JP2007245477A - Printer, method for responding to stick slip, program, and printing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a printer which promptly responds to a stick slip motion when a printing head performs the stick slip motion. <P>SOLUTION: The printer is equipped with the printing head which performs printing to a medium, a motor for moving the printing head, a guide part for guiding the printing head along a predetermined direction, a storing part which stores a stick slip region set at the guide part on the basis of a position where the printing head performs the stick slip motion, and a motor controlling part which generates a command value for controlling the motor, and makes the command value for controlling the motor different depending on whether or not the printing head is present in the stick slip region stored in the storage part. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a printing apparatus, a stick-slip handling method, a program, and a printing system.

  For example, an inkjet printer is known as a printing apparatus that performs printing on a medium such as paper or film. This ink jet printer includes a print head that ejects ink onto a medium, and the print head ejects ink while moving relative to the medium to perform printing on the medium.

The print head moves while being guided along a predetermined direction by a guide portion inside the printer. The print head is moved by a motor. The print head is accelerated to a predetermined speed by a controller of the motor, and moves to a target position while moving at a constant speed at a predetermined speed by, for example, PID control (see Patent Documents 1, 2, and 3).
JP 2001-103778 A JP 2001-158144 A JP 2001-169484 A

  In such an ink jet printer, the following problems may occur. That is, for example, when the ink jet printer is not used for a long period of time, the print head does not slide well along the guide portion, and the print head moves or stops repeatedly. (Also called). Such a stick-slip operation is caused by the fact that the grease at the sliding portion between the print head and the guide portion has solidified. In particular, such a stick-slip operation occurs when the print head tries to move at a low speed.

When such a stick-slip operation occurs, the print head cannot be stopped at the target position, and a problem such as the print head moving back and forth around the target position may occur. When such a stick-slip operation occurs, it may take time to stop the print head at the target position.
Therefore, it is necessary to cope with this.

  The present invention has been made in view of such circumstances, and an object of the present invention is to quickly cope with the case where the print head performs a stick-slip operation.

The main invention for achieving the above object is:
(A) a print head for printing on a medium;
(B) a motor for moving the print head;
(C) a guide portion for guiding the print head along a predetermined direction;
(D) a storage unit that stores a stick-slip region set based on a position where the print head performs a stick-slip operation in the guide unit;
(E) a motor control unit that generates a command value for controlling the motor,
A motor control unit that varies the command value for controlling the motor depending on whether the print head is in the stick-slip region stored in the storage unit;
Is a printing apparatus.

  Other features of the present invention will become apparent from the description of the present specification and the accompanying drawings.

=== Summary of disclosure ===
At least the following matters will become clear from the description of the present specification and the accompanying drawings.

(A) a print head for printing on a medium;
(B) a motor for moving the print head;
(C) a guide portion for guiding the print head along a predetermined direction;
(D) a storage unit that stores a stick-slip region set based on a position where the print head performs a stick-slip operation in the guide unit;
(E) a motor control unit that generates a command value for controlling the motor,
A motor control unit that varies the command value for controlling the motor depending on whether the print head is in the stick-slip region stored in the storage unit;
A printing apparatus comprising:
In this way, since the stick-slip region based on the position where the stick-slip operation occurs is stored in advance, the stick-slip operation can be handled earlier than the stick-slip operation after the stick-slip operation is detected. be able to.

  In this printing apparatus, it is preferable that the storage unit stores a stick-slip region set based on a position where the print head performs a stick-slip operation for each moving direction of the print head. In addition, it is preferable that a determination unit that determines whether or not the print head performs a stick-slip operation is further included, and the storage unit stores the stick-slip region based on the determination by the determination unit. The storage unit may store a predetermined range of the guide unit as a stick-slip region from a position determined by the determination unit to perform the stick-slip operation. In the initial operation of the printing apparatus, when the print head is moved at a predetermined speed or less along the guide unit, the determination unit determines whether the print head performs a stick-slip operation. Is desirable. In addition, a speed detection unit that detects a moving speed of the print head is further provided, and the determination unit determines whether the print head performs a stick-slip operation based on the moving speed detected by the speed detection unit. It is desirable to judge. The determination unit may determine whether the print head performs a stick-slip operation based on the command value. In addition, an acceleration detection unit that detects the acceleration of the print head is further provided, and the determination unit determines whether the print head performs a stick-slip operation based on the acceleration detected by the acceleration detection unit. You can also. A timer for measuring a time during which the moving speed of the print head is equal to or lower than a predetermined allowable lower limit value between the start of movement of the print head and the end of movement; Based on the time, it can also be determined whether the print head performs a stick-slip operation. The motor control unit may vary the command value for controlling the motor depending on whether or not the print head is in the stick-slip region stored in the storage unit. In this case, it is desirable to move the print head from a stopped state. The motor control unit may vary the command value for controlling the motor depending on whether or not the print head is in the stick-slip region stored in the storage unit. It may be when the print head moves and enters. The motor control unit may vary the command value for controlling the motor depending on whether or not the print head is in the stick-slip region stored in the storage unit. It may be when the position and the target stop position of the print head are in the stick-slip region. The print head preferably includes a nozzle that ejects ink toward the medium in order to perform printing on the medium. In this way, since the stick-slip region based on the position where the stick-slip operation occurs is stored in advance, the stick-slip operation can be handled earlier than the stick-slip operation after the stick-slip operation is detected. be able to.

Generating a command value for controlling a motor for moving the print head in order to move the print head that performs printing on the medium along a guide unit that guides the print head along a predetermined direction; When,
Storing a stick-slip area set based on a position where the print head performs a stick-slip operation in the guide unit in a storage unit;
Differentiating the command value for controlling the motor depending on whether the print head is in the stick-slip area stored in the storage unit; and
Including stick-slip handling method.

  In this way, since the stick-slip region based on the position where the stick-slip operation occurs is stored in advance, the stick-slip operation can be handled earlier than the stick-slip operation after the stick-slip operation is detected. be able to.

Generating a command value for controlling a motor for moving the print head in order to move the print head that performs printing on the medium along a guide unit that guides the print head along a predetermined direction; When,
Storing a stick-slip area set based on a position where the print head performs a stick-slip operation in the guide unit in a storage unit;
Differentiating the command value for controlling the motor depending on whether the print head is in the stick-slip area stored in the storage unit; and
A program that executes.

A printing system comprising a computer and a printing device connectable to the computer,
A print head for printing on a medium;
A motor for moving the print head;
A guide portion for guiding the print head along a predetermined direction;
A storage unit that stores a stick-slip region set based on a position at which the print head performs a stick-slip operation in the guide unit;
A motor control unit that generates a command value for controlling the motor, the command for controlling the motor depending on whether or not the print head is in the stick-slip area stored in the storage unit A motor control unit for different values;
A printing system comprising:

=== Overview of Printing Apparatus ===
An embodiment of a printing apparatus according to the present invention will be described using an inkjet printer 1 as an example. 1 to 4 show the ink jet printer 1. FIG. 1 shows the appearance of the inkjet printer 1. FIG. 2 shows the internal configuration of the inkjet printer 1. FIG. 3 shows the configuration of the transport section of the inkjet printer 1. FIG. 4 shows the system configuration of the inkjet printer 1.

  As shown in FIG. 1, the ink jet printer 1 has a structure for discharging a medium such as printing paper supplied from the back surface from the front surface, and an operation panel 2 and a paper discharge portion 3 are provided on the front surface portion. The paper feeding unit 4 is provided on the back side. Various operation buttons 5 and display lamps 6 are provided on the operation panel 2. The paper discharge unit 3 is provided with a paper discharge tray 7 that closes the paper discharge port when not in use. The paper feed unit 4 is provided with a paper feed tray 8 for holding a medium such as cut paper.

  Inside the ink jet printer 1, a carriage 41 is provided as shown in FIG. The carriage 41 is provided to be relatively movable along the left-right direction. Around the carriage 41, a carriage motor 42, a pulley 44, a timing belt 45, and a guide rail 46 are provided. The carriage motor 42 is constituted by a DC motor or the like, and is a drive source for relatively moving the carriage 41 in the left-right direction (hereinafter also referred to as the carriage movement direction). The timing belt 45 is connected to the carriage motor 42 via the pulley 44, and a part of the timing belt 45 is connected to the carriage 41. The carriage 41 is moved relative to the carriage 41 in the carriage movement direction (left-right direction) by the rotation of the carriage motor 42. Move. The guide rail 46 guides the carriage 41 along the carriage movement direction (left-right direction).

  In addition, in the periphery of the carriage 41, a linear encoder 51 that detects the position of the carriage 41 and a direction in which the medium S intersects the moving direction of the carriage 41 (the front-rear direction in the figure, hereinafter also referred to as the transport direction). A transport roller 17A for transporting along the transport path 17 and a transport motor 15 for rotationally driving the transport roller 17A are provided.

  On the other hand, the carriage 41 is provided with an ink cartridge 48 that stores various inks, and a head 21 that performs printing on the medium S. The ink cartridge 48 contains, for example, each color ink such as yellow (Y), magenta (M), cyan (C), black (K), and is detachable from a cartridge mounting portion 49 provided on the carriage 41. It is attached to. In the present embodiment, the head 21 performs printing by ejecting ink onto the medium S. For this purpose, the head 21 is provided with a number of nozzles for ejecting ink.

  The head 21 corresponds to a “print head” that performs printing on the medium S. The guide rail 46 corresponds to a “guide portion” because it guides the carriage 41 (including the head 21) along a predetermined direction. The carriage motor 42 is a motor for moving the carriage 41 and therefore corresponds to a “motor”.

  In addition to this, in the inkjet printer 1, printing is performed in order to prevent clogging of the nozzles of the head 21 and the pump device 31 that sucks out ink from the nozzles in order to eliminate clogging of the nozzles of the head 21. A capping device 35 that seals the nozzles of the head 21 when not in use (such as during standby) is provided.

  Next, the conveyance unit of the inkjet printer 1 will be described. As shown in FIG. 3, the transport unit includes a paper feed roller 13, a paper detection sensor 53, a transport roller 17A, a paper discharge roller 17B, a platen 14, and free rollers 18A and 18B. Yes.

  The medium S to be printed is set in the paper feed tray 8. The medium S set in the paper feed tray 8 is conveyed along the direction of arrow A in the drawing by the paper feed roller 13 having a substantially D-shaped cross section, and is sent into the ink jet printer 1. The medium S sent to the inside of the ink jet printer 1 comes into contact with the paper detection sensor 53. The paper detection sensor 53 is installed between the paper feed roller 13 and the transport roller 17A, and detects the medium S fed by the paper feed roller 13.

The medium S detected by the paper detection sensor 53 is sequentially transported to the platen 14 on which printing is performed by the transport roller 17A. A free roller 18A is provided at a position facing the conveying roller 17A. The medium S is smoothly transported by sandwiching the medium S between the free roller 18A and the transport roller 17A.
The medium S sent to the platen 14 is sequentially printed by the ink ejected from the head 21. The platen 14 is provided to face the head 21 and supports the medium S to be printed from below.

  The medium S on which printing has been performed is sequentially discharged out of the printer by the paper discharge roller 17B. The paper discharge roller 17B is driven in synchronism with the transport motor 15, and sandwiches the medium S with the free roller 18B provided facing the paper discharge roller 17B, and discharges the medium S to the outside of the printer. To do.

<System configuration>
Next, the system configuration of the inkjet printer 1 will be described. As shown in FIG. 4, the inkjet printer 1 includes a buffer memory 122, an image buffer 124, a controller 126, a main memory 127, a communication interface 129, a carriage motor control unit 128, a transport control unit 130, A head driving unit 132.

