JP5871027B2 - Recording device - Google Patents

Description

  The present invention relates to a recording apparatus.

  As a recording apparatus, an ink jet printer is widely known. For example, Patent Document 1 describes a printer capable of recording using long continuous paper. In the printer described in the document, a configuration is provided in which tension is applied to the continuous paper on the platen by providing a difference in rotational speed between the transport roller unit that feeds the continuous paper onto the platen and the transport roller unit that transports the continuous paper from the platen. It was equipped with.

JP 2007-313663 A

When a long recording medium such as continuous paper is used, if an abnormality occurs in the transport system, an excessive load is applied to the recording medium, or the recording medium is bent and interferes with the apparatus. In particular, when the recording medium bends on the platen, the recording medium and the ink jet head come into contact with each other, which may cause a problem with the ink jet head or the head conveyance system.
Note that, as a countermeasure against an abnormality in the transport system, it is common to stop the operation of the apparatus as soon as an abnormality is detected. However, in this target method, a product in progress is wasted. There is a problem.

  The present invention has been made in view of the above-described problems of the prior art, and provides a recording apparatus that can reduce interference with a recording processing unit when an abnormality occurs in a recording medium conveyance system. One of the purposes is to do.

  The recording apparatus of the present invention includes a medium support unit that supports a long recording medium, a recording processing unit that performs a recording process on the recording medium supported by the medium support unit, and the recording processing unit. A recording processing unit transport system that moves in parallel with the support surface of the medium support unit, a first drive roller that feeds the recording medium to the medium support unit, and a first drive coupled to the first drive roller A motor, a second drive roller for unloading the recording medium from the medium support unit, a medium transport system including a second drive motor coupled to the second drive roller, and a control unit for controlling the recording apparatus; And the control unit performs a predetermined process in the medium transport system during a period in which the recording process unit performs a recording process on the recording medium while scanning the recording processing unit on the recording medium. Different There in the event of, and wherein the retracting said recording processing unit to the outside of the area of the medium support member while maintaining the direction of movement at the time of the abnormality has occurred.

  According to this configuration, when a predetermined abnormality occurs in the medium conveyance system, the recording processing unit is retracted to an area outside the medium support unit, so that the recording medium is bent due to the abnormality. In addition, the contact between the recording processing unit and the recording medium can be made difficult to occur. As a result, it is possible to prevent a problem from occurring even in the recording processing unit due to an abnormality in the medium transport system. Further, when the recording processing unit is evacuated, the evacuation operation is executed by moving the recording processing unit as it is in the moving direction in the recording processing, so that the recording processing unit can be evacuated quickly and the recording processing It is possible to prevent a load from being applied to the recording processing section conveyance system due to a sudden change of direction of the section.

The control unit executes a retreat operation of the recording processing unit when the abnormality that has occurred in the medium conveyance system is the first type, and the abnormality is a second type that is different from the first type. Alternatively, the recording process may be continued.
According to this configuration, either the evacuation operation of the recording processing unit or the continuation of the recording process is selected according to the type of abnormality that has occurred in the medium conveyance system. The recording process in progress can be completed. Thereby, the waste of the product at the time of abnormality occurrence can be reduced.

A motor control unit that drives and controls the first drive motor and the second drive motor is provided in the medium transport system, and the motor control unit outputs a control signal that rotates the drive motor to be controlled. The first type of abnormality is detected based on a comparison between the current value of the drive motor after a lapse of a predetermined time from a preset reference current value, and based on the current value of the drive motor to be controlled Thus, the load information of the drive motor may be calculated and integrated, and the second type of abnormality may be detected based on a comparison between the obtained integrated value and a reference integrated value.
The first type of abnormality is a power supply system or drive system abnormality detected as an abnormality in the current value of the drive motor, and has a high possibility of causing the recording medium to bend. On the other hand, the second type of abnormality is an abnormality that is detected when an excessive load is applied to the drive motor, and even if it is detected, the operation of the drive motor does not immediately fail. According to the above configuration, when the first type of abnormality is detected, the save operation of the recording processing unit is executed, and when the second type of abnormality is detected, the recording process is continued. The recording apparatus can make it difficult to cause damage to the processing section and reduce waste of the product.

The motor control unit uses a lower one of the target current value of the drive motor after the lapse of the predetermined time and the maximum current value determined according to the rotation speed of the drive motor as the reference current value. It is good.
Thereby, it is possible to prevent erroneous detection of an error due to a phenomenon that the maximum current value is lowered when the rotation speed of the motor is high.

The motor control unit calculates load information a = i ² α−β represented by a current value i of a drive motor to be controlled, a current heat quantity coefficient α, and a heat release amount constant β, and an integrated value of the load information a A configuration may be adopted in which A is calculated and an overload of the drive motor is detected when the integrated value A of the load information a is larger than a predetermined reference integrated value A _E.
Thereby, it is possible to detect the overload of the drive motor with relatively high accuracy by a simple arithmetic processing. Since the current calorific coefficient α and the heat dissipation constant β can be easily set based on experiments, the initial setting can be easily performed.

1 is a diagram illustrating a printer according to an embodiment. FIG. 3 is a plan view of a printing area where printing is performed in the printer. A side sectional view of a platen. The functional block diagram of a printer. 10 is a flowchart illustrating a processing routine related to conveyance and printing processing. The figure which shows an error monitoring routine. Explanatory drawing of the step which acquires a motor electric current value. Explanatory drawing of the step which determines the power supply abnormality of a motor. The flowchart which shows the detail of an encoder check routine. Explanatory drawing which shows the change of the encoder output at the time of a conveyance start. Explanatory drawing of the printing operation by a printer. The flowchart of an error processing routine.

Hereinafter, embodiments of the recording apparatus will be described with reference to the drawings.
The scope of the present invention is not limited to the following embodiment, and can be arbitrarily changed within the scope of the technical idea of the present invention. Moreover, in the following drawings, in order to make each structure easy to understand, the actual structure may be different from the scale, number, or the like in each structure.

  FIG. 1 is a diagram illustrating a printer according to the present embodiment. FIG. 2 is a plan view of a printing area in which printing is performed in the printer. FIG. 3 is a side sectional view of the platen.

The printer 11 (recording apparatus) employs an inkjet system that ejects liquid onto a continuous paper 12 from a plurality of recording heads (liquid ejection heads) as a printing system, and is a long shape wound in a roll shape. The continuous paper (recorded medium) 12 is sequentially fed out to perform a printing process, and the continuous paper 12 after printing is wound into a roll again.
In this embodiment, an XYZ orthogonal coordinate system is set in which the width direction of the continuous paper 12 in the horizontal plane is the X direction, the transport direction of the continuous paper 12 orthogonal to the X direction is the Y direction, and the vertical direction is the Z direction. Yes.

  The printer 11 includes a main body unit 14 that executes a printing process, a feeding unit 13 that supplies the continuous paper 12 to the main body unit 14, and a winding unit 15 that winds the continuous paper 12 discharged from the main body unit 14. I have.

