JP2007069555A - Inkjet printer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make ink-droplet ejection timing accurate by directly detecting the existence and moving state of a printing medium so as to directly detect a position of the printing medium. <P>SOLUTION: In this line head-type inkjet printer, when first and second inkjet heads 2 and 3 are juxtaposed in the carrying direction of the printing medium 1, a first carrying belt 6 for carrying the printing medium 1 below the inkjet head 2, and a second carrying belt 7 for carrying the printing medium 1 below the inkjet head 3 are arranged each with a space in a nozzle-array direction; and an optical sensor 23 for detecting the existence and moving state of the printing medium 1 by image-processing a surface state on the carrying-belt side of the printing medium 1 is arranged in the space. The optical sensor 23 applies light to the printing medium 1, and detects the amount and direction of the movement of the printing medium 1 from a change in the image of the state of the surface irradiated with the light. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  In the present invention, for example, minute characters of liquid inks of a plurality of colors are ejected from a plurality of nozzles to form fine particles (ink dots) on a print medium, thereby drawing a predetermined character or image. The present invention relates to an ink jet printer.

Such inkjet printers are generally inexpensive and can easily obtain high-quality color prints, and therefore have become widespread not only in offices but also in general users with the spread of personal computers and digital cameras.
In general, such an ink jet printer has a moving body called a carriage in which an ink cartridge and a print head are integrally provided, reciprocating on a print medium in a direction intersecting the transport direction. By ejecting (jetting) liquid ink droplets from the nozzles to form minute ink dots on the printing medium, a desired printed matter is created by drawing predetermined characters or images on the printing medium. Yes. The carriage is equipped with four color (yellow, magenta, cyan) ink cartridges including black (black) and a print head for each color, so that not only monochrome printing but also full-color printing combining each color is easy. (Furthermore, 6 colors, 7 colors, or 8 colors in which light cyan, light magenta, etc. are added to these colors are also put into practical use).

  Further, in this type of ink jet printer in which printing is executed while reciprocating the ink jet head on the carriage in a direction intersecting with the conveyance direction of the print medium, the ink jet head is set to 10 to cleanly print the entire page. Since it is necessary to reciprocate from several times to several tens of times, there is a disadvantage that it takes much printing time compared with other types of printing apparatuses such as laser printers and copying machines using electrophotographic technology.

  In contrast, in an inkjet printer of a type in which a long inkjet head (not necessarily integrated) having the same dimensions as the width of the print medium is disposed and the carriage is not used, the inkjet head is moved in the width direction of the print medium. This is not necessary, and so-called one-pass printing is possible, so that high-speed printing similar to the laser printer is possible. The former inkjet printer is generally referred to as a “multi-pass (serial) inkjet printer”, and the latter inkjet printer is generally referred to as a “line head inkjet printer”.

By the way, in order to perform high-quality printing with this type of ink jet printer, it is necessary to accurately eject ink droplets to a target position of a print medium. In a conventional inkjet printer, an encoder pattern such as a linear scale is attached to a conveyance belt for conveying a print medium, and the encoder pattern is read by an optical sensor to detect the amount of movement of the conveyance belt or to drive the conveyance belt The ink droplet ejection timing is set by detecting the position of the print medium, for example, by detecting the amount of movement of the conveying belt with a rotary encoder attached to the driving roller. Further, in the ink jet printer described in Patent Document 1 below, for example, a comb-shaped electrode provided on a conveyance belt to adsorb a print medium is detected by an optical sensor, and the position of the print medium is detected from the amount of movement. Ink droplet ejection timing is set.
JP 2003-89446 A

However, in any of the conventional ink jet printers, the position of the print medium is indirectly detected from the amount of movement of the transport belt, so that when the print medium is not placed at the target position with respect to the transport belt, the ink droplets The discharge timing is not accurate.
The present invention has been made paying attention to the above-described problems, and an ink jet printer capable of making ink droplet ejection timing accurate by directly detecting the presence and movement state of a print medium. It is intended to provide.

  [Invention 1] In order to solve the above problems, an inkjet printer according to Invention 1 is an inkjet printer that performs printing by placing a print medium on a conveyance belt, conveying the print medium, and discharging ink droplets onto the print medium. An optical sensor for irradiating the medium with light and performing image processing on the surface state of the print medium irradiated with the light to detect the presence and movement of the print medium, and the presence of the print medium detected by the optical sensor And a print medium detecting means for detecting the amount and direction of movement of the print medium based on the movement state.

  According to the ink jet printer according to the first aspect of the invention, the surface state of the print medium irradiated with light by the optical sensor is subjected to image processing to detect the presence and movement state of the print medium, and the print medium detected by the optical sensor Since the movement amount and movement direction of the print medium are directly detected based on the presence and movement state of the print medium, the position of the print medium can be accurately determined even if the print medium is not placed at the target position with respect to the conveyor belt. Thus, it is possible to detect the ink droplet discharge timing and meander control accurately.

[Invention 2] The inkjet printer of Invention 2 is the inkjet printer of Invention 1, wherein a gap is formed in the conveyance belt, and the surface state of the print medium on the conveyance belt side is image-processed by the optical sensor from the gap of the conveyance belt. It is characterized by doing.
According to the ink jet printer according to the second aspect of the present invention, since the gap is formed in the conveyance belt and the surface state of the print medium on the conveyance belt side is image-processed by the optical sensor from the gap of the conveyance belt, the printing surface is smooth. Even in a glossy print medium, its presence and movement state can be detected.