  The communication interface 129 is for the inkjet printer 1 to exchange data with an external computer 140 such as a personal computer. The communication interface 129 is communicably connected to the external computer 140 by wire or wireless, and receives various data such as print data transmitted from the computer 140.

  Various data such as print data received by the communication interface 129 are temporarily stored in the buffer memory 122. The image buffer 124 sequentially stores print data stored in the buffer memory 122. The print data stored in the image buffer 124 is sequentially sent to the head driving unit 132. The main memory 127 is composed of ROM, RAM, EEPROM, and the like. The main memory 127 stores various programs for controlling the inkjet printer 1 and various setting data.

  The controller 126 reads a control program, each setting data, and the like from the main memory 127, and controls the entire inkjet printer 1 according to the control program and various setting data. The controller 126 receives detection signals from various sensors such as the rotary encoder 134, the linear encoder 51, and the paper detection sensor 53.

  When various data such as print data sent from the external computer 140 is received by the communication interface 129 and stored in the buffer memory 122, the controller 126 stores necessary information from the stored data in the buffer memory. Read from 122. Based on the read information, the controller 126 refers to the output from the linear encoder 51 and the rotary encoder 134 and controls the carriage motor control unit 128, the conveyance control unit 130, the head drive unit 132, and the like according to the control program. Control each one.

  The carriage motor control unit 128 drives and controls the rotation direction, number of rotations, torque, and the like of the carriage motor 42 in accordance with a command from the controller 126. The conveyance control unit 130 controls the conveyance motor 15 that rotationally drives the conveyance roller 17 </ b> A according to a command from the controller 126.

  The head drive unit 132 drives and controls the nozzles of each color provided in the head 21 based on the print data stored in the image buffer 124 in accordance with a command from the controller 126.

  In this embodiment, the carriage motor control unit 128 controls the carriage motor 42 for moving the carriage 41 (head 21), and thus corresponds to a “motor control unit”.

<Head>
FIG. 5 is a diagram showing the arrangement of the ink nozzles provided on the lower surface of the head 21. On the lower surface of the head 21, as shown in the figure, nozzles comprising a plurality of nozzles # 1 to # 180 for each color of yellow (Y), magenta (M), cyan (C), and black (K). A cyan nozzle row 211C, a magenta nozzle row 211M, a yellow nozzle row 211Y, and a black nozzle row 211K are provided.

  The nozzles # 1 to # 180 of the nozzle rows 211C, 211M, 211Y, and 211K are arranged in a line in a straight line at intervals from each other along a predetermined direction (here, the transport direction of the medium S). ing. The nozzle rows 211C, 211M, 211Y, and 211K are arranged in parallel at predetermined intervals along the moving direction (scanning direction) of the head 21. Each nozzle # 1 to # 180 is provided with a piezo element (not shown) as a drive element for ejecting ink droplets.

=== Linear encoder ===
<Configuration of encoder>
FIG. 6 schematically shows the configuration of the linear encoder 51. The linear encoder 51 includes a linear encoder code plate 464 and a detection unit 466. As shown in FIG. 2, the linear encoder code plate 464 is attached to the frame side inside the inkjet printer 1. On the other hand, the detection unit 466 is attached to the carriage 41 side. When the carriage 41 moves along the guide rail 46, the detection unit 466 moves relatively along the linear encoder code plate 464. Accordingly, the detection unit 466 detects the movement amount of the carriage 41.

<Configuration of detection unit>
FIG. 7 schematically shows the configuration of the detection unit 466. The detection unit 466 includes a light emitting diode 452, a collimator lens 454, and a detection processing unit 456. The detection processing unit 456 includes a plurality of (for example, four) photodiodes 458, a signal processing circuit 460, and, for example, two comparators 462A and 462B.

  When the voltage Vcc is applied to both ends of the light emitting diode 452 via a resistor, light is emitted from the light emitting diode 452. This light is condensed into parallel light by the collimator lens 454 and passes through the linear encoder code plate 464. The linear encoder code plate 464 is provided with slits at predetermined intervals (for example, 1/180 inch (1 inch = 2.54 cm)).

  The parallel light that has passed through the linear encoder code plate 464 enters each photodiode 458 through a fixed slit (not shown) and is converted into an electrical signal. The electric signals output from the four photodiodes 458 are subjected to signal processing in the signal processing circuit 460, the signals output from the signal processing circuit 460 are compared in the comparators 462A and 462B, and the comparison result is output as a pulse. Pulses ENC-A and ENC-B output from the comparators 462A and 462B are output from the linear encoder 51.

<Output signal>
8A and 8B are timing charts showing waveforms of two output signals of the detection unit 466 when the carriage motor 42 is rotating forward and when the carriage motor 42 is rotating forward. As shown in FIGS. 8A and 8B, the phase of the pulse ENC-A and the pulse ENC-B are different from each other by 90 degrees in both cases of forward rotation and reverse rotation of the carriage motor 42. When the carriage motor 42 is rotating forward, that is, when the carriage 41 is moving along the guide rail 46, the pulse ENC-A is 90 degrees more than the pulse ENC-B, as shown in FIG. 8A. When the phase advances and the carriage motor 42 reverses, the phase of the pulse ENC-A is delayed by 90 degrees from the pulse ENC-B as shown in FIG. 8B. One cycle T of the pulse ENC-A and the pulse ENC-B is equal to the time during which the carriage 41 moves through the slit interval of the linear encoder code plate 464.

  Then, rising edges of the output pulses ENC-A and ENC-B of the linear encoder 51 are detected, the number of detected edges is counted, and the rotational position of the carriage motor 42 is calculated based on the counted value. The This count is incremented by "+1" when one edge is detected when the carriage motor 42 is rotating forward, and is "-1" when one edge is detected when rotating reversely. Is added. The period of each of the pulses ENC-A and ENC-B is equal to the time from when one slit passes through the detection unit 466 until the next slit passes through the detection unit 466 of the linear encoder code plate 464, and The pulse ENC-A and the pulse ENC-B are different in phase by 90 degrees. For this reason, the count value “1” of the count corresponds to ¼ of the slit interval of the linear encoder code plate 464. Thus, if the count value is multiplied by ¼ of the slit interval, the amount of movement of the carriage motor 42 from the rotational position corresponding to the count value “0” can be obtained based on the multiplication value. At this time, the resolution of the linear encoder 51 is ¼ of the slit interval of the linear encoder code plate 464.

=== Carriage motor control unit ===
The configuration of the carriage motor control unit 128 will be described in detail. FIG. 9 is a block configuration diagram illustrating an example of a circuit configuration of the carriage motor control unit 128. As shown in the figure, the carriage motor control unit 128 includes a position calculation unit 331, a subtracter 332, a gain 333, a speed calculation unit 334, a subtractor 335, a proportional element 336A, an integration element 336B, It has a differential element 336C, an adder 337, a PWM circuit 338, an acceleration control unit 339A, and a timer 339B.

  The position calculation unit 331 detects the edge of the output pulse of the linear encoder 51, counts the number thereof, and calculates the rotational position of the carriage motor 42 based on the count value. The position calculation unit 331 recognizes normal rotation / reverse rotation of the carriage motor 42 from the comparison processing of the two pulse signals from the linear encoder 51, and increments according to normal rotation / reverse rotation when one edge is detected. Counting process to decrement.

The subtractor 332 calculates a position deviation between the target position sent from the controller 126 and the detected position detected by the position calculation unit 331. The gain 333 multiplies the position deviation output from the subtracter 332 by the gain Kp, and outputs the target speed Vt. The gain Kp is determined according to the position deviation.
The speed calculation unit 334 measures the pulse period of the output pulse of the linear encoder 51 and calculates the rotation speed Vc of the carriage motor 42 based on this pulse period.
The subtractor 335 calculates a speed deviation ΔV between the target speed Vt output from the gain 333 and the detected speed Vc detected by the speed calculator 334.

  The proportional element 336A multiplies the speed deviation ΔV by the amplification factor Gp and outputs a proportional component QP. The integration element 336B integrates the speed deviation ΔV multiplied by the amplification factor Gi with the previous calculation result QI (j−1), and outputs an integration component QI. The differential element 336C multiplies the difference between the current speed deviation ΔV (j) (where j indicates the time) and the previous speed deviation ΔV (j−1) by the amplification factor Gd to obtain a differential component. QD is output. The differential element 336C corresponds to a calculation unit that calculates the amount of change per unit time of the moving speed of the carriage (print head). The calculation of the proportional element 336A, the integral element 336B, and the differential element 336C is performed for each cycle of the output pulse of the linear encoder 51.

Here, the calculation outputs of the calculation elements 336A, 336B, and 336C, that is, the proportional component QP, the integral component QI, and the differential component QD can be given by the following equations (1) to (3), for example.
QP (j) = ΔV (j) × Gp (1)
QI (j) = QI (j−1) + ΔV (j) × Gi (2)
QD (j) = {ΔV (j) −ΔV (j−1)} × Gd (3)

  The adder 337 adds the proportional component QP of the proportional element 336A, the integral component QI of the integral element 336B, and the differential component QD of the differential element 336C. The addition result ΣQ of these three components, that is, the proportional component QP, the integral component QI, and the differential component QD is output to the PWM circuit 338 as a duty signal.

The addition result ΣQ can be obtained by the following equation (4).
ΣQ (j) = QP (j) + QI (j) + QD (j) (4)

  The PWM circuit 338 generates a control signal corresponding to the addition result ΣQ of the adder 337. The driver 340 drives the carriage motor 42 based on this control signal. The driver 340 includes a plurality of transistors, for example, and applies a voltage to the carriage motor 42 by turning on and off the transistors based on a control signal from the PWM circuit 338.

  The acceleration control unit 339A and the timer 339B are used during acceleration control of the carriage motor 42. The timer 339B generates a timer interrupt signal every predetermined time based on the clock signal sent from the controller 126. The acceleration control unit 339A integrates a predetermined duty DXP every time a timer interrupt signal is received, generates a duty signal as an integration result, and outputs the duty signal to the PWM circuit 338.

  When the carriage motor 42 is driven to accelerate, the PWM circuit 338 generates a control signal based on the duty signal output from the acceleration control unit 339A to control the carriage motor 42. When the carriage motor 42 is driven at a constant speed and when the carriage motor 42 is decelerated, the PWM circuit 338 has three components, that is, a proportional component QP of the proportional element 336A, an integral component QI of the integral element 336B, and A control signal generated based on the duty signal output from the adder 337 as the addition result ΣQ of the differential component QD of the differential element 336C is output to the carriage motor 42 to control the carriage motor 42.

=== Driving method of carriage motor ===
FIG. 10A is a graph of the time change of the duty signal input to the PWM circuit 338. FIG. 10B is a graph of the speed change of the carriage motor 42. Hereinafter, the driving of the carriage motor 42 will be described with reference to these drawings.

  When a start command signal for starting the carriage motor 42 is sent from the controller 126 to the carriage motor control unit 128 while the carriage motor 42 is stopped, a start initial duty signal whose signal value is DX0 is sent from the acceleration control unit 339A to the PWM. Sent to circuit 338. This startup initial duty signal is sent from the controller 126 to the acceleration control unit 339A together with the startup command signal. The start initial duty signal is converted into a control signal corresponding to the signal value DX0 by the PWM circuit 338, and the start of the carriage motor 42 is started.