  The main body portion 14 includes a main body case 16, the feeding portion 13 is installed on the upstream side (−Y side) of the main body case 16 in the transport direction, and the winding portion 15 is downstream in the transport direction of the main body case 16 (+ Y side). Is installed. The feeding unit 13 is connected to the medium supply unit 16a provided on the side wall 16A on the upstream side (−Y side) of the main body case 16 while the medium is provided on the side wall 16B on the downstream side (+ Y side) in the transport direction. The winding unit 15 is connected to the discharge unit 16b.

  The feeding unit 13 includes a support plate 17 attached to a lower portion of the side wall 16A of the main body case 16, a winding shaft 18 provided on the support plate 17, and a feeding table 19 connected to the medium supply unit 16a of the main body case 16. And a relay roller 20 provided at the tip of the feeding table 19. A continuous paper 12 wound in a roll shape on a winding shaft 18 is rotatably supported. The continuous paper 12 fed from the roll is wound around the relay roller 20 and converted to the upper surface of the feeding table 19, and is conveyed along the upper surface of the feeding table 19 to the medium supply unit 16 a.

  The winding unit 15 includes a winding frame 41, a relay roller 42 provided on the winding frame 41, and a winding drive shaft 43. The continuous paper 12 discharged from the medium discharge unit 16 b is wound around the relay roller 42 and guided to the winding drive shaft 43, and is wound into a roll by the rotational drive of the winding drive shaft 43.

  A plate-like base 21 is installed horizontally in the main body case 16 of the main body 14, and the main body case is partitioned into two spaces by the base 21. A space above the base 21 is a printing chamber 22 that performs printing processing on the continuous paper 12. The printing chamber 22 includes a platen (medium support unit) 28 fixed on the base 21, a recording head (recording processing unit) 36 provided above the platen 28, and a carriage 35 a that supports the recording head 36. Two guide shafts 35 (see FIG. 2) for supporting the carriage 35a and a valve unit 37 are provided. The two guide shafts 35 are arranged in parallel with each other along the transport direction (Y direction), and the carriage 35a is configured to be reciprocally movable in the transport direction. In the case of this embodiment, the carriage 35 a and the two guide shafts 35 belong to a recording processing unit transport system that transports the recording head 36.

  As shown in FIGS. 1 to 3, the platen 28 includes a box-shaped support base 28 a having an upper surface opened, and a mounting plate 28 b attached to the opening of the support base 28 a. The support base 28 a is fixed on the base 21, and the inside surrounded by the support base 28 a and the mounting plate 28 b is a negative pressure chamber 31. The continuous paper 12 is placed on the support surface PL (upper surface in the drawing) of the placement plate 28b.

  The mounting plate 28b is formed with a large number of through holes 28A penetrating the mounting plate 28b in the thickness direction. The side wall (in this embodiment, the side wall on the −Y side) is provided on one side wall of the support base 28a. An exhaust port 28 </ b> B that penetrates through is formed. A suction fan 29 is connected to the exhaust port 28B. By sucking the inside of the negative pressure chamber 31 by the suction fan 29, a suction force is applied to the continuous paper 12 through the numerous through holes 28A, and the continuous paper 12 is adsorbed to the support surface PL of the mounting plate 28b to be flat. Can be

A supply conveyance system including a plurality of conveyance rollers is provided on the upstream side (−Y side) of the platen 28 in the conveyance direction. The supply conveyance system is provided in the vicinity of the first conveyance roller pair 25 provided in the printing chamber 22 near the platen 28, the relay roller 24 provided in the lower space of the main body case 16, and the medium supply unit 16a. Relay roller 23.
The first transport roller pair 25 includes a first drive roller 25a and a first driven roller 25b. As shown in FIG. 2, a first transport motor (first drive motor) 26 and a first encoder 26E are connected to the first drive roller 25a.

  In the supply conveyance system, the continuous paper 12 carried into the main body case 16 from the feeding unit 13 via the medium supply unit 16a is wound around the first drive roller 25a via the relay rollers 23 and 24 from below, Nipped by the first conveying roller pair 25. Then, with the rotation of the first drive roller 25 a driven by the first transport motor 26, the first transport roller pair 25 is fed out horizontally on the support surface PL of the platen 28.

On the other hand, a discharge conveyance system including a plurality of conveyance rollers is provided on the downstream side (+ Y side) of the platen 28 in the conveyance direction. The discharge conveyance system includes a second conveyance roller pair 33 provided on the opposite side of the platen 28 from the first conveyance roller pair 25, a reverse roller 38 and a relay roller 39 provided in a space on the lower side of the main body case 16. And a feed roller 40 provided in the vicinity of the medium discharge portion 16b.
The second transport roller pair 33 includes a second drive roller 33a and a second driven roller 33b. As shown in FIG. 2, a second transport motor (second drive motor) 34 and a second encoder 34E are connected to the second drive roller 33a. Since the second driven roller 33b is disposed on the printing surface side (upper surface side) of the continuous paper 12, the end in the width direction (X direction) of the continuous paper 12 to avoid damage to the printed image. It is good also as a structure contact | abutted only to an edge part.

  In the discharge conveyance system, the second conveyance roller pair 33 that nips the continuous paper 12 carries out the continuous paper 12 from the platen 28 as the second driving roller 33 a driven by the second conveyance motor 34 rotates. The continuous paper 12 fed from the second transport roller pair 33 is transported to the feed roller 40 via the reverse roller 38 and the relay roller 39, and is fed to the take-up unit 15 by the feed roller 40 via the medium discharge unit 16b. It is.

  In the present embodiment, the medium conveyance in which the supply conveyance system including the first conveyance roller pair 25 and the discharge conveyance system including the second conveyance roller pair 33 convey the continuous paper 12 that is a recording medium in the main body 14. It belongs to the system.

Next, in the case of the present embodiment, the plurality of recording heads 36 are attached to the carriage 35a via the head attachment plate 36a. The head mounting plate 36a is configured to be movable in the medium width direction (X direction) on the carriage 35a. The head mounting plate 36a can be controlled in position by a head position control unit 35b connected to the carriage 35a, and by moving the head mounting plate 36a in the medium width direction (X direction), a plurality of recording heads 36 are integrated. Line feed can be operated. The recording heads 36 are arranged at regular intervals in the medium width direction so that the adjacent recording heads 36 are alternately arranged in two stages in the medium transport direction (Y direction) on the head mounting plate 36a.
The head position controller 35b controls the position of the recording head 36 in the medium width direction (X direction) and controls the position of the carriage 35a in the medium conveyance direction (Y direction; head scanning direction). The recording head 36 can be arranged at a desired position.

  Each of the plurality of recording heads 36 is connected to a valve unit 37 via an ink supply tube (not shown). The valve unit 37 is provided on the inner wall of the main body case 16 in the printing chamber 22 and is connected to an ink tank (ink reservoir) (not shown). The valve unit 37 supplies the ink supplied from the ink tank to the recording head 36 while temporarily storing the ink.

