12 supported by the platen 28 is surely along the conveyance path. Can be stretched. On the other hand, when the continuous paper 12 is transported, the tension acting on the continuous paper 12 from the second drive roller 33a becomes relatively large, so that the flapping of the continuous paper 12 is more reliably suppressed and supported by the platen 28. The continuous paper 12 to be conveyed can be more securely stretched along the conveyance path.

  (6) In the above embodiment, when the conveyance of the continuous paper 12 is stopped, the continuous paper 12 is attracted to the platen 28 as the suction fan 29 is driven, so that the continuous paper 12 supported by the platen 28 is conveyed. It can be set as the state stopped reliably. On the other hand, when the continuous paper 12 is transported, the suction force acting on the continuous paper 12 is relatively reduced as the suction fan 29 is driven. As a result, the continuous paper 12 transported while being supported by the platen 28 can be more reliably stretched along the transport path.

  (7) In the above embodiment, since the continuous paper 12 is stretched along the conveyance path on the platen 28, the recording head 36 has a higher quality than the continuous paper 12 supported on the platen 28. The recording process can be performed.

In addition, this invention is not limited to the said embodiment, In the range which does not deviate from the meaning of this invention, it can change suitably. For example, the above embodiment may be modified as follows.
In the above-described embodiment, an electrostatic adsorption device that electrostatically adsorbs the continuous paper 12 to the support surface PL of the platen 28 may be employed as an adsorbing unit that adsorbs the continuous paper 12 to the support surface PL of the platen 28. Good. In this case, the electrostatic adsorption device causes the continuous paper 12 to be electrostatically adsorbed to the support surface PL of the platen 28 by the first electrostatic adsorption force when the continuous paper 12 is printed, and during the conveyance processing of the continuous paper 12. It is desirable that the continuous paper 12 be electrostatically attracted to the support surface PL of the platen 28 with a second electrostatic attraction force smaller than the first electrostatic attraction force.

  In the above embodiment, a list data of the management torque values T1 and T2 of the second transport motor 34 corresponding to each material of the continuous paper 12 may be stored in the ROM 46 in advance. In this case, the controller 44 reads out the management torque values T1 to T4 of the second transport motor 34 from the ROM 46 in accordance with the material of the continuous paper 12 to be subjected to each process during the conveyance processing and printing processing of the continuous paper 12. The torque of the second drive roller 33a is controlled with the management torque values T1 to T4 of the second transport motor 34.

  In the embodiment described above, an atmosphere release valve that opens the negative pressure chamber 31 to the atmosphere may be provided. In this case, the suction force in the negative pressure chamber 31 by the suction fan 29 is reduced, and at the same time, the degree of decompression in the negative pressure chamber 31 is rapidly reduced by opening the negative pressure chamber 31 to the atmosphere by the atmospheric release valve. It becomes possible.

  In the above embodiment, a flow rate detection sensor for detecting the flow rate of air exhausted from the negative pressure chamber 31 by the suction fan 29 without providing a pressure detection sensor for detecting a pressure change in the negative pressure chamber 31 may be provided. Good. In this case, the controller 44 receives a detection signal from the flow rate detection sensor indicating that the flow rate of the air exhausted from the negative pressure chamber 31 by the suction fan 29 has fallen below a predetermined threshold value. It can be determined that the pressure reduction in the pressure chamber 31 has been completed.

  In the above embodiment, when the printer 11 is in operation, the continuous paper 12 is continuously transported by continuously rotating the first drive roller 25a without setting the rotation amount X of the first transport motor 26. It is good also as composition to do.

In the above embodiment, a long plastic film or the like may be used as the target.
In the above-described embodiment, the recording apparatus is embodied as an ink jet printer. However, the present invention is not limited to this. Other liquids other than ink (liquids in which functional material particles are dispersed or mixed in a liquid, flow such as a gel) It is also possible to embody the present invention in a liquid ejecting apparatus that ejects or ejects (including a solid body). For example, a liquid that ejects a liquid (liquid material) that is dispersed or dissolved in a material such as an electrode material or a color material (pixel material) used for manufacturing a liquid crystal display, an EL (electroluminescence) display, and a surface emitting display. The liquid ejecting apparatus may be a liquid ejecting apparatus that ejects a bio-organic matter used for biochip manufacturing, or a liquid ejecting apparatus that ejects a liquid that is used as a precision pipette and serves as a sample. 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, a liquid ejecting apparatus that ejects an etching solution such as acid or alkali to etch the substrate, and a liquid ejecting that ejects a liquid (fluid) such as a gel (for example, a physical gel) It may be a device. The present invention can be applied to any one of these liquid ejecting apparatuses.