  [Invention 3] The inkjet printer according to Invention 3 is the inkjet printer according to Invention 1 or 2, wherein the optical sensor detects the movement state in at least two orthogonal directions by performing image processing on the surface property of the print medium. The medium detection means detects the movement amount of the print belt in the conveyance direction and the movement amount of the print medium in the direction orthogonal to the conveyance direction from the movement state of the print medium detected by the optical sensor. Ink ejection timing determination and meandering control are performed using the same optical sensor signal.

  According to the ink jet printer according to the third aspect of the invention, the surface property of the print medium is image-processed by the optical sensor to detect the movement state in at least two directions orthogonal to each other, and the detected movement state of the print medium is detected by the conveyor belt. Since it is configured to detect the amount of movement of the print medium in the conveyance direction and the amount of movement of the print medium in the direction orthogonal to the conveyance direction, not only the position of the print medium in the conveyance direction but also the amount of deviation in the lateral direction of the print medium. (Meandering amount) can also be detected accurately, and it is not necessary to install sensors for ink ejection timing and meandering control.

  [Invention 4] The inkjet printer according to Invention 4 is the inkjet printer according to Invention 3, wherein a plurality of the optical sensors are arranged along a conveyance direction of the print medium by the conveyance belt, and the print medium detection means includes the plurality of print media detection means. Among the optical sensors, only the output of one optical sensor at the part where the print medium exists is selected, and the movement amount of the print medium in the conveyance direction and the movement amount of the print medium in the direction orthogonal to the conveyance direction are detected. It is characterized by doing.

  According to the ink jet printer according to the fourth aspect of the present invention, a plurality of optical sensors are arranged along the conveyance direction of the print medium by the conveyance belt, and one of the plurality of optical sensors is one optical part at which the print medium exists. By selecting only the sensor output and detecting the amount of movement of the print medium in the conveyance direction and the amount of movement of the print medium in the direction orthogonal to the conveyance direction, the position of the conveyed print medium is continuously detected. It becomes possible to do.

Next, a first embodiment of the inkjet printer of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic configuration diagram of the ink jet printer of the present embodiment, FIG. 1a is a plan view thereof, and FIG. 1b is a front view thereof. In FIG. 1, a print medium 1 is a line head type ink jet printer that is conveyed in the direction of the arrow in the figure from the upper right to the lower left of the figure, and is printed in the printing area in the middle of the conveyance. However, the ink jet head of the present embodiment is arranged not only at one place but also at two places.

  Reference numeral 2 in the figure denotes a first inkjet head provided on the upstream side in the conveyance direction of the print medium 1, and reference numeral 3 denotes a second inkjet head provided on the downstream side, and below the first inkjet head 2. Is provided with a first transport unit 4 for transporting the print medium 1, and a second transport unit 5 is provided below the second inkjet head 3. The first transport unit 4 includes four first transport belts 6 arranged at predetermined intervals in a direction intersecting with the transport direction of the print medium 1 (hereinafter also referred to as nozzle row direction). Similarly, the second transport unit 5 includes four second transport belts 7 arranged at predetermined intervals in a direction (nozzle row direction) intersecting the transport direction of the print medium 1.

  The four second conveyor belts 7 as well as the four first conveyor belts 6 are arranged alternately adjacent to each other. In the present embodiment, among these conveyor belts 6, 7, two first conveyor belts 6 and 2 on the right side in the nozzle row direction and two first conveyor belts 6 and second on the left side in the nozzle row direction. The conveyor belt 7 is separated. That is, the right driving roller 8R is disposed in the overlapping portion of the two first conveyance belts 6 and the second conveyance belt 7 on the right side in the nozzle row direction, and the two first conveyance belts 6 and the second conveyance belts on the left side in the nozzle row direction. 7 is provided with a left driving roller 8L, a right first driven roller 9R and a left first driven roller 9L on the upstream side, and a right second driven roller 10R and a second left side on the downstream side. A driven roller 10L is provided. These rollers appear as a series, but are substantially divided at the central portion of FIG. 1a. The two first conveying belts 6 on the right side in the nozzle row direction are wound around the right driving roller 8R and the first driven roller 9R on the right side, and the two first conveying belts 6 on the left side in the nozzle row direction are connected to the left driving roller 8L and the left side. The two second conveying belts 7 on the right side in the nozzle row direction are wound around the first driven roller 9L, and the two second conveying belts on the left side in the nozzle row direction are wound on the right driving roller 8R and the second right driven roller 10R. 7 is wound around the left driving roller 8L and the second left driven roller 10L. The right electric motor 11R is connected to the right driving roller 8R, and the left electric motor 11L is connected to the left driving roller 8L. Accordingly, when the right driving roller 8R is rotationally driven by the right electric motor 11R, the first conveying unit 4 composed of the two first conveying belts 6 on the right side in the nozzle row direction and the two second conveying belts on the right side in the nozzle row direction. The second conveyance unit 5 configured by 7 moves in synchronization with each other at the same speed, and is configured by two first conveyance belts 6 on the left side in the nozzle row direction when the left driving roller 8L is rotationally driven by the left electric motor 11L. The second transport unit 5 including the first transport unit 4 and the two second transport belts 7 on the left side in the nozzle row direction are synchronized with each other and move at the same speed. However, if the rotation speeds of the right electric motor 11R and the left electric motor 11L are different, the conveyance speed in the left and right directions in the nozzle row can be changed. Specifically, the rotation speed of the right electric motor 11R is changed to that of the left electric motor 11L. When the rotational speed is higher than the rotation speed, the conveyance speed on the right side in the nozzle row direction can be made larger than that on the left side, and when the rotation speed of the left electric motor 11L is higher than the rotation speed of the right electric motor 11R. The speed can be greater than the right side.