On the lower surface (nozzle formation surface) of the recording head 36, a large number of ink discharge nozzles are arranged in the medium width direction (X direction). The recording head 36 performs printing by ejecting ink supplied from the valve unit 37 from the ink discharge nozzle toward the continuous paper 12 on the platen 28.
Note that the recording head 36 may have a plurality of ink discharge nozzle arrays. In this case, when performing color printing of 4 colors or 6 colors, if ink is assigned to each ink discharge nozzle row for each color type, a single recording head 36 can eject a plurality of colors of ink. Become.

  In the printing chamber 22, an area on the platen 28 is a printing area R in which printing is performed on the continuous paper 12 by ink ejection from the ink discharge nozzles. The continuous paper 12 is intermittently conveyed by the supply conveyance system and the discharge conveyance system described above. Specifically, the continuous paper 12 having a length corresponding to the printing region R is loaded onto the platen 28 every time printing is performed, and is sent to the discharge conveyance system after the printing process.

  As shown in FIGS. 1 and 2, the guide shaft 35 extending into the printing chamber 22 extends from the printing region R to the outside in the medium conveyance direction. Thereby, the carriage 35a can be moved to an area outside the printing area R. A first maintenance area R1 is provided on the upstream side (−Y side) in the medium conveyance direction of the printing area R, and a second maintenance area R2 is provided on the downstream side (+ Y side) in the medium conveyance direction.

A maintenance unit 60 is provided in the first maintenance region R1. The maintenance unit 60 includes, for example, a cap member and a wiping member that are provided corresponding to each recording head 36, and a suction device that is connected to the cap member and sucks the inside of the cap member.
The second maintenance area R2 is not provided with a maintenance unit or the like, and is a work space in which an operator's hand or arm can be inserted. By disposing the carriage 35a in the second maintenance region R2, the nozzle forming surface of the recording head 36 can be exposed in the work space, and the operator can clean the nozzle forming surface, replace the recording head 36, and the like. It becomes possible.

  The continuous paper 12 after the printing process is naturally dried while being conveyed in the discharge conveyance system. However, the continuous paper 12 may be provided with a heating device for forcibly drying the ink and fixing the ink to the continuous paper 12. Good. For example, the platen 28 may be provided with a platen heater that heats the mounting plate 28b, or the heating device may be provided in the discharge conveyance system.

Next, FIG. 4 is a functional block diagram of the printer 11.
As shown in FIG. 4, the printer 11 includes a controller 44 that controls the driving 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 a processing routine program and the like related to the printing process and the conveyance process shown in the flowchart of FIG. The RAM 47 is used as a temporary storage area for calculation results in the CPU 45 and a temporary storage area for print data input from the external input device 48.

  The controller 44 includes a head driver 49, a first transport motor driver (first motor control unit) 50, a second transport motor driver (second motor control unit) 52, a suction fan motor driver 54, a torque detection sensor 53, a pressure A detection sensor 32 and an external input device 48 are connected.

  A plurality of recording heads 36 and a head position controller 35b are connected to the head driver 49. In the printing process, the controller 44 reads 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 drives the recording head 36 and the head position control unit 35b based on the print data received from the controller 44, and controls the position of the recording head 36 on the continuous paper 12 from the ink discharge nozzles of the recording head 36. Ink droplets are ejected to form an image on the continuous paper 12.

  The first transport motor driver 50 detects the amount of rotation of the first transport motor 26 based on the count signal output from the first encoder 26E connected to the first transport motor 26, and the amount of rotation of the first transport motor 26 Feedback control. That is, the first transport motor driver 50 rotationally drives the first drive roller 25 a by the first transport motor 26 until the predetermined transport length input from the controller 44 is reached, and the continuous paper is fed from the first transport roller pair 25. 12 is fed out onto the platen 28.

  On the other hand, the second transport motor driver 52 drives the second transport motor 34 by torque control based on a control signal input from the controller 44. In the present embodiment, a torque detection sensor 53 that detects the torque of the second transport motor 34 is connected to the controller 44, and the controller 44 detects the torque detection result of the second transport motor 34 that is output from the torque detection sensor 53. Based on the above, the torque of the second transport motor 34 is feedback controlled via the second transport motor driver 52. As a result, a predetermined tension based on the torque of the second transport motor 34 is applied to the continuous paper 12 via the second drive roller 33a.

  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, as the torque detection sensor 53, a current sensor of the second transport motor driver 52 that detects the magnitude of the current flowing through the second transport motor 34 is used. As a result, the controller 44 sets the current value of the second transport motor 34 as the torque setting value for the second transport motor driver 52, and the second transport motor driver 52 sets the second transport motor driver 52 based on the input current value. 2. Current feedback control of the transport motor 34 is performed.

  In this embodiment, since the second transport motor 34 is driven by torque control, the second encoder 34E connected to the second transport motor 34 is used to detect the feed length when transporting the continuous paper 12. Although not, it is used for the initialization operation of the second transport motor 34 when the apparatus is activated and for the stop control of the second drive roller 33a.

  The suction fan motor driver 54 drives and controls the suction fan motor 30 connected to the rotation shaft of the suction fan 29 based on a control signal input from the controller 44. By rotating the suction fan 29 at a predetermined speed by the driving force of the suction fan motor 30, the inside of the negative pressure chamber 31 can be decompressed with a predetermined suction force based on the rotation speed. 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 28A of the placement plate 28b.

Next, conveyance control and printing control in the printer 11 of the present embodiment will be described with reference to FIG. FIG. 5 is a flowchart illustrating a processing routine related to conveyance and printing processing.
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.
Although not shown, when the controller 44 executes the processing routine program relating to the conveyance process and the printing process, print data used for printing on the continuous paper 12 is input from the external input device 48 to the RAM 47. Then, the print data is supplied to the recording head 36 via the head driver 49.

  As shown in FIG. 5, first, in step S <b> 10, the controller 44 outputs a control signal for starting an error monitoring routine to the first transport motor driver 50 and the second transport motor driver 52. The first transport motor driver 50 and the second transport motor driver 52 that have received the control signal start an error monitoring routine for monitoring errors in the first transport motor 26 and the second transport motor 34 connected thereto.

  In the error monitoring routine, the first transport motor driver 50 and the second transport motor driver 52 measure and acquire the currents flowing through the first transport motor 26 and the second transport motor 34 every predetermined time (for example, every 50 μs). An arithmetic process is executed using the current value. Then, an error is determined by comparing the calculation result with a preset reference value, and when the occurrence of the error is detected, the controller 44 is notified of the error that has occurred.

  Once the execution of the error monitoring routine is started, the first transport motor driver 50 and the second transport motor driver 52 are executed every predetermined time independently of the other processing routines. When an error is detected in the error monitoring routine, the first transport motor driver 50 and the second transport motor driver 52 notify the controller 44 of the error that has occurred. When receiving an error notification from the first transport motor driver 50 or the second transport motor driver 52, the controller 44 starts an error processing routine (see FIG. 12). The error handling routine defines an operation according to the type of error received.