  After the carriage motor control unit 128 receives the start command signal, a timer interrupt signal is generated from the timer 339B every predetermined time. Every time the acceleration control unit 339A receives a timer interrupt signal, the acceleration control unit 339A accumulates a predetermined duty DXP on the signal value DX0 of the startup initial duty signal, and sends a duty signal having the accumulated duty as a signal value to the PWM circuit 338. . The duty signal is converted into a control signal corresponding to the signal value by the PWM circuit 338, and the rotation speed of the carriage motor 42 increases. For this reason, the value of the duty signal sent from the acceleration control unit 339A to the PWM circuit 338 increases stepwise.

  The duty integration process in the acceleration control unit 339A is performed until the integrated duty reaches a predetermined duty DXS. When the duty integrated at time t1 reaches a predetermined value DXS, the acceleration control unit 339A stops the integration process, and thereafter sends a duty signal having a constant duty DXS as a signal value to the PWM circuit 338.

  When the carriage motor 42 reaches a predetermined rotation speed (see time t2), the acceleration control unit 339A decreases the duty signal output to the PWM circuit 338 and decreases the duty percentage of the voltage applied to the carriage motor 42. To control. At this time, the rotational speed of the carriage motor 42 further increases. At time t3, the PWM circuit 338 selects the output of the adder 337, and PID control is performed. At the time (t3) when the PID control is started, the integral value of the integral element 336B is set to an appropriate value, and the output value of the integral element 336B becomes a predetermined value.

  When the PID control is started, the carriage motor control unit 128 calculates the target speed Vt by multiplying the position deviation between the target rotational position and the actual rotational position obtained from the output of the linear encoder 51 by the gain Kp. . Then, the carriage motor control unit 128 sets the proportional element 336A, the integral element 336B, and the differential element 336C based on the speed deviation ΔV between the target speed Vt and the actual rotational speed Vc obtained from the output of the linear encoder 51. The proportional component QP, the integral component QI, and the differential component QD are calculated using this, and the carriage motor 42 is controlled based on the sum ΣQ of these calculation results. The proportional calculation, integral calculation, and differential calculation are performed in synchronization with the rising edge of the output pulse ENC-A of the linear encoder 51, for example. Thereby, the rotation speed of the carriage motor 42 is controlled to be a desired rotation speed at time t4.

  When the carriage motor 42 approaches the target rotation position (time t5), the position deviation decreases, so the target rotation speed also decreases. Therefore, the speed deviation, that is, the output of the subtractor 335 becomes negative, the carriage motor 42 decelerates, and stops at time t6.

=== Printing operation ===
Next, the printing operation of the above-described ink jet printer 1 will be described. Here, “bidirectional printing” will be described as an example. FIG. 11 is a flowchart showing an example of the processing procedure of the printing operation of the inkjet printer 1. Each process described below is executed by the controller 126 reading a program from the main memory 127 and controlling the carriage motor control unit 128, the conveyance control unit 130, the head drive unit 132, and the like according to the program. The

  Upon receiving print data from the computer 140, the controller 126 first performs a paper feed process to execute printing based on the print data (S102). The paper feed process is a process of supplying the medium S to be printed into the ink jet printer 1 and transporting it to a print start position (also referred to as a cue position). The controller 126 rotates the paper feed roller 13 to send the medium S to be printed to the transport roller 17A. The controller 126 rotates the transport roller 17A to position the medium S sent from the paper feed roller 13 at the print start position (near the upper side of the platen 14).

  Next, the controller 126 drives the carriage motor 42 through the carriage motor control unit 128 and moves the carriage 41 relative to the medium S to execute a printing process for printing on the medium S. Here, first, forward printing is performed to eject ink from the head 21 while moving the carriage 41 in one direction along the guide rail 46 (S104). The controller 126 drives the carriage motor 42 to move the carriage 41 and drives the head 21 based on the print data to eject ink. The ink ejected from the head 21 reaches the medium S and is formed as dots.

  After printing in this way, the controller 126 next executes a transport process for transporting the medium S by a predetermined amount (S106). Here, the controller 126 drives the conveyance motor 15 through the conveyance control unit 130 to rotate the conveyance roller 17A, and conveys the medium S by a predetermined amount relative to the head 21 in the conveyance direction. By this carrying process, the head 21 can print in an area different from the previously printed area.

  After performing the carrying process in this manner, the controller 126 determines whether or not to discharge paper (S108). Here, if there is no other data to be printed on the medium S being printed, the controller 126 executes a paper discharge process (S116). On the other hand, if there is other data to be printed on the medium S being printed, the controller 126 performs the backward printing without performing the paper discharge process (S110). In this backward printing, printing is performed by moving the carriage 41 along the guide rail 46 in the direction opposite to the previous forward printing. Again, the controller 126 rotates the carriage motor 42 through the carriage motor control unit 128 to move the carriage 41 in the reverse direction, and also drives the head 21 based on the print data to eject ink and print. Apply.

  After performing the return pass printing, a carrying process is executed (S112), and then a paper discharge determination is made (S114). Here, if there is other data to be printed on the medium S being printed, the paper discharge process is not performed, the process returns to step S104, and the forward printing is executed again (S104). On the other hand, if there is no other data to be printed on the medium S being printed, a paper discharge process is executed (S116).

  After the paper discharge process is performed, next, a print end determination is performed to determine whether or not to end printing (S118). Here, based on the print data from the computer 140, it is checked whether there is a medium S to be printed next. If there is a medium S to be printed next, the process returns to step S102, the paper feed process is executed again, and printing is started. On the other hand, if there is no medium S to be printed next, the printing process is terminated.

=== Stick-slip operation ===
In such an ink jet printer 1, the carriage 41 (printing head) does not slide well along the guide rail 46 when it is not used for a long period of time, and the moving speed of the carriage 41 is periodically increased. There is a case where a so-called stick-slip operation (also referred to as a sucking operation) is performed in which the operation of moving or stopping the carriage 41 is repeated.

  In this stick-slip operation, the speed is periodically increased or decreased. In an extreme case, it becomes a jerky sliding motion in which the carriage 41 is repeatedly moved and stopped. This stick-slip operation is also called fixed slip. The main cause of such stick-slip operation is considered to be the difference between the coefficient of static friction and the coefficient of dynamic friction of the sliding portion between the carriage 41 and the guide rail 46 that guides it. That is, since the static friction coefficient of the sliding portion between the carriage 41 and the guide rail 46 is very large compared to the dynamic friction coefficient, the carriage 41 does not move easily even if the torque of the carriage motor 42 increases. When the torque of the carriage motor 42 reaches a certain level, the carriage 41 starts to move. When the carriage 41 starts to move, the moving friction coefficient rapidly decreases because the coefficient of dynamic friction is low. When the moving speed of the carriage 41 is rapidly increased in this way, the carriage motor control unit 128 applies rapid braking to the carriage motor 42 in order to suppress the moving speed of the carriage 41. For this reason, the carriage 41 is stalled.

  FIG. 12 shows an example of a change in the moving speed of the carriage 41 when the carriage 41 performs a stick-slip operation. As shown in the figure, the carriage 41 does not start to move unless the torque of the carriage motor 42 increases to some extent.

  When the moving speed of the carriage 41 becomes zero, an activation command signal is issued from the controller 126. When the start command signal is issued, the PWM circuit 338 selects the output from the acceleration control unit 339A. Further, the acceleration control unit 339A increases the duty signal value by DXP by setting the initial value to DX0. When the duty signal value becomes DXP, the PWM circuit 338 selects the output of the adder 337, and the carriage motor 42 is PID-controlled.

  The moving speed of the carriage 41 is detected by the speed calculation unit 334 (see FIG. 9). The carriage motor control unit 128 monitors the moving speed of the carriage 41 through the speed calculation unit 334. When the moving speed of the carriage 41 does not increase, the carriage motor control unit 128 performs control to increase the torque of the carriage motor 42 in order to move the carriage 41. As a result, when the torque of the carriage motor 42 increases to some extent, the carriage 41 starts to move, and the moving speed of the carriage 41 rapidly increases. When the moving speed of the carriage 41 increases and reaches a predetermined level, the carriage motor control unit 128 applies braking to the carriage motor 42 in order to suppress the moving speed of the carriage 41. As a result, the moving speed of the carriage 41 decreases, and the carriage 41 stalls and stops again.

  When the carriage 41 stops, an activation command signal is issued from the controller 126 again. Then, acceleration control by the acceleration control unit 339A is performed again, and when the predetermined duty signal value is reached, the process shifts to PID control. Then, the carriage motor control unit 128 performs control to increase the torque of the carriage motor 42 again in order to move the carriage 41. As a result, when the carriage 41 starts to move again and the moving speed rapidly increases, the carriage 41 stalls again and stops. Such a movement operation and a stop operation are alternately repeated.

=== When stick-slip motion occurs ===
The carriage 41 performs such a stick-slip operation when the carriage motor control unit 128 attempts to move the carriage 41 at a constant speed below a predetermined speed via the carriage motor 42. That is, when the carriage 41 moves at a constant speed exceeding a predetermined speed, that is, for example, when the carriage 41 moves at a very high speed during execution of printing, the stick-slip operation hardly occurs. Here, the predetermined speed refers to an upper limit speed at which the carriage 41 may perform a stick-slip operation.

  Examples of cases where the carriage 41 moves at a constant speed below a predetermined speed at which a stick-slip operation is performed include the following cases (1) to (4).

(1) Ink cartridge replacement In this case, the ink cartridge 48 (see FIG. 2) mounted on the carriage 41 is replaced by a user or the like. When the ink cartridge 48 is replaced by a user or the like, it is necessary to move the carriage 41 to a predetermined position so that the ink cartridge 48 can be easily replaced by the user or the like. In this case, it is necessary to move the carriage 41 slowly at a low speed below a predetermined speed so that the user or the like does not carelessly come into contact with the carriage 41.

(2) During capping When the carriage 41 moves to a position where the capping device 35 (see FIG. 2) is provided. When printing is not performed (such as during standby), the carriage 41 moves to the installation position of the capping device 35 to prevent the nozzles # 1 to # 180 of the head 21 from being clogged. An operation of sealing 1 to # 180 is performed. In such a case, the carriage 41 is slowly moved at a low speed below a predetermined speed.

(3) When the power is turned on When the power is turned on, the carriage 41 moves away from the capping device 35 to prepare for execution of the printing process, for example, to clean the nozzles # 1 to # 180 of the head 21, etc. Start operation. In such a case, the carriage 41 is slowly moved at a low speed below a predetermined speed. A stick-slip area, which will be described later, is also set when the power is turned on. At this time, the carriage 41 is moved at a low speed below a predetermined speed.

(4) During paper width detection The carriage 41 moves along the guide rail 46 in order for the ink jet printer 1 to detect the width of the medium S to be printed by an optical sensor (not shown) provided on the carriage 41. . At this time, in order to accurately check the width of the medium S, the carriage 41 slowly moves at a low speed below a predetermined speed.

  In the case where the carriage 41 moves at a constant speed below a predetermined speed at which a stick-slip operation is performed, other cases than those described in (1) to (4) may be used.

=== Judgment method of stick-slip motion ===
When the carriage 41 performs such a stick-slip operation, the carriage 41 cannot be stopped at the target position, and problems such as moving the carriage 41 around the target position may occur. there were. When such a stick-slip operation occurs, it may take time to stop at the target position. For this reason, when the carriage 41 performs a stick-slip operation, it is necessary to quickly detect and respond to this.