  The first ink-jet head 2 and the second ink-jet head 3 are shifted in the transport direction of the printing medium 1 for each of six colors, for example, yellow (Y), magenta (M), cyan (C), and black (K). Arranged. Ink is supplied to each inkjet head 2 and 3 from an ink tank of each color (not shown) via an ink supply tube. Each inkjet head 2, 3 is formed with a plurality of nozzles in the direction intersecting with the conveyance direction of the print medium 1 (that is, in the nozzle row direction), and a necessary amount of ink droplets are simultaneously applied from the nozzles to necessary locations. By discharging, minute ink dots are formed and output on the printing medium 1. By performing this for each color, it is possible to perform so-called one-pass printing by passing the print medium 1 conveyed by the first conveyance unit 4 and the second conveyance unit 5 once. That is, the area where the inkjet heads 2 and 3 are disposed corresponds to the print area.

  As a method for discharging and outputting ink from each nozzle of the ink jet head, there are an electrostatic method, a piezo method, a film boiling ink jet method, and the like. In the electrostatic system, when a drive signal is given to the electrostatic gap, which is an actuator, the diaphragm in the cavity is displaced, causing a pressure change in the cavity, and ink drops are ejected from the nozzle by the pressure change. It is. In the piezo method, when a drive signal is given to a piezo element that is an actuator, the diaphragm in the cavity is displaced to cause a pressure change in the cavity, and ink droplets are ejected from the nozzle by the pressure change. . In the film boiling ink jet method, there is a minute heater in the cavity, the ink is instantaneously heated to 300 ° C. or more, the ink becomes a film boiling state, bubbles are generated, and ink droplets are ejected from the nozzle by the pressure change. That's it. Any ink output method can be applied to the present invention.

  The ink droplet ejection nozzles of the first inkjet head 2 are formed only between the four first conveyance belts 6 of the first conveyance unit 4, and the ink droplet ejection nozzles of the second inkjet head 3 are the second conveyance. It is formed only between the four second conveyor belts 7 of the section 5. This is because the inkjet heads 2 and 3 are cleaned by a cleaning unit, which will be described later, but in this way, one-pass printing cannot be performed with only one of the inkjet heads. Therefore, the first ink jet head 2 and the second ink jet head 3 are arranged so as to be shifted in the transport direction of the print medium 1 in order to compensate for the portions that cannot be printed with each other.

  Disposed below the first inkjet head 2 is the first cleaning cap 12 for cleaning the first inkjet head 2, and disposed below the second inkjet head 3 is the second inkjet head. 2 is a second cleaning cap 13 that cleans 3. Each of the cleaning caps 12 and 13 has such a size that it can pass between the four first conveying belts 6 of the first conveying unit 4 and between the four second conveying belts 7 of the second conveying unit 5. It is formed. These cleaning caps 12 and 13 are, for example, a rectangular bottomed cap body that covers the nozzles formed on the lower surfaces of the ink jet heads 2 and 3, that is, the nozzle surfaces and can be in close contact with the nozzle surfaces, and is disposed at the bottom thereof. And a tube pump connected to the bottom of the cap body, and a lifting device that lifts and lowers the cap body. Therefore, the cap body is raised by the lifting device and is brought into close contact with the nozzle surfaces of the inkjet heads 2 and 3. In this state, when the cap body is made negative pressure by the tube pump, ink droplets and bubbles are sucked out from the nozzles established on the nozzle surfaces of the ink jet heads 2 and 3, and the ink jet heads 2 and 3 can be cleaned. . When the cleaning is completed, the cleaning caps 12 and 13 are lowered. In some cases, the meniscus of each nozzle may be adjusted by stroking the nozzle surface with a wiper.

  On the upstream side of the first driven rollers 9R and 9L, there are two pairs of gate rollers 14 that adjust the paper feed timing of the printing medium 1 supplied from the paper feeding unit 15 and correct the skew of the printing medium 1. Is provided. The skew is a twist of the print medium 1 with respect to the transport direction. A pickup roller 16 for supplying the print medium 1 is provided above the paper supply unit 15. Reference numeral 17 in the figure denotes an electric motor that drives the gate roller 14.

  A belt charging device 19 is disposed below the drive rollers 8R and 8L. The belt charging device 19 includes a charging roller 20 that is in contact with the first conveying belt 6 and the second conveying belt 7 with the driving rollers 8R and 8L interposed therebetween, and the charging roller 20 is connected to the first conveying belt 6 and the second conveying belt 7. A spring 21 for pressing and a power source 22 for applying a charge to the charging roller 20 are configured to charge the first conveying belt 6 and the second conveying belt 7 from the charging roller 20 to charge them. In general, these belts are composed of a medium / high resistance body or an insulator. Therefore, when charged by a belt charging device, the charge applied to the surface is also composed of a high resistance body or an insulator. The print medium 1 is caused to generate dielectric polarization, and the print medium 1 can be adsorbed to the belt by electrostatic force generated between the charge generated by the dielectric polarization and the charge on the belt surface. The charging means may be a so-called corotron that drops the charge.

  Therefore, according to this ink jet printer, the belt charging device 19 charges the surfaces of the first conveyance belt 6 and the second conveyance belt 7, and in this state, the print medium 1 is fed from the gate roller 14, and a spur (not shown) When the printing medium 1 is pressed against the first conveying belt 6 by a paper pressing roller composed of a roller, the printing medium 1 is attracted to the surface of the first conveying belt 6 by the action of the dielectric polarization described above. In this state, when the driving rollers 8R and 8L are rotationally driven by the electric motors 11R and 11L, the rotational driving force is transmitted to the first driven rollers 9R and 9L via the first conveying belt 6.