Here, the error monitoring routine will be described with reference to FIGS.
FIG. 6 is a diagram illustrating an error monitoring routine executed in the first transport motor driver 50 and the second transport motor driver 52. FIG. 7 is an explanatory diagram of steps for obtaining a motor current value.
Hereinafter, an error monitoring routine in the first transport motor driver 50 and the first transport motor 26 will be described in detail, but the same applies to the second transport motor driver 52 and the second transport motor 34 unless otherwise specified.

The error monitoring routine according to the present embodiment includes steps S20 to S25.
First, in step S20, it is determined whether or not a control signal for instructing termination of the error monitoring routine is input. When a control signal for instructing the end of processing is input from the controller 44 to the first transport motor driver 50, the error monitoring routine is ended. Otherwise, the process proceeds to step S21.

  Next, in step S21, the first transport motor driver 50 acquires the current value i of the first transport motor 26 to be driven, as shown in FIG. In the case of this embodiment, the first transport motor 26 and the second transport motor 34 are both DC motors, and the acquired current value i is a direct current value.

  Next, in step S22, the current value i acquired in step S21 is compared with the reference current value to determine whether or not there is an abnormality in the power supply of the motor. Here, FIG. 8 is an explanatory diagram of steps for determining a motor power supply abnormality, FIG. 8A is an explanatory diagram of a target current value used as a reference current value, and FIG. 8B is used as a reference current value. It is explanatory drawing of the largest electric current value made.

  In principle, the target current value shown in FIG. 8A is used as the reference current value in step S22. The target current value is a command value for current control input from the controller 44 to the first transport motor driver 50, or a value obtained by multiplying the command value by a predetermined coefficient.

  In the example shown in FIG. 8A, a command value (target current value) i2 is input from the controller 44 to the first transport motor driver 50 at time t1. Then, the first transport motor driver 50 starts driving the first transport motor 26, and the current value i flowing through the first transport motor 26 gradually increases. At time t4, the current value i reaches the target current value i2.

In step S22, in view of such a current rising curve, the current value i at a time (time t4 or a time after that) after a predetermined time has elapsed since the target current value was input (time t1). Is compared with the target current value i2, and it is determined whether or not the current value i is less than the target current value i2.
If the current value i does not reach the target current value i2, an abnormality such as, for example, the power supply line of the first transport motor 26 being cut off or the brush of the first transport motor 26 being worn occurs. Steps S23 and S24 are omitted, and the process proceeds to Step S25. On the other hand, if the current value i has reached the target current value i2, it is determined that the power supply system of the first transport motor 26 is normal, and the process proceeds to step S23.

  In the above description, the command value i2 is used as the target current value. However, instead of the command value itself, a value obtained by multiplying the command value by a predetermined coefficient may be used as the target current value. Specifically, a value of 0.8 × i2 (0.8 times) or 0.9 × i2 (0.9 times) may be used as the target current value. When the target current value is set to these values, as shown in FIG. 8A, the time when the current value i reaches the target current value is the time t2 and 0.9 × i2 when 0.8 × i2. In this case, time t3 is reached, which is earlier than time t4. Therefore, by setting the target current value to a value smaller than the command value as described above, it is possible to shorten the time until the state of the current value i is determined after the driving of the first transport motor 26 is started. it can.

  By the way, in the DC motor, the value of the flowing current changes depending on the rotation speed. Specifically, as shown in FIG. 8B, the maximum current value I decreases as the rotational speed N increases, and the current hardly flows. Therefore, for example, when the command value i2 shown in FIG. 8 (a) is an intermediate value between the maximum current values I1 and I2 shown in FIG. 8 (b), the first conveyance is performed when the above steps S21 and S22 are executed. When the rotational speed of the motor 26 is N2, the current value i rises only up to the maximum current value I2, and does not reach the command value i2 that is the target current value. If the current value i and the target current value i2 are simply compared at this time, an error (motor power supply abnormality) is erroneously detected.

  Therefore, when the above phenomenon is assumed, the reference current value according to step S22 is set to the target current value based on the command value input from the controller 44, and the maximum current value determined according to the number of rotations of the motor. Set to the lower of. That is, when executing step S21, the maximum current value I is acquired from the rotational speed of the motor at the time of step S21 and the relationship shown in FIG. 8B, and the maximum current value I is lower than the target current value. In this case, the maximum current value I is set as the reference current value according to step S22. Thereby, the erroneous detection of the error in step S22 can be prevented.

Next, in step S23, a load integrated value calculation for estimating the state of the temperature load in the first transport motor 26 is executed.
In the load integrated value calculation in step S23, the first transport motor driver 50 uses the current value i acquired in step S21, the preset current heat amount coefficient α, and the heat release amount constant β to load information a = i ² α-β is calculated. Then, the integrated value A is calculated by integrating the calculated load information a every step execution.

  The current calorie coefficient α in the formula of the load information a is a coefficient that correlates the flowing current amount and the heat generation amount. The current calorific value coefficient α can be calculated based on the winding resistance value of the first transport motor 26, but it is more realistic by correcting it based on the actual value of the heat generation amount when the current value i is changed. Load information a can be calculated. On the other hand, the heat dissipation constant β is a heat dissipation amount per unit time of the first transport motor 26 and varies depending on the type of the first transport motor 26 and the configuration of the cooling system, but experimentally according to the configuration of the printer 11. Can be sought.

That is, the load information “a” is obtained by subtracting the heat release amount (β) per unit time from the heat generation amount (i ² α) of the first transport motor 26 per unit time. It corresponds to the amount of heat storage. The integrated value A corresponds to the amount of heat accumulated in the first transport motor 26 due to operation, and can be used as a parameter for estimating the load on the first transport motor 26 due to heat generation.

In the first transport motor driver 50, the load information a becomes a negative value when i ² α corresponding to the heat generation amount is smaller than the heat dissipation amount constant β corresponding to the heat dissipation amount. The integrated value A is calculated so that it does not become less than zero. This is because the temperature of the first transport motor 26 does not fall below the ambient temperature, and thus the amount of heat accumulated in the motor cannot be accurately reflected when the integrated value A becomes a negative value. Therefore, when the value obtained by adding the load information a to the integrated value A is negative, 0 (zero) is set as the integrated value A.

Next, in step S24, the first transport motor driver 50 compares the integrated value A calculated in step S23 with a preset reference integrated value A _E. The reference integrated value A _E is an integrated value for determining that the motor is in an overload state due to heat generation, and can be obtained experimentally according to the heat resistance of the first transport motor 26 and the like.
If the integrated value A exceeds the reference integrated value A _E , the process proceeds to step S25. On the other hand, if the integrated value A is equal to or less than the reference integrated value A _E, it is determined that the first transport motor 26 is operating normally, and the process returns to step S20.