  Therefore, in the inkjet printer 1 according to the present embodiment, whether or not the carriage 41 has performed the stick-slip operation in order to be able to respond smoothly when the carriage 41 performs such a stick-slip operation. Can be determined. Here, the controller 126 determines whether or not the carriage 41 has performed a stick-slip operation. As a determination method of the stick-slip operation, for example, there are the following methods (1) to (4).

(1) Determination Based on Moving Speed Based on the moving speed of the carriage 41, it is determined whether the carriage 41 has performed a stick-stick operation. As one of the determination methods, there is a method of determining that the carriage 41 is performing a stick-slip operation when the moving speed of the carriage 41 exceeds a predetermined threshold value V0. When the carriage 41 performs a stick-slip operation, as described in FIG. 13A, the moving speed of the carriage 41 increases rapidly when the carriage 41 starts to move. At this time, the moving speed of the carriage 41 reaches a speed much faster than the original moving speed of the carriage 41. From this, an appropriate predetermined threshold value V0 is set, and whether or not the carriage 41 has performed a stick-slip operation by checking whether or not the moving speed of the carriage 41 exceeds the predetermined threshold value V0. You can easily check whether or not.

  In addition to this, as a method for determining whether or not the carriage 41 has performed the stick-slip operation based on the moving speed of the carriage 41, as described in FIG. 13B, the moving speed of the carriage 41 is a predetermined upper limit allowable value. There is a method of determining that the carriage 41 is performing a stick-slip operation when V1 is exceeded and then falls below a predetermined lower limit allowable value V2. When the carriage 41 performs a stick-slip operation, as shown in the figure, the moving speed of the carriage 41 increases rapidly when the carriage 41 starts to move, and then decreases rapidly. Eventually, the carriage 41 may stall and become close to a stopped state. The moving speed of the carriage 41 reaches a speed much faster than the originally assumed upper limit allowable value V1 of the carriage 41, and then rapidly decreases to the lower limit allowable value of the expected moving speed of the carriage 41. A speed lower than V2 (including the stop state) is reached. From this, it can be easily determined whether or not the carriage 41 has performed a stick-slip operation.

  Here, in determining whether or not the carriage 41 has performed the stick-slip operation, the number of times that the moving speed of the carriage 41 has exceeded a predetermined threshold value V0 is counted, and the number of times is the predetermined number of times. When (for example, twice) is exceeded, it may be determined that the carriage 41 is performing a stick-slip operation. Further, the number of times that the moving speed of the carriage 41 exceeds the predetermined upper limit allowable value V1 and then falls below the predetermined lower limit allowable value V2 is counted, and the number of times exceeds a predetermined number (for example, twice). It may be determined that the carriage 41 is performing a stick-slip operation.

(2) Determination Based on Control Signal Based on the control signal generated for the carriage motor control unit 128 to control the carriage motor 42, it is determined whether or not the carriage 41 has performed a stick-slip operation. Here, the control signal is determined based on, for example, a duty signal input to the PWM circuit 338 (see FIG. 9) of the carriage motor control unit 128.

  FIG. 14A illustrates the relationship between the movement speed of the carriage 41 when the carriage 41 performs a stick-slip operation and the signal value of the duty signal input to the PWM circuit 338. When the carriage 41 performs a stick-slip operation, the moving speed of the carriage 41 increases rapidly and then decreases rapidly as shown in the upper part of FIG. The carriage 41 repeats such a movement operation and a stop operation alternately.

  On the other hand, the duty signal value is as follows. When the speed of the carriage 41 is increased from 0 (the carriage motor 42 is stopped), an activation command signal is issued from the controller 126. Then, the PWM circuit 338 of the carriage motor control unit 128 selects the output of the acceleration control unit 339A. Further, the acceleration control unit 339A outputs the startup initial duty value DX0 to the PWM circuit 338. Thereafter, the duty signal is increased in increments of the predetermined value DXP by acceleration control by the acceleration control unit 339A until the predetermined value is reached. When the duty signal value reaches the predetermined value DXS, the PWM circuit 338A selects the output (PID control) from the adder 337 from the output of the acceleration control unit 339A.

  It should be noted that while the control by the acceleration control unit 339A is being performed, the duty signal value seems to increase continuously, but since this is incremented every 4 (ms), it continues macroscopically. It seems to increase, and it actually increases in a stepped manner.

  Even after the PID control is selected, the carriage 41 does not start moving. For this reason, the duty signal value continues to increase while being smaller than in the case of control by the acceleration control unit 339A. If the duty signal value continues to increase, the moving speed of the carriage 41 increases rapidly at a certain time. Then, the carriage motor control unit 128 abruptly decreases the signal value of the duty signal input to the PWM circuit 338 so as to suppress the moving speed of the carriage 41. As a result, the speed of the carriage 41 also decreases rapidly. Then, the carriage motor control unit 128 tries to increase the duty value abruptly in order to control the speed of the carriage 41 so as to become a predetermined speed. Stops.

  When the carriage 41 stops and the moving speed becomes zero, a start command signal is issued again from the controller, and the PWM circuit 338 selects acceleration control by the acceleration control unit 339A from PID control. The acceleration control unit 339A outputs a signal value DX0 of the startup initial duty signal. Then, the acceleration control unit 339A gradually increases the signal value of the duty signal in increments of DXP. Thereafter, the control shifts to PID control. However, since the moving speed of the carriage 41 suddenly increases at a certain time, the carriage motor control unit 128 rapidly decreases the driving force of the carriage motor 42, and the carriage 41 It will stop again.

  In this way, the signal value of the duty signal input to the PWM circuit 338 repeatedly fluctuates.

  In practice, as a method for determining whether or not the carriage 41 has performed the stick-slip operation, here, the maximum value Vmax and the minimum value Vmin of the signal value of the duty signal input to the PWM circuit 338 are examined, and the maximum value is obtained. Based on the difference ΔV between Vmax and the minimum value Vmin, it is determined whether or not the carriage 41 has performed a stick-slip operation. That is, it is checked whether or not the difference ΔV between the maximum value Vmax and the minimum value Vmin of the signal value of the due signal exceeds a predetermined threshold value V0, and when the difference ΔV exceeds the predetermined threshold value V0. Then, it is determined that the carriage 41 is performing a stick-slip operation. On the other hand, if the difference ΔV between the maximum value Vmax and the minimum value Vmin of the signal value of the due signal does not exceed the predetermined threshold value V0, it is determined that the carriage 41 has not performed the stick-slip operation.

  FIG. 14B explains in detail an example of the determination method. First, the maximum value Vmax and the minimum value Vmin of the signal value of the due signal are acquired. A difference ΔV is obtained from the acquired maximum value Vmax and minimum value Vmin. When the carriage 41 performs a stick-slip operation, as shown in the figure, the difference ΔV is large between the maximum value Vmax and the minimum value Vmin of the signal value of the duty signal. By comparing this difference ΔV with a predetermined threshold value V0, it can be easily determined whether or not the carriage 41 has performed a stick-slip operation.

Here, in determining whether or not the carriage 41 has performed the stick-slip operation, the difference ΔV between the maximum value Vmax and the minimum value Vmin of the signal value of the duty signal input to the PWM circuit 338 is a predetermined value. When the threshold value V0 is exceeded a predetermined number of times (for example, twice or more), it may be determined that the carriage 41 is performing a stick-slip operation.
Further, as a method for determining whether or not the carriage 41 has performed the stick-slip operation based on the control signal, other than the determination based on the difference ΔV between the maximum value Vmax and the minimum value Vmin of the signal value of the due signal, there are other methods. It may be determined by a method.

(3) Determination Based on Acceleration Here, it is determined based on the acceleration of the carriage 41 whether or not the carriage 41 has performed a stick-slip operation. Here, the acceleration is acquired by the speed calculation unit 334 (see FIG. 9) of the carriage motor control unit 128. That is, the speed calculation unit 334 periodically outputs the moving speed of the carriage 41 detected based on the output from the linear encoder 51 at predetermined time intervals. The controller 126 acquires the acceleration of the carriage 41 from the difference in the moving speed of the carriage 41 periodically sent from the speed calculation unit 334, and determines whether or not the carriage 41 has performed a stick-slip operation based on this difference. To do.

  FIG. 15 illustrates an example of a method for determining whether or not a stick-slip operation has been performed based on the acceleration of the carriage 41. When the carriage 41 performs a stick-slip operation, the moving speed of the carriage 41 increases rapidly and then decreases rapidly as shown in FIG. Since the acceleration of the carriage 41 becomes very large in this way, it is possible to determine whether or not the carriage 41 has performed a stick-slip operation by paying attention to this acceleration.

  The controller 126 periodically acquires the movement speeds V1 to V6 of the carriage 41 from the speed calculation unit 334 of the carriage motor control unit 128 at a predetermined time interval T0. Then, the controller 126 sequentially calculates the difference as an acceleration from the acquired movement speeds V1 to V6 of the carriage 41. That is, the controller 126 calculates the difference ΔV21 from the moving speed V1 and the moving speed V2 by “V2−V1”, and the difference ΔV32 from the moving speed V2 and the moving speed V3 by “V3−V2”, and the moving speed V3. The difference ΔV43 from the moving speed V4 by “V4−V3”, the difference ΔV54 by “V5−V4” from the moving speed V4 and the moving speed V5, and the difference by “V6−V5” from the moving speed V5 and the moving speed V6. ΔV65 is calculated respectively.

  The controller 126 compares the obtained differences ΔV21, ΔV32, ΔV43, ΔV54, and ΔV65 with a predetermined threshold value V0, and the differences ΔV21, ΔV32, ΔV43, ΔV54, and ΔV65 exceed the predetermined threshold value V0. Check whether or not. When the differences ΔV21, ΔV32, ΔV43, ΔV54, and ΔV65 exceed a predetermined threshold value V0, the controller 126 determines that the carriage 41 is performing a stick-slip operation. On the other hand, when the differences ΔV21, ΔV32, ΔV43, ΔV54, and ΔV65 do not exceed the predetermined threshold value V0, the controller 126 determines that the carriage 41 is not performing the stick-slip operation.

  Here, it is determined whether or not the carriage 41 has performed a stick-slip operation while paying attention to the acceleration of the carriage 41, but in addition to this, when the carriage 41 is decelerated, that is, minus (−) acceleration (decrease). It may be determined whether or not the carriage 41 has performed a stick-slip operation by paying attention to (speed).

  In determining whether or not the carriage 41 has performed a stick-slip operation, the number of times that the obtained difference exceeds a predetermined threshold value V0 occurs a predetermined number of times or more (for example, two times or more). It may be determined that the carriage 41 is performing a stick-slip operation.

(4) Determination Based on Time Less Than Predetermined Allowable Speed Here, a timer that measures the time during which the movement speed of the carriage 41 becomes less than a predetermined allowable lower limit value from the start of movement of the carriage 41 to the end of movement Based on the measurement time, it is determined whether or not the carriage 41 has performed a stick-slip operation.

  FIG. 16A illustrates the timer 60 provided in the carriage motor control unit 128. As shown in the figure, the timer 60 receives an output signal output from the linear encoder 51 to the speed calculation unit 334 and the position calculation unit 331. The timer 60 monitors the output signal of the linear encoder 51, and starts time measurement when the moving speed of the carriage 41 falls below a predetermined allowable lower limit value. Here, the timer 60 starts time measurement when the pulse period of the output signal from the linear encoder 51 becomes longer than a predetermined period. When the moving speed of the carriage 41 is not less than the predetermined allowable lower limit value, the timer 60 stops time measurement. Thereby, the timer 60 measures the time when the moving speed of the carriage 41 becomes equal to or less than a predetermined allowable lower limit value. Information regarding the measurement time of the timer 60 is transmitted to the controller 126. The controller 126 determines whether or not the carriage 41 has performed a stick-slip operation based on the information regarding the measurement time acquired from the timer 60.