  In this way, the first conveyance belt 6 is moved downstream in the conveyance direction while the print medium 1 is adsorbed, and the print medium 1 is moved below the first inkjet head 2 to be formed on the first inkjet head 2. Printing is performed by ejecting ink droplets from the nozzles. When printing by the first ink jet head 2 is completed, the print medium 1 is moved downstream in the transport direction and transferred onto the second transport belt 7 of the second transport unit 5. As described above, since the surface of the second transport belt 7 is also charged by the belt charging device 19, the print medium 1 is attracted to the surface of the second transport belt 7 by the action of the dielectric polarization described above.

  In this state, the second conveying belt 7 is moved downstream in the conveying direction, the printing medium 1 is moved below the second inkjet head 3, and ink droplets are ejected from nozzles formed on the second inkjet head. To print. When printing by the second ink jet head is completed, the print medium 1 is further moved downstream in the transport direction, and the print medium 1 is discharged to the paper discharge unit while being separated from the surface of the second transport belt 7 by a separation device (not shown). To do.

  When the first and second inkjet heads 2 and 3 need to be cleaned, the first and second cleaning caps 12 and 13 are raised as described above to raise the nozzle surfaces of the first and second inkjet heads 2 and 3. In this state, the cap body is brought into a negative pressure so that ink drops and bubbles are sucked out from the nozzles of the first and second ink jet heads 2 and 3 and cleaned. 2 Lower the cleaning caps 12 and 13.

  The surface of the print medium 1 is the gap between the first conveyor belts 6 or the gap between the second conveyor belts 7 and immediately below the surface of each conveyor belt 6, 7, that is, immediately below the surface of the print medium 1 on the conveyor belt side. An optical sensor 23 is provided that performs image processing on the state and detects the amount and direction of movement. In this embodiment, between the two first conveying belts 6 on the left side in the nozzle row direction and at two locations on the front side and the front side in the printing medium conveying direction of the first inkjet head 2, and the second conveying belt on the left side in the nozzle row direction. A total of three optical sensors 23 are arranged at one position on the left side of 7 and on the front side in the print medium conveyance direction of the second inkjet head 3.

  For example, as shown in FIG. 2, the optical sensor 23 is irradiated with light, an LED that emits light, a reflecting mirror 31 that irradiates the surface of the print medium 1 with the light of the LED, and an object. The target object, in this case, a lens 32 that captures the surface state of the print medium 1, a CMOS, and the like. The surface condition of the print medium 1 is captured, for example, by minute irregularities on the surface, and this is processed and captured at predetermined time intervals by an image processing calculation unit (not shown), and changes in the image are extracted compared to the previous time, From the change state, the movement state of the object, in this case, the print medium 1, that is, the movement amount and the movement direction is calculated. Accordingly, since the optical sensor 23 can detect the two-dimensional movement amount and movement direction of the print medium 1, it can output the movement amount in two orthogonal directions. In the present embodiment, one of these directions is made to coincide with the conveyance direction of the print medium 1. Accordingly, the remaining one direction is a direction that intersects the transport direction of the print medium 1, that is, the nozzle row direction, and can be said to be the width direction of the print medium 1. In the present embodiment, a case where the movement amount information is output as a two-phase pulse will be described.

  A control device for controlling itself is provided in the ink jet printer. For example, as shown in FIG. 3, the control device prints on a print medium by controlling a printing device, a paper feeding device, and the like based on print data input from a host computer 60 such as a personal computer or a digital camera. The processing is performed. An input interface unit 61 that receives print data input from the host computer 60, a control unit 62 configured by, for example, a microcomputer that executes print processing based on the print data input from the input interface unit 61, A drive signal generation circuit 70 that forms a drive signal COM, an oscillation circuit 71 that outputs a clock signal SCK, a control signal from the control unit 62, a drive signal COM from the drive signal generation circuit 70, and a clock signal from the oscillation circuit 71 An output interface unit 63 that converts SCK into drive signals for the inkjet heads 2 and 3 and the right and left electric motors 11R and 11L, and an output of the optical sensor 23 is read via the optical sensor selection circuit 24, and a reset from the control unit 62 The signal rstn is output to the optical sensor selection circuit 24. Constructed and an output interface portion 64 for benefit.

  The control unit 62 temporarily stores a CPU (Central Processing Unit) 62a that executes various processes such as a print process, and print data input through the input interface 61 or various data when the print data print process is executed. A ROM (Read-Only ROM) comprising a RAM (Random Access Memory) 62c that temporarily stores an application program such as print processing or the like, and a non-volatile semiconductor memory that stores a control program executed by the CPU 62a Memory) 62d. When the control unit 62 obtains print data (image data) from the host computer 60 via the input interface unit 61, the CPU 62a executes predetermined processing on the print data, and outputs the processed data and various sensors. Based on the input data, a control signal is output to the output interface unit 63 and the input / output interface unit 64. As a result, the output interface unit 63 outputs the right motor drive signal DMR toward the right electric motor 11R, the left motor drive signal DML toward the left electric motor 11L, and the pixel data SI and the waveform pattern toward the inkjet heads 2 and 3. Data SP, latch signal LAT, channel signal CH, drive signal COM, and clock signal SCK are output, respectively.

  Further, the inkjet heads 2 and 3 include first to third shift registers 81 to 83, first to first, which sequentially store pixel data SI and waveform pattern data SP output from the output interface unit 63 based on the clock signal SCK. The first and second latch circuits 84 and 85 for latching the stored contents of the three shift registers 81 to 83 based on the latch signal LAT, and the control for setting the decoding timing of the latched contents based on the latch signal LAT and the channel signal CH A logic circuit 86; a decoder 87 for decoding the contents latched by the first and second latch circuits 84 and 85 at a decoding timing set by the control logic circuit 86; a level shifter 88 for increasing the voltage of the signal decoded by the decoder 87; Switch circuit 89 opened and closed by the output of the level shifter 88, switch circuit It is driven by the drive signal COM outputted from the 9, and includes a piezoelectric vibrator 90 as an actuator for ejecting ink droplets pressurizing the ink in the cavity.