Next, in step S25, an error notification operation is executed. That is, when the current value i of the first transport motor 26 does not reach the reference current value at step S22 (S22-YES), or when the integrated value A exceeds the reference integrated value A _E at step S24 (S24-YES). ), The first transport motor driver 50 notifies the controller 44 of the error that has occurred.

  If an error is determined in step S22, the first transport motor driver 50 notifies the controller 44 of error information indicating that the power supply of the first transport motor 26 is abnormal, and the error is determined in step S24. In such a case, error information indicating that the first transport motor 26 is in an overload state is notified.

  Returning to FIG. 5, in step S <b> 11, the controller 44 transmits a control signal to the suction fan motor driver 54. Then, when the suction fan motor 30 is driven to rotate, the suction fan 29 starts to rotate so that negative pressure is generated 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 28A of the mounting plate 28b. In this case, the continuous paper 12 is adsorbed onto the support surface PL of the platen 28 with a second adsorbing force substantially equal to the attraction force F1 of the suction fan 29.

  Subsequently, in step S <b> 12, the controller 44 confirms the pressure in the negative pressure chamber 31 based on the detection signal from the pressure detection sensor 32 provided in the negative pressure chamber 31. The controller 44 repeatedly confirms the pressure in the negative pressure chamber 31 until the pressure in the negative pressure chamber 31 reaches a pressure value substantially equal to the suction force F1 of the suction fan 29. When it is confirmed that the negative pressure chamber 31 has a pressure equal to the suction force F1, it is determined that the pressure reduction by the suction fan 29 is completed, and the process proceeds to step S13.

Next, in step S13, the controller 44 sets the conveyance amount (feed length) of the continuous paper 12 by the first drive roller 25a by setting the rotation amount of the first conveyance motor 26 to C.
The rotation amount C of the first transport motor 26 is determined so that the transport amount of the continuous paper 12 by the first drive roller 25a is rotated when the first drive roller 25a is rotationally driven with the rotation drive of the first transport motor 26. 1 is set so as to have a length corresponding to the print region R from the left end (downstream end in the transport direction) to the right end (upstream end in the transport direction). In the present embodiment, the rotation amount C is input to the first transport motor driver 50 as the count number of the first encoder 26E.

In step S13, 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 to T1.
The management torque value T1 of the second transport motor 34 is such that the magnitude of the tension acting on the continuous paper 12 on the platen 28 from the second drive roller 33a based on the torque of the second transport motor 34 is the continuous paper 12 during transport. It is set to a size that can sufficiently suppress fluttering. In the case of this embodiment, the management torque value T <b> 1 is input to the second transport motor driver 52 as the target current value of the second transport motor 34.

  Next, FIG. 9 is a flowchart showing details of step S14. In step S14, the continuous paper 12 conveyance start operation and the encoder check operation are executed by the processing routine including steps S30 to S34 shown in FIG.

  First, in step S <b> 30 shown in FIG. 9, the controller 44 transmits a control signal for starting conveyance to the first conveyance motor driver 50 and the second conveyance motor driver 52. Then, the first driving roller 25a starts to rotate with the rotation of the first conveying motor 26, whereby the conveying of the continuous paper 12 onto the platen 28 is started. In addition, the second driving roller 33 a starts to rotate with the rotation of the second transport motor 34, so that the second driving roller 33 a applies tension to the continuous paper 12.

Next, in step S <b> 31, the controller 44 determines whether the operation being executed is the first transport operation or the second and subsequent transport operations when continuous printing is performed. If it is the first transport operation, the process proceeds to step S32, and an encoder check operation is executed. On the other hand, in the case of the second and subsequent transport operations, the operation after step S32 is skipped and the process proceeds to step S15 of the processing routine shown in FIG.
That is, when the continuous paper 12 is transported and printed repeatedly, the encoder check operation is executed only during the first transport operation, and is not executed in the second and subsequent transport operations.

  Next, in step S32, the controller 44 transmits a control signal for checking the encoder to the first transport motor driver 50 and the second transport motor driver 52. The first transport motor driver 50 and the second transport motor driver 52 that have received the control signal confirm the count signals of the first encoder 26E and the second encoder 34E connected thereto.

  Specifically, for example, the first transport motor driver 50 confirms whether or not a periodic pulse is transmitted for a plurality of count signals (A phase, B phase, etc.) of the first encoder 26E. Here, FIG. 10 is an explanatory diagram showing changes in the encoder output at the start of conveyance. As shown in FIG. 10, when the first transport motor 26 is rotated from the stopped state, the first encoder is immediately after the voltage input time (time t1) even if the drive voltage V1 is input to the first transport motor 26. No count signal is output from 26E, the pulse rises from time t2 when a predetermined time (dead time) has elapsed, and becomes H level at time t3 thereafter. This is because a gear or roller and the first encoder 26E are connected to the drive shaft of the first transport motor 26. The operations of the second transport motor driver 52 and the second transport motor 34 are the same as described above.

  Therefore, the first transport motor driver 50 (second transport motor driver 52) starts to rotate the first transport motor 26 (second transport motor 34) based on the transport start control signal, and then starts from the above dead time. After a long time has elapsed, the count signal of the first encoder 26E (second encoder 34E) is confirmed.

  Next, in step S33, the first transport motor driver 50 (second transport motor driver 52) determines whether a plurality of count signals of the first encoder 26E (second encoder 34E) are normally output. If it is determined that the pulse of the count signal is normally output, the process proceeds to step S15 shown in FIG. On the other hand, if no pulse is detected in at least some of the count signals, it is determined that there is an abnormality in the first encoder 26E or the second encoder 34E, and the process proceeds to step S34.

  As an example when an abnormality is detected in the output pulse of the encoder, in the first encoder 26E or the second encoder 34E, (e1) when the power of the encoder itself is cut off, or (e2) continuous due to a paper jam or the like When the paper 12 is not sent and the first transport motor 26 or the second transport motor 34 is locked, or (e3) the power source of either the A-phase or B-phase pulse output unit is shut off Etc.

  In the case of (e1) and (e2), no pulse of the count signal is detected at the target encoder. In the case of (e3), the pulse to be output from the pulse output unit whose power is cut off is not detected. Therefore, the problems (e1) to (e3) can be detected by confirming the pulse of the count signal after a predetermined time has elapsed from the start of conveyance.

  Next, in step S <b> 34, the first transport motor driver 50 and the second transport motor driver 52 transmit generated error information to the controller 44. The controller 44 that has received the error information notifies the user of the occurrence of the error and cancels the processing routine shown in FIG. This is because the errors (e1) to (e3) detected in the check operation of the encoder are all errors that cannot continue the conveyance operation.

  For example, in the case of the above errors (e1) and (e3), the first driving roller 25a and the second driving roller 33a are driven to rotate while the encoder is defective, and the continuous paper 12 continues to be conveyed without being controlled. Sometimes. Then, there is a possibility that the continuous paper 12 bends on the platen 28 and comes into contact with the recording head 36. In the case of the error (e2), there is a possibility that an excessive load is applied to the continuous paper 12. Accordingly, even if any error occurs, it is necessary to stop the conveyance promptly.