  FIG. 16B illustrates an example of a method for determining whether or not the carriage 41 has performed a stick-slip operation. When the carriage 41 performs a stick-slip operation, as shown in the figure, the moving speed of the carriage 41 increases rapidly and decreases rapidly. The carriage 41 starts to move again after a while. The carriage 41 repeats such a movement operation and a stop operation alternately between the start of movement and the end of movement.

  On the other hand, when the carriage 41 does not perform the stick-slip operation, normally, such a moving operation and a stopping operation are not repeated alternately. That is, the carriage 41 does not move below the predetermined allowable lower limit for a predetermined time or more after the movement is started until the movement is completed. From this, after the carriage 41 starts moving, it is checked whether or not the carriage 41 has performed a stick-slip operation by measuring a time T when the moving speed of the carriage 41 has fallen below a predetermined allowable lower limit value VL. Can do. Here, the predetermined allowable lower limit value VL is set to a sufficiently low speed that cannot be assumed as the moving speed of the carriage 41 when the carriage 41 moves without performing the stick-slip operation. This predetermined allowable lower limit value VL may be set to a value close to “0 (zero)” in order to measure time when the carriage 41 stops, for example.

  The timer 60 monitors the output signal of the linear encoder 51. When the pulse period of the output signal from the linear encoder 51 becomes longer than a predetermined period, the moving speed of the carriage 41 is less than or equal to a predetermined allowable lower limit value VL. It is determined that there is, and time measurement is started. The time measurement by the timer 60 is performed until it is determined that the moving speed of the carriage 41 has exceeded a predetermined allowable lower limit value VL. Thereby, the timer 60 measures a time T when the moving speed of the carriage 41 falls below a predetermined allowable lower limit value VL. The measurement result of the timer 60 is transmitted from the timer 60 to the controller 126. Here, the measurement time T of the timer 60 may be transmitted from the timer 60 to the controller 126 in real time, or after the time measurement by the timer 60 is completed, the measurement time T of the timer 60 may be transmitted. .

  The controller 126 compares the measurement time T transmitted from the timer 60 with a predetermined threshold value T0, and if the measurement time T has reached the predetermined threshold value T0, the carriage 41 performs stick-slip. It is determined that the operation is being performed. On the other hand, if the measurement time T of the timer 60 has not reached the predetermined threshold value T0, the controller 126 determines that the carriage 41 is not performing a stick-slip operation.

Here, in determining whether or not the carriage 41 has performed a stick-slip operation, the number of times that the measurement time T has reached a predetermined threshold value T0 is counted, and the number of times is equal to or greater than a predetermined number (for example, If it occurs, it may be determined that the carriage 41 is performing a stick-slip operation.
Further, as a method for determining whether or not the carriage 41 has performed a stick-slip operation, a method other than these methods (1) to (4) may be used.

=== Embodiment ===
<First Embodiment>
In the inkjet printer 1 according to the first embodiment, when the printer is turned on, the carriage 41 is moved at a constant speed in a forward direction at a speed equal to or lower than a predetermined speed, and the position where the stick-slip operation is detected is specified. Then, a predetermined range centered on the position where the stick-slip operation is detected is stored in the main memory 127 as a stick-slip region. When the carriage 41 is controlled to move at a low speed during the actual printing operation, the duty signal value for controlling the carriage motor 42 is controlled depending on whether or not the carriage 41 is in the stick-slip region. This operation will be described below. The duty signal value corresponds to a command value for controlling the motor.

  FIG. 17 is a diagram for explaining the relationship between the position where the stick-slip operation is detected and the stick-slip region. In FIG. 17, the leftmost end (FIG. 2) in the carriage movement direction is the starting point of the forward path. In this embodiment, the count value at the starting point is set to 0, and the count value increases as the carriage 41 advances in the forward direction (the carriage movement direction to the right in FIG. 2).

  The above-described linear encoder 51 mounted on the ink jet printer 1 can specify the position of the carriage 41 with a resolution of 720 dpi. Then, the count value at the starting point is set to 0, and the count value is incremented every time 720 dpi advances in the forward direction. For example, when the count value is “100”, it indicates that the position is advanced 100/720 inches from the starting point.

  When the power is turned on, a stick-slip area storage operation is performed as one of the initial operations. First, the carriage 41 is moved at a constant speed from the starting point (count value 0) in the forward direction at a speed equal to or lower than a predetermined speed. At this time, the stick-slip operation is detected by any one of the determination methods of the stick-slip operation described above. For example, it is determined based on the moving speed of the carriage 41 whether or not the stick-slip operation is being performed. When the stick-slip operation is detected, a predetermined range centering on the detected position is set as the stick-slip region.

  For example, in FIG. 17, a stick-slip operation is detected at position A. Then, the controller 126 determines the range around the position A as the stick-slip region. For example, if the range a is 100 counts and the count value at the position A is 300, the stick-slip area is a range where the count value is 200 to 400.

  Next, a stick-slip region is set based on this. Here, the start point count value and end point count value of the stick-slip area are stored in the main memory 127. For example, when the stick-slip operation is detected at the position of the count value 300 as described above, the range where the count value is 200 to 400 is stored in the main memory 127 as the stick-slip region.

  FIG. 18A is a diagram showing the start point count value and end point count value of the stick-slip area stored in the main memory 127. For example, in FIG. 18A, the start point count value of the stick-slip region is 200, the end point count value is stored as 400, and the range of the count values 200 to 400 is the stick-slip region.

  FIG. 18B is a processing example when the stick-slip areas overlap. Referring to FIG. 17 again, stick-slip motion is detected at position B and position C. If the count value at position B is 1700 and the count value at position C is 1800, the stick-slip areas corresponding to position B are 1600-1800, and the stick-slip areas corresponding to position C are 1700-1900. In this case, the stick-slip areas overlap in the range of 1700 to 1800. In this case, as shown in the right figure of FIG. 18B, the range of 1600 to 1900 is stored as the stick-slip area.

  Processing when the stick-slip regions overlap is performed, for example, as follows. First, 1600 is recorded as the start point count value and 1800 is recorded as the end point count value as the stick-slip region corresponding to the position B. Next, 1700 is recorded as the start point count value and 1900 is recorded as the end point count value as the stick-slip area corresponding to the position C. Then, it is determined whether or not the start point count value 1700 is between the previous stick-slip areas 1600 to 1800. Here, since the start point count value 1700 is between the previous stick-slip areas, the end point count value 1900 of the subsequent stick-slip area is recorded as the previous end-point count value, and the data of the subsequent stick-slip area is recorded. (Start point count value 1700, end point count value 1900) is deleted. In this way, when the stick-slip areas overlap, these stick-slip areas are combined.

  In this way, the carriage 41 is moved at a constant speed at a predetermined speed in the initial operation when the power is turned on, the stick-slip operation is detected, and the stick-slip region is stored based on this.

  Next, based on the stored stick-slip area when moving at a constant speed below a predetermined speed except for the initial operation (for example, at the time of ink cartridge replacement, capping, paper width detection, etc. described above). The carriage motor 42 is controlled. Specifically, when moving at a constant speed below a predetermined speed, the controller 126 reads all the start point count value and end point count value of the stored stick-slip area from the main memory 127. When the head 21 is positioned in the stick-slip area, the carriage motor 42 is controlled with a duty signal value having a control amount different from that in the non-stick-slip area.

  By the way, the manner in which the carriage 41 is positioned in the stick-slip region is as follows: (1) When the carriage 41 stops and starts moving in the stick-slip region, (2) the carriage 41 moves from outside the stick-slip region to within the stick region. (3) When the carriage 41 is in the stick-slip region during movement and the target stop position of the carriage 41 is in the stick-slip region, that is, when the carriage 41 stops in the stick-slip region. There are three modes. Here, it respond | corresponds to these 3 aspects as follows.

  When all the start point count value and end point count value of the stick-slip area are read, when the carriage 41 is moved at a constant speed at a low speed, the controller 126 determines whether or not the position at the start of movement of the carriage 41 is in the stick-slip area. Judge about. Then, when the position at the start of the movement of the carriage 41 is not in the stick-slip region, the movement of the carriage 41 is started by normal control. On the other hand, when the movement start position of the carriage 41 is in the stick-slip region, the duty signal value is generated by the special process for starting the movement, and the movement of the carriage 41 is started. The special processing for starting movement will be described in detail later.

  Next, the controller 126 determines whether or not the carriage 41 moves from outside the stick-slip area to inside the stick-slip area. When the carriage 41 does not move to the stick-slip region, the carriage 41 is moved by normal control. On the other hand, when the carriage 41 moves to the stick-slip region, the duty signal value is generated and moved by special processing for moving within the region when the carriage 41 enters the stick-slip region. This special processing for moving in the area will be described in detail later.

  Next, the controller 126 determines whether or not the moving carriage 41 and the target stop position of the carriage 41 are in the same stick-slip region. When it is determined that the moving carriage 41 and the target stop position of the carriage 41 are not in the stick-slip region, the carriage 41 is stopped at the target stop position by normal control. On the other hand, when it is determined that the moving carriage 41 and the target stop position of the carriage 41 are in the same stick-slip region, a duty signal value is generated and stopped by a special process for stopping. This special processing for stopping will be described in detail later.

  Thus, in the above-described three aspects, when the carriage 41 is in the stick-slip region, the duty signal value is generated and controlled by special processing. As described above, when the carriage 41 is in the stick-slip region, a duty signal value is generated by a special process, and the movement of the carriage 41 is controlled to suppress the stick-slip operation or cause the stick-slip operation to occur. The adverse effect caused by the slip operation can be reduced.

  In addition, since the stick-slip region is set in advance based on the detection position of the stick-slip operation, the stick-slip operation can be handled more quickly than when the carriage 41 is moved while determining whether the stick-slip operation occurs. can do.

  Here, the stick-slip area is set in the initial operation when the power is turned on. However, the stick-slip area may be set in advance in the nonvolatile memory before being shipped from the factory.

FIG. 19 is a flowchart for explaining an example of the handling process of the controller 126. During the initial operation when the power is turned on, the carriage 41 is moved at a constant speed below a predetermined speed, and the controller 126 detects a stick-slip operation. Then, the controller 126 sets a predetermined range from the detected position as the stick-slip region, and stores it in the main memory 127 (S202).
Next, before entering the normal printing process, the controller 126 reads the stored stick-slip area (S204).
Next, when the carriage 41 is moved at a constant speed below a predetermined speed during normal printing processing, the duty signal value to be generated differs depending on whether or not the position where the carriage 41 exists is in the stick-slip region. The carriage motor 42 is controlled (S206).

  In this way, by controlling the movement of the carriage 41 by varying the duty signal value generated depending on whether or not it is in the stick-slip region, the stick-slip operation is suppressed or the stick-slip operation occurs. The adverse effects of can be reduced.

Second Embodiment
The detection position of the stick-slip operation may vary depending on whether the carriage 41 moves in the forward direction or in the backward direction. Therefore, in the second embodiment, in order to cope with this, the stick-slip area when moved in the forward direction and the stick-slip area when moved in the backward direction are stored separately in the main memory 127.

  FIG. 20A is a diagram showing a start point count value and an end point count value of a stick-slip region in the forward direction used in the second embodiment. FIG. 20B is a diagram showing a start point count value and an end point count value in a stick-slip area in the backward direction used in the second embodiment.