  The optical sensor selection circuit 24 has a configuration as shown in FIG. Here, of the three optical sensors 23 described above, the optical sensor 23 closest to the print medium conveyance direction is the first optical sensor 23, the central optical sensor 23 is the second optical sensor 23, and the farthest optical sensor 23 is located. The optical sensor 23 is a third optical sensor, the two-phase pulse signals of the movement amount in the print medium conveyance direction output from the first optical sensor 23 are Xa1, Xb1, and the two-phase pulse signals of the movement amount in the nozzle array direction are Ya1, Yb1, Xa2 and Xb2 are the two-phase pulse signals of the movement amount in the print medium conveyance direction output from the second optical sensor 23, Y2 and Yb2 are the two-phase pulse signals of the movement amount in the nozzle array direction, and the third optical sensor. 23, the two-phase pulse signals of the movement amount in the print medium conveyance direction output from 23 are Xa3 and Xb3, and the two-phase pulse signals of the movement amount in the nozzle array direction are Ya3 and Yb3. Each pulse signal is output one pulse each time the object, in this case, the print medium 1 moves by a predetermined amount.

  Two-phase pulse signals Xa1 and Xb1 of the amount of movement of the first optical sensor 23 in the print medium conveyance direction are input to the first counter CNT1 via the switches SWXa1 and SWXb1, respectively, and the output cnt1 of the first counter CNT1 is the first The output qc1 of the first comparator COMP1 is input to the two AND gates AND1a and AND1b via the first inverter INV1, the output inXa1 of the switch SWXa1 is input to one AND gate AND1a, and the other The output inXb1 of the switch SWXb1 is input to the AND gate AND1b, the output of one AND gate AND1a is input to the first OR gate OR1, and the output of the other AND gate AND1b is input to the second OR gate OR2. The output of the first inverter INV1 is input as an ON / OFF signal for the switches SWXa1 and SWXb1. The output of the first comparator COMP1 is grounded via the first switch SW1 and the first diode D1.

  Two-phase pulse signals Xa2 and Xb2 of the movement amount of the second optical sensor 23 in the print medium conveyance direction are input to the second counter CNT2 via the switches SWXa2 and SWXb2, respectively, and the output cnt2 of the second counter CNT2 is the second The output qc2 of the second comparator COMP2 is input to the two AND gates AND2a and AND2b via the second inverter INV2, and the output inXa2 of the switch SWXa2 is input to one AND gate AND2a. The output inXb2 of the switch SWXb2 is input to the AND gate AND2b, the output of one AND gate AND2a is input to the first OR gate OR1, and the output of the other AND gate AND2b is input to the second OR gate OR2. The output of the second inverter INV2 is input as an ON / OFF signal of the first switch SW1. The output of the first switch SW1 is input as an ON / OFF signal for the switches SWXa2 and SWXb2.

  Two-phase pulse signals Xa3 and Xb3 of the movement amount of the third optical sensor 23 in the print medium transport direction are input to the third counter CNT3 via the switches SWXa3 and SWXb3, respectively, and the output cnt3 of the third counter CNT3 is the third The output qc3 of the third comparator COMP3 is input to the two AND gates AND3a and AND3b via the third inverter INV3, the output inXa3 of the switch SWXa3 is input to one AND gate AND3a, and the other The output inXb3 of the switch SWXb3 is input to the AND gate AND3b, the output of one AND gate AND3a is input to the first OR gate OR1, and the output of the other AND gate AND3b is input to the second OR gate OR2. The output qc2 of the second comparator COMP2 is input as an ON / OFF signal for the switches SWXa2 and SWXb2.

  The reset signal rstn output from the control unit 62 is input to the reset terminals res of the first to third counters CNT1 to CNT3 via the diode D3. The third switch SW3 is interposed between the output terminal of the diode 3 and the output terminal of the third comparator COMP3, and the reset signal rstn inverted by the reset inverter INVrstn is used as the ON / OFF signal of the third switch SW3. Entered. Then, the output XA of the first OR gate OR1 and the output XB of the second OR gate OR2 are read into the control unit 62 as movement amounts of the print medium 1 in the conveyance direction, respectively. Note that the reset terminals res of the first to third counters CNT1 to CNT3 are all active Hi. In addition, the two-phase pulse signals Ya1 to Ya3 and Yb1 to Yb3, which are amounts of movement of the first to third optical sensors 23 in the nozzle row direction, are read into the control unit 62 as needed.

  The circuit operation of the optical sensor selection circuit 24 is shown in FIG. When a print command is transmitted from the host computer 60 to the inkjet printer control apparatus, a reset signal rstn that is a pulse signal is transmitted from the control unit 62 to the optical sensor selection circuit 24. When the reset signal rstn is at the Hi level, the first to third counters CNT1 to CNT3 are reset and the inverted output of the reset inverter INVrstn is at the Low level, so that the third switch SW3 is turned OFF, and the third comparator COMP The output qc3 is cut off. Also, when the first to third counters CNT1 to CNT3 are reset, the outputs cnt1 to cnt3 of the first to third counters CNT1 to CNT3 become 0, so the outputs qc1 to qc1 of the first to third comparators COMP1 to COMP3 All qc3 are at the Low level. Note that when the reset signal rstn, which is a pulse signal, becomes the low level level, the third switch SW3 is turned on, so that the output qc3 of the third comparator COMP3 is input to the reset terminals res of the first to third counters CNT1 to CNT3. The