Returning to FIG. 5 again, in step S15, the controller 44 sets the rotation amount of the first conveyance motor 26 in step S13 based on the rotation amount information of the first conveyance motor 26 transmitted from the first conveyance motor driver 50. It is determined whether or not the rotation amount C has been reached.
The controller 44 determines that the conveyance of the continuous paper 12 by the first drive roller 25a is not completed when the determination result in step S15 is a negative determination (the rotation amount of the first conveyance motor 26 is not C). The conveyance of the continuous paper 12 by the first drive roller 25a is continued until the conveyance amount of the continuous paper 12 by the first drive roller 25a reaches a desired conveyance amount.

  On the other hand, if the determination result in step S15 is affirmative (rotation amount of the first conveyance motor 26 = C), the controller 44 determines that the conveyance of the continuous paper 12 has been completed, and proceeds to step S17. To do. At this time, the first transport motor driver 50 determines that the rotational drive of the first transport motor 26 based on the command value input from the controller 44 has been completed, and stops the first transport motor 26. Thereby, the conveyance of the continuous paper 12 is also stopped.

  In the transport operation of the continuous paper 12, the controller 44 monitors the rotation amount of the first drive roller 25 a as needed, and also from the second drive roller 33 a based on the detection signal from the torque detection sensor 53. 12 is monitored at any time, and based on the detection signal from the pressure detection sensor 32, the pressure change in the negative pressure chamber 31 accompanying the rotational drive of the suction fan 29 is monitored at any time. Yes. Then, the controller 44 is driven by the first transport motor driver 50, the second transport roller 25a, the second drive roller 33a, and the suction fan 29 driven (rotation amount, tension, suction force). When a deviation occurs with respect to the driving conditions defined based on the control signals transmitted from the motor driver 52 and the suction fan motor driver 54, an error notification is performed. That is, the controller 44 is a control signal transmitted from the first transport motor driver 50, the second transport motor driver 52, and the suction fan motor driver 54 by the first drive roller 25a, the second drive roller 33a, and the suction fan 29. Based on the above, whether or not it is operating normally is monitored at any time. Thereby, high operation reliability can be obtained in the transport operation.

  Further, when the continuous paper 12 is conveyed, the rotation speed of the second drive roller 33a is set to be faster than the rotation speed of the first drive roller 25a. Thereby, tension can be applied to the continuous paper 12 being conveyed from the second drive roller 33a, and the flatness of the continuous paper 12 on the platen 28 can be improved. The continuous paper 12 pulled from the platen 28 to the downstream side in the transport direction by the second drive roller 33a is sequentially wound by the winding drive shaft 43 on the downstream side in the transport direction from the second drive roller 33a. Therefore, the continuous paper 12 is hardly bent at the downstream side in the transport direction with respect to the second drive roller 33a, and is stably transported at a speed fed out from the first drive roller 25a.

  Further, during the conveyance, the suction force of the suction fan 29 is set to such a magnitude that the continuous paper 12 is not firmly adsorbed to the support surface PL of the platen 28. Thereby, it is possible to prevent the conveyance of the continuous paper 12 from being hindered by the suction force of the platen 28, and it is possible to avoid an excessive driving load on the first conveyance motor 26 and the second conveyance motor 34 during conveyance. Further, since the tension of the second drive roller 33a can be reliably applied to the continuous paper 12 without being obstructed by the suction force of the platen 28, the magnitude of the tension can be adjusted with high accuracy.

  In the printer 11 of this embodiment, the suction force F1 of the suction fan 29 and the management torque value T1 of the second transport motor 34 are arbitrarily changed based on data input from the external input device 48 to the controller 44. can do. By using this, if the management torque value T1 of the second transport motor 34 is set smaller within a range in which the flapping of the continuous paper 12 during transport can be suppressed, the driving load of the second transport motor 34 is reduced, 2 The conveyance motor 34 can be prevented from being overheated, and energy saving of the entire apparatus can be achieved.

Next, in step S16, the controller 44 changes the suction force of the suction fan 29 to F2 by setting the rotation speed of the suction fan motor 30. The suction force F2 is a value larger than the suction force F1 of the suction fan 29 set in step S13. At this time, the conveyance of the continuous paper 12 is stopped, and the portion of the continuous paper 12 disposed on the platen 28 is adsorbed to the support surface PL of the platen 28 with a first adsorbing force substantially equal to the suction force F2.
In other words, the printer 11 of the present embodiment causes the continuous paper 12 to be attracted to the support surface PL of the platen 28 with a relatively large first attracting force when the printing process is performed, while compared to the first attracting time when the transport process is performed. The continuous paper 12 is attracted to the support surface PL of the platen 28 with a small second attracting force (suction force F1).

  Next, in step S17, the controller 44 changes 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 to T2. The management torque value T2 is a value smaller than the management torque value T1 of the second transport motor 34 set in step S13. Therefore, the driving load of the second transport motor 34 that rotationally drives the second driving roller 33a is reduced, thereby saving energy of the entire apparatus.

  As described above, the controller 44 increases the suction force of the suction fan 29 (suction force F2) in step S16 to attract the continuous paper 12 to the platen 28, and then in step S17, manages the torque of the second transport motor 34. Decrease value to T2. Thereby, since the continuous paper 12 is adsorbed to the platen 28 in a state where a relatively large tension is applied, the continuous paper 12 can be adsorbed while maintaining high flatness. Further, since the tension is reduced while the continuous paper 12 is firmly adsorbed to the platen 28, the continuous paper 12 is not displaced.

  Next, in step S <b> 18, the controller 44 executes a printing process for the continuous paper 12. 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. 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.

Here, FIG. 11 is an explanatory diagram of a printing operation by the printer 11. FIG. 11 shows a plan view of a part of the continuous paper 12 arranged in the printing region R, the carriage 35a, the two guide shafts 35, the first maintenance region R1, and the second maintenance region R2.
In the printer 11 of the present embodiment, as shown in FIG. 11, ink is ejected from the recording head 36 while scanning the carriage 35 a in the medium transport direction (Y direction; guide shaft extending direction) and onto the continuous paper 12. By repeating the operation of forming an image four times while changing the recording head 36, the entire surface of the continuous paper 12 in the print region R is printed.

  More specifically, in scanning (1) and scanning (3) in FIG. 11, the recording head 36 is scanned while scanning the carriage 35a from the end on the upstream side (−Y side) in the medium conveyance direction toward the downstream side (+ Y direction). In the scanning (2) and scanning (4), the ink is ejected while scanning the carriage 35a from the downstream side to the upstream side in the medium transport direction in the illustrated -Y direction. The line feed operation of the recording head 36 is performed between each of the scans (1) to (4). The plurality of recording heads 36 are attached to the carriage 35a via the head attachment plate 36a, and the scanning region of the recording head 36 on the continuous paper 12 is moved by moving the head attachment plate 36a in the medium width direction (X direction). To change.