  The method of setting the stick-slip area in the forward direction is the same as in the first embodiment. Even in the setting of the stick-slip area in the return path direction, the stick 41 is detected by moving the carriage 41 at a constant speed in the return path direction at an initial operation. A predetermined range centered on the position where the stick-slip operation is detected is stored in the main memory 127 as a stick-slip region.

  Next, when moving at a constant speed in the forward direction at a speed equal to or lower than a predetermined speed during a time other than the initial operation (for example, when the ink cartridge is replaced, when capping, when detecting the paper width, etc.), the stored forward direction is stored. The carriage motor 42 is controlled based on the stick-slip region. Specifically, when moving at a constant speed below a predetermined speed in the forward direction, the controller 126 reads all the stored start point count value and end point count value of the stick slip area in the forward direction from the main memory 127. When the head 21 is positioned in the stick-slip area, the carriage motor 42 is controlled with a duty signal value having a control amount different from that in the non-stick-slip area. As described above, there are three modes in which the head 21 is positioned in the stick-slip region. And there are respective corresponding methods for these three modes, but these are the same as those in the first embodiment, so the description will be omitted.

  In addition, when moving at a constant speed in the backward direction at a speed equal to or lower than a predetermined speed during a time other than the initial operation (for example, at the time of ink cartridge replacement, capping, paper width detection, etc. described above) The carriage motor 42 is controlled based on the stick-slip region. Specifically, when moving at a constant speed below a predetermined speed in the backward direction, the controller 126 reads all the stored start point count value and end point count value of the stick slip region in the backward direction from the main memory 127. When the head 21 is positioned in the stick-slip area, the carriage motor 42 is controlled with a duty signal value having a control amount different from that in the non-stick-slip area. Here, as described above, there are three modes in which the head 21 is positioned in the stick-slip region. And there are respective corresponding methods for these three modes, but these are the same as those in the first embodiment, so the description will be omitted.

  By storing the stick-slip area for each moving direction in this way, it is more suitable than moving the carriage 41 while determining whether or not a stick-slip operation occurs while corresponding to a stick-slip area that varies depending on the moving direction. It can respond to stick-slip operation quickly.

<Third Embodiment>
In the inkjet printer 1 according to the third embodiment, the area on the guide rail 46 is virtually divided into eight areas. When a stick-slip operation is detected even once in each area, that area is set as a stick-slip area. In the stick-slip region, the movement of the carriage 41 is controlled by a duty signal value generated by special processing different from normal control.

FIG. 21A is an example when the region on the guide rail is divided into eight regions. Here, the regions are divided so that they all have the same width.
In the initial operation, the carriage 41 is moved at a constant speed from the starting point in the forward direction at a speed equal to or lower than a predetermined speed. At this time, the stick-slip operation is detected by any one of the above-described determination methods of the stick-slip operation. For example, it is determined based on the moving speed of the carriage 41 whether or not the stick-slip operation is being performed. When the stick-slip operation is detected, the area where the detected position exists is set as the stick-slip area. For example, in FIG. 21A, a stick-slip operation is detected in region C, region D, and region E. Accordingly, the region C, the region D, and the region E are set as a stick-slip region. The position is determined based on the count value obtained by the linear encoder 51 and the controller 126.

  FIG. 21B is a diagram showing an example of stick-slip area byte data stored in the main memory 127. In the stick-slip area byte data, whether each area from area A to area H is a stick-slip area is recorded. Here, 1 is recorded in the bit corresponding to the area that is the stick-slip area, and 0 is recorded in the bit corresponding to the area that is not. In FIG. 21A, since region C, region D, and region E are stick-slip regions, 1 is recorded for the bits of region C, region D, and region E, and the other bits are set to 0.

  Next, when moving at a constant speed below a predetermined speed during a time other than the initial operation (for example, at the time of ink cartridge replacement, capping, paper width detection, etc. described above), the stored stick slip area byte The carriage motor 42 is controlled based on the data. Specifically, the controller 126 reads the stored stick-slip area byte data from the main memory 127 when moving at a constant speed below a predetermined speed. When the head 21 is positioned in the stick-slip area in light of this data, the carriage motor 42 is controlled with a duty signal value having a control amount different from that in the non-stick-slip area.

  There are three modes for the head 21 to be positioned in the stick-slip region. There are respective corresponding methods corresponding to these three aspects, but these are the same as those in the first embodiment, and thus description thereof is omitted.

  As described above, by generating the duty signal value by special processing in the stick-slip region, it is possible to suppress the stick-slip operation or to reduce the adverse effects caused by the stick-slip operation although the stick-slip operation occurs.

  Although the guide rail 46 is virtually divided into eight here, it may be divided more finely. In addition, since the stick-slip area byte data in the forward direction and the stick-slip area byte data in the return direction are respectively provided, it is possible to take a correspondence corresponding to each direction.

=== Special processing in the stick-slip region ===
<1. Special processing for moving start>
Here, when the carriage 41 is stopped in the stick-slip region and the speed is increased by the acceleration control unit 339A, the increment of the predetermined duty signal value output from the controller 126 is changed from DXP to DXP ′. The Here, there is a relationship of DXP <DXP ′. That is, the increment of the duty signal value transmitted to the acceleration control unit 339A is changed to a larger one. This operation will be described below. The duty signal value corresponds to a command value for controlling the motor.

  FIG. 22 is a diagram for describing a change in the increment of the duty signal value when the carriage 41 is in the stick-slip region and outside the region.

  When the controller 126 determines that the carriage 41 is not in the stick-slip region, the duty signal value increment is set to a predetermined value DXP. On the other hand, if the controller 126 determines that the carriage 41 is in the stick-slip region, the increment of the duty signal value is changed from the predetermined value DXP to the predetermined value DXP ′ by the controller 126 as shown in FIG. Accordingly, the acceleration control unit 339A outputs a duty value obtained by adding the predetermined value DXP ′ to the PWM circuit 338 every time the timer interrupt signal is input.

  The change in the duty signal value when the carriage 41 is not in the stick-slip region has been described with reference to FIG. 10A. This is because when the carriage 41 is not in the stick-slip region, the duty signal value first rises with the startup initial duty signal DX0, and then increases with an increment of DXP until the duty signal value becomes DXS.

  On the other hand, the duty signal value when the carriage 41 is in the stick-slip region first rises at the starting initial duty DX0, and then increases the duty value in increments of DXP 'until the duty signal value becomes DXS. That is, in this case, the time until the duty signal value reaches the predetermined value DXS can be shortened.

  Thus, when the increment DXP of the duty signal value is changed to a larger increment DXP ', the increase rate of the duty signal value during acceleration control is large, so that the predetermined value DXS is reached quickly. Thereafter, the control is switched to the PID control, but the carriage 41 starts to move as soon as the DXS can be reached earlier.

  By doing in this way, the stop period of the carriage 41 can be shortened. This indicates that even when the stick-slip operation occurs in the stick-slip region, the carriage 41 can be moved for a longer period of time within the predetermined time, and can be moved more within the predetermined time. That is, by increasing the increment of the duty signal value, the stick-slip operation may occur in the stick-slip region, but the carriage 41 can be quickly reached the target position.

  Further, as a special process for starting movement, the startup initial duty signal value DX0 may be changed to a larger value DX0 '.

<2. Special processing for moving within an area>
Here, when the carriage 41 moves to the stick-slip region, the gain used in the calculation executed by at least one of the proportional element 336A, the integral element 336B, or the derivative element 336C of the carriage motor control unit 128. Increase Gp, Gi, Gd. That is, the amplification factor used in the calculation executed by at least one of the proportional element 336A, the integral element 336B, and the differential element 336C of the carriage motor control unit 128, that is, of the amplification factors Gp, Gi, Gd Change at least one of them to a higher amplification factor. Thereby, the calculation is executed at the high amplification factor. In the present embodiment, the amplification factors Gp, Gi, and Gd are changed by an instruction from the controller 126.

  FIG. 23 illustrates the change in the amplification factor when the carriage 41 is outside the stick-slip region and when it is inside the region. Here, a case where the amplification factor Gd of the differential element 336C is changed will be described as an example.

  When the controller 126 determines that the carriage 41 is moving outside the stick-slip region, the amplification factor Gd of the differential element 336C is set to a predetermined value Gd1, for example, as shown in FIG. When the controller 126 determines that the carriage 41 enters the stick-slip region and moves within the stick-slip region, the gain Gd of the differential element 336C is set to a predetermined value by the controller 126 as shown in FIG. The value is changed from Gd1 to a predetermined value Gd2. Here, the predetermined value Gd1 corresponds to a predetermined amplification factor. Thereby, the differentiation element 336C calculates the predetermined value Gd2 when the calculation is performed based on the speed deviation ΔV between the target speed Vt output from the gain 333 and the detection speed Vc detected by the speed calculation unit 334. Is used to execute the calculation.

An example of an arithmetic expression of the differential element 336C when the controller 126 determines that the carriage 41 is moving outside the stick-slip region is shown in the following expression (5). Further, the following equation (6) shows an example of an arithmetic expression of the differential element 336C when the controller 126 determines that the carriage 41 is moving in the stick-slip region.
QD (j) = {ΔV (j) −ΔV (j−1)} × Gd1 (5)
QD (j) = {ΔV (j) −ΔV (j−1)} × Gd2 (6)

  Thus, when the gain Gd of the differential element 336C is changed from the predetermined value Gd1 to the predetermined value Gd2 by the controller 126, when the carriage 41 enters the stick-slip region, the output of the differential element 336C, that is, the differential The component QD can be increased. Thereby, the differential component QD input to the adder 337 can be increased. From this, when the moving speed of the carriage 41 rapidly increases, in order to suppress a rapid increase in the moving speed of the carriage 41, a higher gain Gd (Gd2) is obtained as a calculation result of the differential element 336C. The large minus (−) output amplified in this manner can be input to the adder 337 as the differential component QD. Thereby, the movement speed of the carriage 41 can be stabilized. Further, when the moving speed of the carriage 41 rapidly decreases, in order to suppress a rapid decrease in the moving speed of the carriage 41, amplification is performed with a higher amplification factor Gd (Gd2) as a calculation result of the differential element 336C. The large plus (+) output can be input to the adder 337 as the differential component QD. Thereby, the movement speed of the carriage 41 can be stabilized. In this way, the stick-slip operation in the stick-slip region of the carriage 41 can be suppressed.

  Note that, when it is determined that the carriage 41 is in the stick-slip region, the amplification factor that is changed to a higher amplification factor by the controller 126 includes the amplification factor Gd of the differential element 336C and the amplification factor of the proportional element 336A. It may be the rate Gp or the amplification factor Gi of the integration element 336B. When the stick-slip operation in the stick-slip region of the carriage 41 is suppressed, it is preferable to include the gain Gd of the differential element 336C as the gain that is changed to a higher gain. In addition, the amplification factor Gi of the integration element 336B may be included.

<3. Special processing for stopping>
Here, when the moving carriage 41 and the target stop position of the carriage 41 are in the stick-slip region, the carriage motor control unit 128 performs brake control on the carriage motor 42 in order to stop the carriage 41 at the target stop position. Is set to a position in front of the moving carriage 41 and the position where the target position of the carriage 41 is not in the stick-slip region. That is, the carriage motor control unit 128 starts brake control on the carriage motor 42 at an earlier timing than when the moving carriage 41 and its target stop position are not in the stick-slip region. As a result, the carriage 41 can be smoothly stopped at the target stop position.

  FIG. 24A illustrates a case where it is determined that the carriage 41 and its target stop position are not in the stick-slip region. FIG. 24B illustrates a case where it is determined that the carriage 41 and its target stop position are in the same stick-slip region.