  When the output of the first comparator COMP1 becomes Low level by the above-described reset operation, the output of the first inverter INV1 becomes Hi level, so that the switches SWXa1 and SWXb1 are turned on, and the first optical sensor 23 moves in the print medium conveyance direction. Are counted by the first counter CNT1. On the other hand, since the output of the second comparator COMP2 is also at the low level, the output of the second inverter INV2 is at the high level and the first switch SW1 is turned on, but the output qc1 of the first comparator COMP1 is still at the low level. Therefore, the switches SWXa2 and SWXb2 between the second optical sensor 23 and the second counter CNT2 remain in the OFF state, and the output qc2 of the second comparator COMP2 at the low level is input. The switches SWXa3 and SWXb3 with the third counter CNT3 also remain in the OFF state. Accordingly, the two-phase pulses Xa2 and Xb2 indicating the amount of movement in the print medium conveyance direction from the second optical sensor 23 to the second counter CNT2 are blocked, and the print medium conveyance direction from the third optical sensor 23 to the third counter CNT3. Two-phase pulses Xa3 and Xb3 indicating the amount of movement to are also cut off.

  Until the output cnt1 of the first counter CNT1 reaches the set value of the first comparator COMP1, the output qc1 of the first comparator COMP1 remains at the low level. Accordingly, since the Hi level signal inverted by the first inverter INV1 is continuously input to one input terminal of the AND gates AND1a and AND1b, the outputs of the AND gates AND1a and AND1b are transferred to the print medium of the first optical sensor 23. Each time the two-phase pulses Xa1 and Xb1 indicating the amount of movement in the direction become Hi level, they become Hi level, and this becomes the output XA of the first OR gate OR1 and the output XB of the second OR gate OR2, that is, in the transport direction of the printing medium 1. Is output to the control unit 62 as the amount of movement.

  From this state, when the output cnt1 of the first counter CNT1 reaches the set value of the first comparator COMP1, the output qc1 of the first comparator COMP1 becomes Hi level, and the output of the first inverter INV1 becomes Low level. The switches SWXa1 and SWXb1 between the first optical sensor 23 and the first counter CNT1 are turned off, and the two-phase pulse Xa1 indicating the amount of movement in the print medium conveyance direction from the first optical sensor 23 to the first counter CNT1. , Xb1 are cut off, and the outputs from the AND gates AND1a and AND1b are also set to the low level. On the other hand, the switches SWXa2 and SWXb2 to which the output qc1 of the first comparator COMP1 held at the Hi level is input are turned on, and the two-phase pulse indicating the amount of movement of the second optical sensor 23 in the print medium conveyance direction. Xa2 and Xb2 start to be counted by the second counter CNT2.

  Until the output cnt2 of the second counter CNT2 reaches the set value of the second comparator COMP2, the output qc2 of the second comparator COMP2 remains at the low level. Accordingly, since the Hi level signal inverted by the second inverter INV2 is continuously input to one input terminal of the AND gates AND2a and AND2b, the outputs of the AND gates AND2a and AND2b are transferred to the print medium of the second optical sensor 23. Each time the two-phase pulses Xa2 and Xb2 indicating the amount of movement in the direction become Hi level, they become Hi level, and this becomes the output XA of the first OR gate OR1 and the output XB of the second OR gate OR2, that is, in the transport direction of the printing medium 1. Is output to the control unit 62 as the amount of movement. Since the output qc2 of the second comparator COMP2 is at the low level, the switches SWXa3 and SWXb3 between the third optical sensor 23 and the third counter CNT3 also remain in the OFF state, and the third counter CNT3 is output from the third optical sensor 23. The two-phase pulses Xa3 and Xb3 indicating the amount of movement in the print medium conveyance direction are also cut off.

  From this state, when the output cnt2 of the second counter CNT2 reaches the set value of the second comparator COMP2, the output qc2 of the second comparator COMP2 becomes Hi level, and the output of the second inverter INV2 becomes Low level. 1 switch SW1 is turned off. As a result, the switches SWXa2 and SWXb2 between the second optical sensor 23 and the second counter CNT2 are also turned off, and the print medium is conveyed from the second optical sensor 23 to the second counter CNT2. The two-phase pulses Xa2 and Xb2 indicating the amount of movement in the direction are cut off, and the outputs from the AND gates AND2a and AND2b are also set to the low level. On the other hand, the switches SWXa3 and SWXb3 to which the output qc2 of the second comparator COMP2 held at the Hi level is input are turned on, and the two-phase pulse indicating the movement amount of the third optical sensor 23 in the print medium conveyance direction. Xa3 and Xb3 start to be counted by the third counter CNT3.

  Until the output cnt3 of the third counter CNT3 reaches the set value of the third comparator COMP3, the output qc3 of the third comparator COMP3 remains at the low level. Accordingly, since the Hi level signal inverted by the third inverter INV3 is continuously input to one input terminal of the AND gates AND3a and AND3b, the outputs of the AND gates AND3a and AND3b are transferred to the print medium of the third optical sensor 23. Each time the two-phase pulses Xa3 and Xb3 indicating the amount of movement in the direction become Hi level, they become Hi level, and this becomes the output XA of the first OR gate OR1 and the output XB of the second OR gate OR2, that is, in the transport direction of the printing medium 1. Is output to the control unit 62 as the amount of movement.