  During the printing operation, the second drive roller 33a is torque-controlled with the management torque value T2, and the tension is continuously applied to the continuous paper 12 from the second drive roller 33a. The first drive roller 25a supports the continuous paper 12 pulled by the second drive roller 33a on the downstream side in the medium conveyance direction (+ Y direction) in a stopped state. Therefore, the continuous paper 12 is held flat by being given tension from both the first drive roller 25a and the second drive roller 33a. Thereby, it is possible to perform a printing process on the continuous paper 12 in a state where the flatness is maintained, and high-quality printing is possible.

  If the printing operation in step S18 is completed, then in step S19, the controller 44 determines whether or not to continue the printing process for the continuous paper 12. When the printing process for the continuous paper 12 is continued, the process proceeds to step S11, and the processes from step S11 to step S18 are recursively executed. On the other hand, when the printing process for the continuous paper 12 is terminated, the processing routine program relating to the conveyance process and the printing process for the continuous paper 12 is terminated.

Next, processing when an error occurs in the transport system in the printer 11 will be described.
FIG. 12 is a flowchart of the error processing routine. As described above, in the printer 11 of the present embodiment, while the above steps S11 to S19 are executed, the error monitoring routine started in step S10 causes the first transport motor 26 and the second transport motor 34 to perform operations. The error is monitored from time to time.

  The error processing routine illustrated in FIG. 12 is performed when an error that has occurred to the controller 44 is notified from the first transport motor driver 50 or the second transport motor driver 52 in step S25 of the error monitoring routine illustrated in FIG. Executed.

  When the error processing routine is executed, first, in step S40, the controller 44 analyzes the error information notified from the first transport motor driver 50 or the second transport motor driver 52. Specifically, the location where the error has occurred (first transport motor 26, second transport motor 34) and the type of error that has occurred (motor power supply abnormality, motor overload) are identified.

  Next, in step S41, the controller 44 acquires the operating state of the printer 11, and determines whether or not the apparatus is performing a printing operation. When the printing operation is being performed, the process proceeds to step S43. On the other hand, when the printing operation is not performed and the continuous paper 12 is being transported or is in a standby state, the error processing routine is terminated, and processing routines related to the transport processing and print processing being executed are also included. finish. Therefore, even if the continuous paper 12 is being conveyed, the conveying operation is stopped.

  Next, in step S42, the controller 44 determines whether or not the error that has occurred is a serious error. When the error that has occurred is a serious error (when it is a first type of abnormality), the process proceeds to step S43, and an operation for safely stopping printing is started. On the other hand, when it is not a serious error (when it is a second type of abnormality), the process proceeds to step S46, and the printing operation is continued.

  In the present embodiment, the serious error is an error related to a motor power supply abnormality, and the other error is an error related to an overload of the motor. That is, in the error monitoring routine shown in FIG. 6, the error that is notified when the error is determined in step S22 is the above serious error, and the error that is notified when the error is determined in step S24 is the other error. It is an error.

  When the error that has occurred is an error related to a power supply abnormality of the motor, the first transport motor 26 and the second transport motor 34 are inoperable or are not operating normally. In this state, normal operation is not guaranteed for applying an appropriate tension to the continuous paper 12 or holding the continuous paper 12 at a predetermined position on the platen 28. Is canceled.

On the other hand, when the error that has occurred is related to an overload of the motor, the reference integrated value A _E used for error determination is usually set with a margin so that the error can be reported in the normal operating range. Therefore, an operation abnormality is not immediately caused when an error is determined. The time required for the printing operation is about several seconds to several tens of seconds. From these, in this embodiment, when the error that has occurred is an error related to the overload of the motor, the printing up to the end of printing is completed.

First, the case where it is determined in step S42 that the error that has occurred is a serious error (S42-YES) will be described in more detail.
In this case, in step S43, the controller 44 determines the traveling direction of the carriage 35a during the printing operation. If the carriage 35a is moving upstream in the medium conveyance direction (−Y direction), the process proceeds to step S44. If the carriage 35a is moving downstream in the conveyance direction (+ Y direction), the process proceeds to step S45. To do.

  When the process proceeds to step S44, the carriage 35a is retracted to the first maintenance area R1 shown in FIG. On the other hand, when the process proceeds to step S45, the carriage 35a is retracted to the second maintenance area R2 shown in FIG. Hereinafter, this operation will be described in more detail with reference to FIG.

  If a serious error occurs when the carriage 35a is positioned at the first position Er1 of the scan (2) shown in FIG. 11, the carriage 35a is moving upstream in the medium conveyance direction (−Y direction). The above step S44 is selected, and the operation of retracting the carriage 35a to the first maintenance region R1 is started. At this time, since the first maintenance area R1 is located on the extension of the movement direction of the carriage 35a, the carriage 35a is moved to the outside of the printing area R without changing its direction, and the carriage 35a is moved to the first maintenance area. It can be saved in the region R1.

  If a serious error occurs when the carriage 35a is positioned at the second position Er2 for scanning (3), the movement direction of the carriage 35a is downstream in the medium conveyance direction (+ Y direction). Step S45 is selected, and an operation for retracting the carriage 35a to the second maintenance region R2 is started. Also in this case, it is not necessary to change the direction of the carriage 35a, and the carriage 35a can be retreated to the second maintenance area R2 only by being moved outside the printing area R as it is.

  On the other hand, if it is determined in step S42 that the error that has occurred is not serious (NO in step S42), the printing operation is continued until completion while determining the end of the printing operation in step S46. Then, after the printing operation is completed, the error processing routine is ended, and the processing routine relating to the carrying process and the printing process being executed is also ended. Therefore, even during the continuous printing in which the continuous paper 12 is transported and printed repeatedly, only the printing operation that was in progress when the error occurred is executed, and the subsequent continuous paper 12 transport operation and printing operation are stopped. Is done.

  As described above in detail, according to the printer of this embodiment, in the first transport motor driver 50 and the second transport motor driver 52, the current value flowing through the first transport motor 26 and the second transport motor 34 is confirmed. By doing so, the power supply abnormality of the 1st conveyance motor 26 and the 2nd conveyance motor 34 can be detected, and it can alert | report to the controller 44. FIG. Thereby, it is possible to quickly detect an abnormality in the transport system. Therefore, since it is possible to quickly cope with an abnormality in the transport system, it is possible to prevent the continuous paper 12 from being bent, which greatly contributes to stable operation of the apparatus.

  Further, in the first transport motor driver 50 and the second transport motor driver 52, the first transport motor 26 and the second transport motor 34 are subjected to arithmetic processing based on the current values flowing in the first transport motor 26 and the second transport motor 34. An overload due to heat generation can be detected and notified to the controller 44. Thereby, it is possible to quickly detect an abnormality in the transport system. Therefore, since it is possible to quickly cope with an abnormality in the transport system, it is possible to prevent the continuous paper 12 from being bent, which greatly contributes to stable operation of the apparatus.