  When the moving carriage 41 and its target stop position are not in the stick-slip region, as shown in FIG. 25A, the carriage 41 starts moving from the movement start position P0 and is a predetermined distance L1 from the target stop position P2. When reaching the brake control start position P 1 set just before, the carriage motor control unit 128 starts brake control for the carriage motor 42. Brake control here refers to control for stopping the carriage 41. Here, the carriage motor control unit 128 performs the brake control by reducing the signal value of the generated control signal. Actually, when the carriage 41 approaches the target stop position, the position deviation between the target stop position P2 from the controller 126 and the current position detected by the position calculation unit 331 decreases, and the PWM described with reference to FIG. A control signal having a small signal value is output from the circuit 338 to the driver 340 as a control signal. As another example of the brake control, there is a method in which the carriage motor control unit 128 gives a control signal having a negative signal value to the carriage motor 42 as a control signal. There is also a method of mechanically suppressing the movement of the carriage 41 and the rotational drive of the carriage motor 42 from the outside by a brake mechanism (deceleration mechanism) or the like.

  The carriage motor control unit 128 starts the brake control for the carriage motor 42 at the brake control start position P1, and then gradually decelerates the carriage motor 42 when the carriage 41 reaches the target stop position P2. The drive of the motor 42 is stopped. As a result, the carriage motor control unit 128 stops the carriage 41 at the target stop position.

  On the other hand, when it is determined that the carriage 41 and its target stop position are in the stick-slip region, as shown in FIG. 24B, after the carriage 41 starts moving from the movement start position P0, the carriage 41 moves to the target stop position. The carriage motor control unit 128 starts brake control with respect to the carriage motor 42 when it reaches the brake control start position P3 set by a predetermined distance L2 before P2. Here, the brake control start position P3 is set before the brake control start position P1 when the carriage 41 and its target stop position are not in the stick-slip region, that is, at the movement start position P0 side of the carriage 41. is there. The distance L2 between the brake control start position P3 and the target stop position P2 is the distance L1 between the brake control start position P1 and the target stop position P2 when the carriage 41 and the target stop position are not in the stick-slip region. It is longer than that. As a result, the brake control for the carriage motor 42 is started at an earlier timing than when the carriage 41 and its target stop position are not in the stick-slip region.

  After starting the brake control for the carriage motor 42 at the brake control start position P3, the carriage motor control unit 128 sets a distance L2 longer than the distance L1 when the carriage 41 and its target stop position are not in the stick-slip region. As a result, the carriage motor 42 can be gradually decelerated. As a result, the carriage 41 can be smoothly stopped at the target stop position P2.

  In addition, when the carriage 41 and its target stop position are in the stick-slip region, the carriage motor control unit 128 applies a larger brake to the carriage motor 42 than when the carriage 41 and its target stop position are not in the stick-slip region. The brake 41 may be executed by force to stop the carriage 41 at the target stop position.

  As a method of increasing the braking force of the brake control in the carriage motor control unit 128, the gain Kp of the gain 333, the constant Gp of the proportional element 336A, the constant Gi of the integral element 336B, and the constant Gd of the differential element 336C are appropriately changed. A method of increasing the control amount can be considered. That is, by changing the gain Kp and the constants Gp, Gi, and Gd, the magnitudes of the components QP, QI, and QD input to the adder 337 are adjusted and output from the adder 337 to the PWM circuit 338. By changing the addition result ΣQ, the PWM circuit 338 outputs a control signal that increases the braking force on the carriage motor 42.

=== Summary ===
(1) In the printing apparatus according to the present embodiment, the head 21 for printing on the paper S, the carriage motor 42 for moving the head 21, and the guide for guiding the head 21 along a predetermined direction. A rail 46, a main memory 127 for storing a stick-slip region set based on a position at which the head 21 performs a stick-slip operation on the guide rail 46, and a carriage motor for generating a duty signal value for controlling the carriage motor 42 And a control unit 128. Then, the carriage motor control unit 128 varies the duty signal value for controlling the carriage motor 42 depending on whether or not the head 21 is in the stick-slip area stored in the main memory 127.

  In this way, since the stick-slip region based on the position where the stick-slip operation occurs is stored in advance, the stick-slip operation can be handled earlier than the stick-slip operation after the stick-slip operation is detected. be able to.

(2) The main memory 127 stores a stick-slip region set based on a position where the head 21 performs a stick-slip operation for each moving direction of the head 21.
In this way, even if the place where the stick-slip operation occurs differs depending on whether the carriage 41 moves in the forward direction or the backward direction, a stick-slip region is set for each direction. Therefore, the stick-slip operation can be accurately handled.

(3) The printing apparatus further includes a controller 126 that determines whether or not the head 21 performs a stick-slip operation, and the main memory 127 stores a stick-slip area based on the determination of the controller 126.
By doing so, it is possible to determine the occurrence of the stick-slip operation and set the stick-slip region.

(4) Further, the main memory 127 stores a predetermined range on the guide rail 46 as a stick-slip region from the position determined by the controller 126 to perform the stick-slip operation.
By doing in this way, a stick slip area | region can be set easily.

(5) When the head 21 is moved along the guide rail 46 at a predetermined speed or less in the initial operation of the printer 1, the controller 126 determines whether or not the head 21 is performing a stick-slip operation.
In this way, it is possible to determine whether or not the stick-slip operation is being performed when the head 21 that is likely to cause the stick-slip operation is moved at a predetermined speed or less.

(6) The printing apparatus further includes a speed detection unit that detects the moving speed of the head 21. Then, the controller 126 determines whether or not the head 21 performs a stick-slip operation based on the moving speed detected by the speed detecting unit.

(7) The controller 126 can also determine whether or not the head 21 performs a stick-slip operation based on the duty signal value.

(8) The printing apparatus further includes an acceleration detection unit that detects the acceleration of the head 21. The controller 126 can also determine whether or not the head 21 performs a stick-slip operation based on the acceleration detected by the acceleration detection unit.

(9) Further, a timer for measuring a time during which the moving speed of the head 21 becomes equal to or lower than a predetermined allowable lower limit value from the start of movement of the head 21 to the end of movement is further provided. Then, the controller 126 can determine whether or not the head 21 performs the stick-slip operation based on the measurement time of the timer.
By making such a determination, it can be easily determined whether or not the head 21 is performing a stick-slip operation.

(10) The carriage motor control unit 128 makes the duty signal value for controlling the carriage motor 42 different depending on whether or not the head 21 is in the stick-slip area stored in the main memory 127. This is when the head 21 is moved from the stopped state in the slip region.

  In this way, when the movement of the carriage 41 is started in the stick-slip region where the stick-slip operation can occur, the carriage 41 is started to move quickly by making the duty signal value different from that when it is not the stick-slip region. Can do.

(11) The carriage motor control unit 128 varies the duty signal value for controlling the carriage motor 42 depending on whether or not the head 21 is in the stick-slip area stored in the main memory 127. This is when the head 21 enters the slip region.

  In this way, when the carriage 41 passes through the stick-slip region where the stick-slip operation can occur, the duty signal value is different from that when the carriage 41 is not in the stick-slip region, so that the carriage 41 performs the stick-slip operation. Can be suppressed.

(12) The carriage motor control unit 128 varies the duty signal value for controlling the carriage motor 42 depending on whether or not the head 21 is in the stick-slip area stored in the main memory 127. This is when the position 21 and the target stop position of the head 21 are in the stick-slip region.

  In this way, when the head 21 is located in the stick-slip region where the stick-slip operation can occur, and there is a target stop position, the duty is different from that when the head 21 and the target stop position are not in the stick-slip region. Even if the carriage 41 performs the stick-slip operation by changing the signal value, it can be smoothly stopped at the target position.

(13) Further, the head 21 includes a nozzle that ejects ink toward the paper S in order to perform printing on the paper S.

(14) Further, according to the printing apparatus including almost all of the above-described constituent elements, the effects of the present invention can be achieved most effectively because the above-described effects can be achieved.

(15) Further, in order to move the head 21 that performs printing on the paper S along the guide rail 46 that guides the print head 21 along a predetermined direction, the carriage motor 42 that moves the head 21 is controlled. A duty signal value for generating a stick-slip region set on the guide rail 46 based on a position where the head 21 performs a stick-slip operation, and a step of storing the stick-slip region in the main memory 127. Needless to say, there is a stick-slip handling method including a step of varying a duty signal value for controlling the carriage motor 42 depending on whether or not the head 21 is in the stick-slip region.

(16) Needless to say, there is a program for executing the above-described stick-slip countermeasure method. That is, this program controls the carriage motor 42 that moves the head 21 in order to move the head 21 that performs printing on the paper S along the guide rail 46 that guides the head 21 along a predetermined direction. And a step of storing in the main memory 127 a stick-slip region set based on a position at which the head 21 performs a stick-slip operation on the guide rail 46. Further, this program executes a step of varying the duty signal value for controlling the carriage motor 42 depending on whether or not the head 21 is in the stick-slip area stored in the main memory 127.

(17) Furthermore, it goes without saying that there is a printing system to which a computer that can be connected to the printing apparatus is connected.

=== Configuration of Printing System etc. ===
Next, as an embodiment of a printing system according to the present invention, a case where an inkjet printer 1 is provided as a printing apparatus will be described as an example. FIG. 25 shows an external configuration of an embodiment of a printing system. The printing system 300 includes a computer 140, a display device 304, and an input device 306. The computer 140 includes various computers such as a personal computer.

  The computer 140 includes a reading device 312 such as an FD drive device 314 and a CD-ROM drive device 316. In addition, the computer 140 may include, for example, an MO (Magnet Optical) disk drive device or a DVD drive device. The display device 304 includes various display devices such as a CRT display, a plasma display, and a liquid crystal display. The input device 306 includes a keyboard 308, a mouse 310, and the like.

  FIG. 26 is a block diagram showing an example of the system configuration of the printing system of this embodiment. The computer 140 includes a CPU 318, a memory 320, and a hard disk drive 322 in addition to the reading device 312 such as the FD drive device 314 and the CD-ROM drive device 316.

  The CPU 318 performs overall control of the computer 140. The memory 320 stores various data. A printer driver or the like is installed in the hard disk drive 322 as a program for controlling a printing apparatus such as the ink jet printer 1 of the present embodiment. The CPU 318 reads a program such as a printer driver stored in the hard disk drive 322 and operates according to the program. The CPU 318 is connected to a display device 304, an input device 306, the ink jet printer 1, and the like installed outside the computer 140.

  The printing system 300 realized in this way is a system that is superior to the conventional system as a whole system.

=== Other Embodiments ===
As described above, the printing apparatus such as a printer according to the present invention has been described based on one embodiment. However, the above-described embodiment is for facilitating the understanding of the present invention, and the present invention is limited and interpreted. Not meant to be The present invention can be changed or improved without departing from the gist thereof, and needless to say, the present invention includes equivalents thereof. In particular, even the embodiments described below are included in the printing apparatus according to the present invention.

<About print head>
In the embodiment described above, the print head (head 21) has the nozzles # 1 to # 180 that eject ink, and prints by ejecting ink from the nozzles # 1 to # 180, respectively. However, the print head here is not necessarily limited to such a head 21. That is, any form of print head may be used as long as printing is performed on a medium.

<About motor>
In the above-described embodiment, the carriage motor 42 moves as the “motor” via the pulley 44 and the timing belt 45, but the carriage 41 moves to the “motor” for moving the “printing head”. However, it is not necessarily limited to such a motor. That is, any motor may be used as long as it is a motor for moving a print head that performs printing on a medium.