  From this state, when the output cnt3 of the third counter CNT3 reaches the set value of the third comparator COMP3, the output qc3 of the third comparator COMP3 becomes Hi level, which resets the first to third counters CNT1 to CNT3. Since the voltage is supplied to the terminal res, the count values of the counters CNT1 to CNT3 are reset. Accordingly, since the output cnt3 of the third counter CNT3 becomes less than the set value of the third comparator COMP3, the output qc3 of the third comparator COMP3 immediately becomes Low level. Further, since the output cnt2 of the second counter CNT2 becomes less than the set value of the second comparator COMP2, the output qc2 of the second comparator COMP2 also becomes a low level, and the output between the third optical sensor 23 and the third counter CNT3. The switches SWXa3 and SWXb3 are also turned off, and the two-phase pulses Xa3 and Xb3 indicating the amount of movement in the print medium conveyance direction from the third optical sensor 23 to the third counter CNT3 are blocked, and the AND gates AND3a and AND3b together. The output of becomes low level.

  On the other hand, since the output cnt1 of the first counter CNT1 is less than the set value of the first comparator COMP1, the output qc1 of the first comparator COMP1 is also at the low level, but the inverted output of the first inverter INV1 is at the Hi level. The switches SWXa1 and SWXb1 between the first optical sensor 23 and the first counter CNT1 are turned on, and a two-phase pulse indicating the amount of movement in the print medium conveyance direction from the first optical sensor 23 to the first counter CNT1. Xa1 and Xb1 can be input. Note that the Hi level reset signal rstn is not output from the control unit 62, so the output of the reset inverter INVrstn remains at the Hi level, and the third switch SW3 also remains in the ON state.

  Therefore, the set value of the first comparator COMP1 is set to the number of two-phase pulses indicating the amount of movement in the print medium conveyance direction from the first optical sensor 23 corresponding to the distance between the first optical sensor 23 and the second optical sensor 23. The set value of the second comparator COMP2 is set to the number of two-phase pulses corresponding to the distance between the second optical sensor 23 and the third optical sensor 23 and indicating the amount of movement in the print medium conveyance direction from the second optical sensor 23. For example, the optical sensor 23 that detects the amount of movement in the transport direction of the print medium 1 each time the front end of the print medium 1 passes in order on the three optical sensors 23 is changed from the first to the second, third. It is possible to select one by one by switching in the order. Further, the set value of the third comparator COMP3 corresponds to the distance from the rear end of the previous print medium 1 to the front end of the next print medium 1, and the amount of movement in the print medium conveyance direction from the third optical sensor 23 If the number of two-phase pulses indicating is set, the amount of movement of the next print medium 1 in the transport direction is detected by the first optical sensor 23 immediately after the previous print medium 1 passes through the third optical sensor 23. It is possible to set the interval for continuous printing to a minimum.

  For example, in FIG. 6A, a linear encoder LE is attached to the widthwise end of the conveyor belt B, and this is read by an optical sensor to detect the position of the print medium 1. For example, as in the present embodiment, the print medium When adsorbing 1 to the conveying belt B and conveying it, if the contact area between the printing medium 1 and the conveying belt B is small, such as when the printing medium 1 is fed or discharged, the adsorbing force of the printing medium 1 The print medium 1 may not be placed (adsorbed) at the target position. If the print medium 1 cannot be accurately placed at the target position of the transport belt B as described above, ink dots are formed at positions indicated by solid lines with respect to the ink dot target positions indicated by broken lines as shown in FIG. Such misalignment of ink dots is difficult to understand with a single color, but it becomes noticeable when a plurality of colors are overprinted, leading to deterioration in print image quality.

On the other hand, in this embodiment, since the optical sensor 23 directly detects the presence and movement state (movement direction and movement amount) of the print medium 1, the print medium 1 is placed at the target position with respect to the conveyance belt. Even if it is not placed, it is possible to accurately detect the position of the print medium 1, and it is possible to ensure the print image quality by preventing the displacement of the ink dots.
Next, the so-called meandering control of the printing medium 1 using the two-phase pulse signals Ya1 to Ya3 and Yb1 to Yb3 which are the movement amounts of the first to third optical sensors 23 in the nozzle row direction will be described with reference to the flowchart of FIG. explain. In this meandering control, the amount of movement of the print medium 1 in the nozzle row direction is detected from the two-phase pulse signals Ya1 to Ya3 and Yb1 to Yb3 of the first to third optical sensors 23 so that the amount of movement becomes zero. Drive signals are set and output to the right and left electric motors 11R and 11L.

This calculation process is a timer interrupt process at every predetermined sampling time. First, in step S1, the two-phase pulse signals Ya1 to Ya3 and Yb1 to Yb3 of the first to third optical sensors 23 are moved in the nozzle row direction of the print medium 1. Read the amount of movement.
Next, the process proceeds to step S2, and the meandering amount of the printing medium 1 is calculated from the movement amount of the printing medium 1 read in step S1 in the nozzle row direction.

Next, the process proceeds to step S3, and the drive speed correction amount of the left and right transport belts 6, 7 in the print medium transport direction for correcting the meandering amount of the print medium 1 calculated in step S2 is calculated.
Next, the process proceeds to step S4, and the left and right electric motor rotation speed is calculated by taking into account the left and right belt drive speed correction amount calculated in step S3.
Next, the process proceeds to step S5, where a motor drive signal for achieving the left and right electric motor rotation speed calculated in step S4 is generated and output, and then the process returns to the main program.