The above configuration for detecting an error related to overload calculates load information a = i ² α−β expressed by the current value i of the drive motor to be controlled, the current heat quantity coefficient α, and the heat dissipation constant β. At the same time, the integrated value A of the load information a is calculated, and when the integrated value A of the load information a is larger than a predetermined reference integrated value A _E , the overload of the first transport motor 26 or the second transport motor 34 is detected. It is good also as a structure to detect. As a result, the overload of the transport motor can be detected with relatively high accuracy by a simple arithmetic process. In addition, since the above-mentioned current calorie coefficient α and heat dissipation constant β can be easily set based on experiments, initial setting can be easily performed.

  Further, the first transport motor driver 50 and the second transport motor driver 52 confirm the count signals of the first encoder 26E and the second encoder 34E connected to the first transport motor 26 and the second transport motor 34, thereby An abnormality in the first encoder 26E and the second encoder 34E can be detected and notified to the controller 44. Thereby, it is possible to quickly detect an abnormality in the transport system. Therefore, since it is possible to quickly cope with an abnormality in the transport system, it is possible to prevent the continuous paper 12 from being bent, which greatly contributes to stable operation of the apparatus.

  If the error that has occurred in the transport system is serious, even if the printer 11 is in a printing operation, the printing operation is quickly stopped and the carriage 35a is retracted outside the printing region R. When the continuous paper 12 is bent due to an abnormal operation of the first transport motor 26 or the second transport motor 34, it is easy to avoid the recording head 36 and the continuous paper 12 coming into contact with each other.

  In addition, when printing is interrupted and the carriage 35a is retracted as described above, the carriage 35a is retracted to the maintenance area located on the extension of the movement direction of the carriage 35a when an error occurs, so that the carriage 35a is moved to the printing area R. Can be evacuated quickly. In addition, if the direction of the carriage 35a is suddenly changed, the transport system of the carriage 35a may be damaged. However, in the above embodiment, occurrence of such a problem can be avoided.

  If the error that has occurred in the transport system is not serious, if the printer 11 is in a printing operation, the printing operation in progress is completed. As a result, it is possible to prevent a product in progress from being wasted due to a minor error.

  Moreover, in the said embodiment, the magnitude | size of the tension | tensile_strength provided to the continuous paper 12 from the 2nd drive roller 33a is adjusted because the 2nd conveyance motor 34 drives the 2nd drive roller 33a by torque control. Therefore, the continuous paper 12 conveyed while being supported by the platen 28 can be reliably stretched along the conveyance path.

  The second drive roller 33a applies tension to pull the continuous paper 12 supported by the platen 28 toward the downstream side in the transport direction, while the first drive roller 25a does not pull the continuous paper 12. Therefore, the continuous paper 12 is not reversely conveyed from the downstream side in the conveyance direction toward the upstream side. Thereby, since the positional error of the continuous paper 12 resulting from said reverse conveyance does not arise, the continuous paper 12 can be conveyed with high precision.

  Further, a 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. Thereby, when the continuous paper 12 is conveyed, fluttering of the continuous paper 12 is suppressed, so that the continuous paper 12 can be conveyed in a stable state. Further, when the conveyance of the continuous paper 12 is stopped, the continuous paper 12 conveyed while being supported by the platen 28 can be reliably stretched along the conveyance path.

In addition, you may change the said embodiment as follows.
As an adsorption unit that adsorbs the continuous paper 12 to the support surface PL of the platen 28, an electrostatic adsorption device that electrostatically adsorbs the continuous paper 12 to the support surface PL of the platen 28 may be employed. 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 during the printing process of the continuous paper 12, and during the conveyance process 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.

  A list data of 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 and T2 of the second conveyance motor 34 from the ROM 46 according to 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 by the management torque values T1 and T2 of the second transport motor 34.

  The magnitude relationship between the management torque values T1 and T2 is not limited to the above embodiment. For example, when the continuous paper 12 having a very large swelling ratio when absorbing ink is used, the second transport motor 34 during the printing process is more than the management torque value T1 of the second transport motor 34 during the transport process. The management torque value T2 may be set to be larger.

  The platen 28 may be provided with an air release valve that opens the inside of the negative pressure chamber 31 to the atmosphere. By using the suction force adjustment by the suction fan 29 and the air release valve in combination, the degree of decompression in the negative pressure chamber 31 can be quickly reduced, and the conveyance of the continuous paper 12 can be started at an earlier timing.

  Instead of the pressure detection sensor 32 according to the above embodiment, a flow rate detection sensor for detecting the flow rate of the air exhausted through the suction fan 29 may be provided. If the negative pressure chamber 31 is discarded by the suction fan 29, the exhaust flow rate decreases as the pressure decreases. Therefore, the pressure in the negative pressure chamber 31 can be estimated based on the exhaust flow rate detected by the flow rate detection sensor. it can.

  Further, a long plastic film or the like may be used as a recording medium.

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, a 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 (eg, 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 (recording medium), 25a ... 1st drive roller, 26 ... 1st conveyance motor (1st drive motor), 26E ... 1st encoder, 28 ... Platen (medium support) Part), 33a ... second drive roller, 34 ... second transport motor (second drive motor), 34E ... second encoder, 36 ... recording head (recording processing part), 50 ... first transport motor driver (first motor) Control unit), 52 ... second transport motor driver (second motor control unit), A ... integrated value, A _E ... reference integrated value, a ... load information, I, I1, I2 ... maximum current value, i ... current value , I2 ... command value (target current value), i2 ... target current value.

Claims (4)

A medium support unit for supporting the recording medium on a flat support surface;
A recording processing unit for recording on the recording medium supported by the medium supporting unit;
A recording processing unit transport system for moving the recording processing unit in parallel with the support surface;
A medium conveyance system for conveying the recording medium, the first driving roller for sending the recording medium to the medium support unit, the first driving motor connected to the first driving roller, and the medium support A second drive roller for unloading the recording medium from the unit, a medium transport system including a second drive motor coupled to the second drive roller;
When an abnormality occurs in the medium transport system while the recording processing unit is moving, the recording processing unit is retracted to an area outside the medium support unit while maintaining the moving direction at the time when the abnormality occurs. A control unit;
A recording apparatus comprising: The recording apparatus according to claim 1, wherein the recording processing transport system transports the recording processing unit in parallel with a transport direction in which the medium transport system transports the recording medium. Wherein the control unit is capable of determining the extent of the abnormality, the according to the degree of abnormality, the one recording unit performs recording, according to claim 1 or 2, characterized in that determining whether to suspend, A recording apparatus according to any one of the above. A motor control unit that drives and controls at least one of the first drive motor and the second drive motor;
The control unit can determine the degree of abnormality based on the current value of the motor control unit, and determines whether the recording processing unit performs recording or interrupts according to the degree of abnormality. The recording apparatus according to claim 1 , wherein:

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