<About the guide>
In the embodiment described above, the guide for guiding the print head (head 21, carriage 41) linearly in the lateral direction is used as a “guide portion” for guiding the print head (head 21, carriage 41) along a predetermined direction. Although the rail 46 has been disclosed, the “guide portion” is not necessarily limited to such a guide rail 46 alone. That is, any type of guide unit may be used as long as it is a guide unit for guiding the print head (head 21, carriage 41) along a predetermined direction.

<About the motor controller>
In the above-described embodiment, the motor controller that executes PID control or the like on the motor (carriage motor 42) has been described by taking the carriage motor controller 128 as an example of the “motor controller”. The “motor control unit” is not necessarily limited to such a motor control unit. That is, as long as the control unit controls the “motor”, any control method for controlling the motor may be used. For example, a motor control unit that controls the motor by a method other than PID control or the like may be used.

<About printing devices>
In the embodiment described above, the case of the inkjet printer 1 as described above has been described as an example of the printing apparatus. However, the printing apparatus is not limited to such a printing apparatus, but may be an inkjet printer that ejects ink by other methods. May be.
In addition to this, as a printing apparatus, in addition to the ink jet printer 1 described above, any printing apparatus provided with a print head that performs printing on a medium and is movable along a predetermined direction may be used. Any type of printing apparatus may be used.

<About ink>
The ink to be used may be a pigment ink, or other various inks such as a dye ink.
Regarding the ink color, in addition to the above-described yellow (Y), magenta (M), cyan (C), and black (K), for example, light cyan (LC), light magenta (LM), and dark yellow (DY), for example, Ink of other colors such as red, violet, blue, and green may be used.

<About media>
For media, including plain paper, matte paper, cut paper, glossy paper, roll paper, paper, photo paper, roll-type photo paper, etc., in addition to these, film materials and cloth materials such as OHP film and gloss film, It may be a metal plate. That is, any medium can be used as long as it can be a printing target.

1 is a perspective view of an embodiment of a printing apparatus according to the present invention. It is the perspective view explaining the internal configuration of the printing apparatus. It is sectional drawing which shows the conveyance part of a printing apparatus. 1 is a block configuration diagram illustrating a system configuration of a printing apparatus. It is a top view which shows an example of the head of a printing apparatus. It is explanatory drawing explaining an example of the linear encoder. It is a block diagram which shows the structure of the detection part of a linear encoder. FIG. 8A is a timing chart showing the output waveform of the linear encoder during forward rotation, and FIG. 8B is a timing chart showing the output waveform of the linear encoder during reverse rotation. It is a block block diagram of a carriage motor control unit. FIG. 10A is a graph of time change of the duty signal, and FIG. 10B is a graph of speed change of the motor. 6 is a flowchart illustrating an example of a printing process. It is explanatory drawing of the change of the moving speed when a carriage performs stick-slip operation | movement. It is explanatory drawing of an example of the determination method of the stick slip operation | movement based on a moving speed. It is explanatory drawing of the other example of the determination method of the stick slip operation | movement based on a moving speed. It is explanatory drawing of the relationship between the moving speed of a carriage at the time of stick-slip operation | movement, and the signal value of a duty signal. It is explanatory drawing of an example of the determination method of the stick-slip operation | movement based on the signal value of a duedy signal. It is explanatory drawing of an example of the determination method of the stick slip operation | movement based on an acceleration. It is explanatory drawing of the timer of a carriage motor control part. It is explanatory drawing of an example of the determination method of the stick slip operation | movement based on the measurement result of a timer. It is a figure for demonstrating the relationship between the position where stick-slip movement was detected, and a stick-slip area | region. FIG. 18A is a diagram showing the start point count value and end point count value of the stick-slip area stored in the main memory 127, and FIG. 18B is an example of processing when the stick-slip areas overlap. 10 is a flowchart for explaining an example of a handling process of a controller 126. It is a figure which shows the start point count value and end point count value of the stick slip area | region of an outward path | route used in 2nd Embodiment, FIG. 20B is the start point count value of the stick slip area | region of a backward path | route used in 2nd Embodiment. It is a figure which shows an end point count value. FIG. 21A is an example when the region on the guide rail is divided into eight regions, and FIG. 21B is a diagram showing an example of stick-slip region byte data stored in the main memory 127. It is a figure for demonstrating the change of the increment of a duty signal value when the carriage 41 exists in a stick-slip area | region, and when it is out of an area | region. This is a description of the change in gain when the carriage 41 is outside the stick-slip region and when the carriage 41 is inside the region. FIG. 24A illustrates a case where it is not determined that the carriage 41 and its target stop position are not in the stick-slip region, and FIG. 24B is a determination that the carriage 41 and its target stop position are in the stick-slip region. This is a description of the case. 1 illustrates an external configuration of an embodiment of a printing system. 1 is a block configuration diagram illustrating an example of a system configuration of a printing system according to an exemplary embodiment.

Explanation of symbols

1 Inkjet printer, 2 operation panel, 3 paper discharge unit, 4 paper supply unit,
5 operation buttons, 6 indicator lamps, 7 paper discharge tray, 8 paper feed tray,
13 paper feed roller, 14 platen, 15 transport motor, 17A transport roller,
17B paper discharge roller, 18A free roller, 18B free roller, 21 heads,
31 pump device, 35 capping device, 41 carriage,
42 Carriage motor, 44 pulley, 45 timing belt,
46 guide rail, 48 ink cartridge, 49 cartridge mounting part,
51 linear encoder, 53 paper detection sensor, 60 timer,
122 buffer memory, 124 image buffer, 126 controller,
127 main memory, 128 carriage motor controller,
129 communication interface, 130 transport control unit,
132 head drive unit, 134 rotary encoder, 140 computer,
211Y yellow nozzle row, 211C cyan nozzle row,
211M magenta nozzle row, 211K black nozzle row,
331 Position calculator, 332 subtractor, 333 gain,
334 Speed calculator, 335 subtractor, 336A proportional element,
336B integral element, 336C differential element, 337 adder, 338 PWM circuit,
339A acceleration control unit, 339B timer, 340 driver, 342 limiter,
452 LED, 454 collimator lens,
456 detection processing unit, 458 photodiode, 460 signal processing circuit,
462A comparator, 462B comparator,
464 linear encoder code plate, 466 detector

Claims (17)

(A) a print head for printing on a medium;
(B) a motor for moving the print head;
(C) a guide portion for guiding the print head along a predetermined direction;
(D) a storage unit that stores a stick-slip region set based on a position where the print head performs a stick-slip operation in the guide unit;
(E) a motor control unit that generates a command value for controlling the motor,
A motor control unit that varies the command value for controlling the motor depending on whether the print head is in the stick-slip region stored in the storage unit;
A printing apparatus comprising: The printing apparatus according to claim 1, wherein the storage unit stores a stick-slip region set based on a position where the print head performs a stick-slip operation for each movement direction of the print head. A determination unit for determining whether or not the print head performs a stick-slip operation;
The printing apparatus according to claim 1, wherein the storage unit stores the stick-slip region based on determination by the determination unit.   The printing apparatus according to claim 3, wherein the storage unit stores a predetermined range of the guide unit as a stick-slip region from a position determined by the determination unit to perform the stick-slip operation.   The determination unit determines whether or not the print head performs a stick-slip operation when the print head is moved along the guide unit at a predetermined speed or less in an initial operation of the printing apparatus. The printing apparatus according to 3 or 4. A speed detecting unit for detecting a moving speed of the print head;
The printing apparatus according to claim 3, wherein the determination unit determines whether the print head performs a stick-slip operation based on the moving speed detected by the speed detection unit.   The printing apparatus according to claim 3, wherein the determination unit determines whether or not the print head performs a stick-slip operation based on the command value. An acceleration detector for detecting the acceleration of the print head;
The printing apparatus according to claim 3, wherein the determination unit determines whether or not the print head performs a stick-slip operation based on the acceleration detected by the acceleration detection unit. A timer for measuring a time during which the moving speed of the print head is equal to or lower than a predetermined allowable lower limit between the start of movement of the print head and the end of movement;
The printing apparatus according to claim 3, wherein the determination unit determines whether or not the print head performs a stick-slip operation based on a measurement time of the timer. The motor control unit varies the command value for controlling the motor depending on whether or not the print head is in the stick-slip region stored in the storage unit.
The printing apparatus according to claim 1, wherein the printing head is moved from a stopped state in the stick-slip region. The motor control unit varies the command value for controlling the motor depending on whether or not the print head is in the stick-slip region stored in the storage unit.
The printing apparatus according to claim 1, wherein the printing head is in the stick-slip region. The motor control unit varies the command value for controlling the motor depending on whether or not the print head is in the stick-slip region stored in the storage unit.
The printing apparatus according to claim 1, wherein the position of the print head and the target stop position of the print head are in the stick-slip region.   The printing apparatus according to claim 1, wherein the print head includes a nozzle that discharges ink toward the medium in order to perform printing on the medium. (A) a print head for printing on a medium;
(B) a motor for moving the print head;
(C) a guide portion for guiding the print head along a predetermined direction;
(D) a storage unit that stores a stick-slip region set based on a position where the print head performs a stick-slip operation in the guide unit;
(E) a motor control unit that generates a command value for controlling the motor,
A motor control unit that varies the command value for controlling the motor depending on whether the print head is in the stick-slip region stored in the storage unit;
With
The storage unit stores, for each moving direction of the print head, a stick-slip region set based on a position where the print head performs a stick-slip operation;
A determination unit for determining whether the print head performs a stick-slip operation; and the storage unit stores the stick-slip region based on the determination by the determination unit;
The storage unit stores a predetermined range of the guide unit as a stick-slip region from a position determined by the determination unit to perform the stick-slip operation.
When the print head is moved along the guide portion at a predetermined speed or less in the initial operation of the printing apparatus, the determination unit determines whether the print head performs a stick-slip operation,
The apparatus further includes a speed detection unit that detects a movement speed of the print head, and the determination unit determines whether the print head performs a stick-slip operation based on the movement speed detected by the speed detection unit. ,
The motor control unit varies the command value for controlling the motor depending on whether or not the print head is in the stick-slip region stored in the storage unit. When the print head moves in and
The printing head includes a nozzle that ejects ink toward the medium to perform printing on the medium. Generating a command value for controlling a motor for moving the print head in order to move the print head that performs printing on the medium along a guide unit that guides the print head along a predetermined direction; When,
Storing a stick-slip area set based on a position where the print head performs a stick-slip operation in the guide unit in a storage unit;
Differentiating the command value for controlling the motor depending on whether the print head is in the stick-slip area stored in the storage unit; and
Including stick-slip handling method. Generating a command value for controlling a motor for moving the print head in order to move the print head that performs printing on the medium along a guide unit that guides the print head along a predetermined direction; When,
Storing a stick-slip area set based on a position where the print head performs a stick-slip operation in the guide unit in a storage unit;
Differentiating the command value for controlling the motor depending on whether the print head is in the stick-slip area stored in the storage unit; and
A program that executes. A printing system comprising a computer and a printing device connectable to the computer,
A print head for printing on a medium;
A motor for moving the print head;
A guide portion for guiding the print head along a predetermined direction;
A storage unit that stores a stick-slip region set based on a position at which the print head performs a stick-slip operation in the guide unit;
A motor control unit that generates a command value for controlling the motor, the command for controlling the motor depending on whether or not the print head is in the stick-slip area stored in the storage unit A motor control unit for different values;
A printing system comprising:

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