  According to this calculation process, the movement amount in the nozzle row direction of the print medium 1 is read from the two-phase pulse signals Ya1 to Ya3 and Yb1 to Yb3 of the first to third optical sensors 23, and the nozzles of the read print medium 1 are read. A meandering amount of the printing medium 1 is calculated from the amount of movement in the column direction, and a driving speed correction amount of the left and right conveying belts 6 and 7 in the printing medium conveying direction for correcting the meandering amount of the printing medium 1 is calculated; By calculating the left and right electric motor rotation speed taking into account the calculated left and right belt drive speed correction amount, and generating and outputting a motor drive signal for achieving the calculated left and right electric motor rotation speed, the nozzle array of the print medium 1 Since the amount of movement in the direction, that is, the amount of meandering is directly detected and a motor drive signal for correcting it is generated and outputted, meandering of the print medium 1 can be corrected appropriately and quickly.

  As described above, according to the ink jet printer of the present embodiment, the surface state of the print medium 1 irradiated with light by the optical sensor 23 is subjected to image processing to detect the presence and movement state of the print medium 1, and the optical sensor. 23, the moving amount and moving direction of the printing medium 1 are detected based on the presence and moving state of the printing medium 1 detected at 23, so that the printing medium 1 is placed at the target position with respect to the conveyor belts 6 and 7. Even if it is not done, the position of the print medium 1 can be accurately detected, and the ink droplet ejection timing can be made accurate.

Further, since a gap is formed in the conveyor belts 6 and 7 and the surface state on the conveyor belt side of the print medium 1 is image-processed by the optical sensor 23 from the gap between the conveyor belts 6 and 7, the gloss is smooth on the printing surface. The presence and movement state of the print medium can be detected.
The optical sensor 23 performs image processing on the surface property of the print medium 1 to detect a movement state in at least two orthogonal directions, and the print medium 1 by the conveyor belts 6 and 7 is detected from the detected movement state of the print medium 1. The movement amount in the conveyance direction and the movement amount in the direction orthogonal to the conveyance direction of the print medium (nozzle row direction) are detected, so that not only the position of the print medium 1 in the conveyance direction but also the horizontal direction of the print medium 1 is detected. The amount of deviation in the direction, that is, the amount of meandering can be detected accurately.

In addition, a plurality of optical sensors 23 are arranged along the conveyance direction of the print medium 1 by the conveyance belts 6 and 7, and one of the plurality of optical sensors 23 is one optical sensor 23 at a portion where the print medium 1 exists. Therefore, it is possible to continuously detect the position of the transported print medium 1 because the amount of movement of the print medium 1 in the transport direction is detected.
In the above-described embodiment, only the case where three optical sensors 23 are provided along the print medium conveyance direction has been described in detail. However, the number of optical sensors 23 is not limited to this. For example, FIG. 8 shows a total of two locations, one on the front side in the print medium conveyance direction of the first inkjet head 2 and one on the front side in the print medium conveyance direction of the second inkjet head 3, and FIG. In this embodiment, a total of eight optical sensors 23 are arranged at four sides and four sides of each of the four second inkjet heads 3. However, for example, when the optical sensor 23 is disposed as shown in FIG. 8, the distance between the two optical sensors 23 needs to be at least smaller than the length of the print medium 1 in the transport direction.

  In the above embodiment, only an example in which the ink jet printer of the present invention is applied to a so-called line head type ink jet printer has been described in detail. However, the ink jet printer of the present invention can be applied to all types of ink jet including a multi-pass type printer. Applicable to printers.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram which shows one Embodiment of the inkjet printer of this invention, (a) is a top view, (b) is a front view. It is explanatory drawing of the optical sensor of this invention. 1 is a block diagram of an inkjet printer according to the present invention. It is a block block diagram of the optical sensor selection circuit of this invention. It is operation | movement explanatory drawing of the optical sensor selection circuit of this invention. It is explanatory drawing of printing medium conveyance and an ink dot shift. 6 is a flowchart showing a calculation process for correcting meandering of a print medium in the present invention. It is a schematic structure top view which shows other embodiment of the inkjet printer of this invention. It is a schematic structure top view which shows other embodiment of the inkjet printer of this invention.

Explanation of symbols

  1 is a print medium, 2 is a first inkjet head, 3 is a second inkjet head, 4 is a first transport unit, 5 is a second transport unit, 6 is a first transport belt, 7 is a second transport belt, and 8R and 8L. Is a driving roller, 9R and 9L are first driven rollers, 10R and 10L are second driven rollers, 11R and 11L are electric motors, 19 is a belt charging device, 23 is an optical sensor, and 24 is an optical sensor selection circuit.

Claims (4)

  In an inkjet printer that performs printing by placing a print medium on a conveyance belt and discharging ink droplets onto the print medium, the print medium is irradiated with light and the surface state of the print medium irradiated with the light An image sensor for detecting the presence and movement state of the print medium, and printing for detecting the movement amount and movement direction of the print medium based on the presence and movement state of the print medium detected by the optical sensor An ink jet printer comprising a medium detecting means.  The inkjet printer according to claim 1, wherein a gap is formed in the conveyance belt, and the surface state of the print medium on the conveyance belt side is image-processed by the optical sensor from the gap of the conveyance belt.   The optical sensor performs image processing on a surface property of the print medium to detect a movement state in at least two directions orthogonal to each other, and the print medium detection unit detects the movement belt from the movement state of the print medium detected by the optical sensor. The ink ejection timing is determined and the meandering control is performed using signals from the same optical sensor by detecting the amount of movement of the print medium in the conveyance direction and the amount of movement of the print medium in the direction orthogonal to the conveyance direction. An ink jet printer according to claim 1 or 2.   A plurality of the optical sensors are arranged along the conveyance direction of the print medium by the conveyance belt, and the print medium detection means is one of the plurality of optical sensors of one optical sensor at a portion where the print medium exists. 4. The ink jet printer according to claim 3, wherein only the output is selected to detect the amount of movement of the print medium in the conveyance direction and the amount of movement of the print medium in the direction orthogonal to the conveyance direction.

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