  DESCRIPTION OF SYMBOLS 11 ... Printer (recording apparatus), 12 ... Continuous paper (target), 25a ... 1st drive roller, 26 ... 1st conveyance motor (1st drive means), 28 ... Platen (support means), 33a ... 2nd drive roller 34 ... second transport motor (second drive means), 36 ... recording head (recording means), 44 ... controller (drive control unit), T1 ... first management torque value, T2 ... second management torque value, T3 ... third management torque value, T4 ... fourth management torque value, A ... acceleration period, B ... deceleration period.

Claims (8)

A support means for supporting a long target along a transport path along a length direction of the target, a recording means for performing a recording process on the target in a state supported by the support means, and A first driving roller for winding the target at a position in the vicinity of the upstream end of the supporting means on the conveying path; a first conveying motor for driving the first driving roller; and the supporting means on the conveying path. A control method for a recording apparatus comprising: a second drive roller that winds the target at a position near a downstream end portion; and a second transport motor that drives the second drive roller,
In transporting the target,
The first drive roller is driven by rotation amount control using the first transport motor, and the second drive roller is driven by first, second, third and fourth torque management values using the second transport motor. Driven by the management torque value based on
The first management torque value is a management torque value corresponding to the time when the target is not transported, and the second management torque value is the acceleration speed of the first transport motor to a predetermined speed when the target transport operation is started. The management torque value corresponding to an acceleration period to be performed, the third management torque value is a management torque value corresponding to a constant speed rotation period in which the first transfer motor is rotated at a constant speed during the transfer operation of the target, The fourth management torque value is a management torque value corresponding to a deceleration period in which the first transport motor performs a deceleration operation when the target transport operation is finished,
The fourth management torque value is set lower than the first management torque value;
The second management torque value is set higher than the first management torque value,
The third management torque value is set higher than the first management torque value and lower than the second management torque value,
A control method for a recording apparatus, wherein the non-conveyance includes a printing operation.   2. The recording according to claim 1, wherein in the acceleration period of the second management torque value, the rotation of the second drive roller is started earlier than the timing at which the first drive roller starts to rotate. Control method of the device.   In the deceleration period of the fourth management torque value, the first drive roller decelerates more than the timing at which the second drive roller switches from the third management torque value to the rotational drive by the fourth management torque value. 3. The method for controlling a recording apparatus according to claim 1, wherein the recording apparatus is started early.   The said 2nd management torque value is a magnitude | size of the grade which can fully control the flapping of the said target at the time of conveyance, The Claim 1 characterized by the above-mentioned. Control method of recording apparatus.   5. The fourth management torque value according to claim 1, wherein the fourth management torque value is large enough to sufficiently control flapping of the target during conveyance. Control method of recording apparatus. A support means for supporting the long target along the transport path along the length direction of the target;
Recording means for performing a recording process on the target in a state of being supported by the support means;
A first drive roller for winding the target at a position in the vicinity of the upstream end of the support means on the transport path;
A first transport motor for driving the first drive roller;
A second drive roller for winding the target at a position near the downstream end of the support means on the transport path;
A second transport motor for driving the second drive roller;
A recording device comprising:
When the recording apparatus transports the target, the recording apparatus drives the first driving roller by rotation amount control using the first transport motor, and uses the second transport motor to drive the second drive roller to the first. A drive control unit that is driven by a management torque value based on the first, second, third, and fourth torque management values;
The first management torque value is a management torque value corresponding to the time when the target is not transported, and the second management torque value is the acceleration speed of the first transport motor to a predetermined speed when the target transport operation is started. The management torque value corresponding to an acceleration period to be performed, the third management torque value is a management torque value corresponding to a constant speed rotation period in which the first transfer motor is rotated at a constant speed during the transfer operation of the target, The fourth management torque value is a management torque value corresponding to a deceleration period in which the first transport motor performs a deceleration operation when the target transport operation is finished,
The fourth management torque value is set lower than the first management torque value;
The second management torque value is set higher than the first management torque value,
The third management torque value is set higher than the first management torque value and lower than the second management torque value,
The recording apparatus characterized in that the non-conveyance includes a printing operation.   The recording apparatus according to claim 6, wherein the second management torque value is large enough to sufficiently control flapping of the target during conveyance.   The recording apparatus according to claim 6, wherein the fourth management torque value is a magnitude that can sufficiently control the fluttering of the target during conveyance.

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