JP2017071067A - Device for emitting liquid and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve a problem in that if recovery cannot be carried out even when a recovery operation is performed a predetermined number of times, all recovery operations thereafter are stopped regardless of the possibility that recovery may be able to be carried out.SOLUTION: From the result of a liquid emission detecting means, it is determined whether a predetermined abnormal emission requiring a recovery operation has occurred or not. If it is determined that a predetermined abnormal emission has arisen, the number of occurrences is stored as the occurrence history of predetermined abnormal emissions. Before the occurrence history satisfies predetermined conditions, the recovery operation is performed. If it is determined that a predetermined abnormal emission does not occur before the occurrence history satisfies the predetermined conditions, the stored occurrence history is cancelled.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an apparatus and a program for discharging a liquid.

  In an apparatus for ejecting liquid that includes a liquid ejection head for ejecting liquid, the apparatus includes an ejection detection unit (ejection state detection unit) that detects the ejection state of ejection of the liquid from the nozzle. It is known to perform a recovery operation.

  Conventionally, it has been known that when the ejection failure cannot be recovered even if the recovery operation is repeated a predetermined number of times in succession for the ejection failure, the printing is continued as it is without performing ejection detection thereafter. (Patent Document 1).

JP 2012-176537 A

  By the way, when a discharge failure is detected, the discharge state may not be resolved even if the nozzle recovery operation is performed. If the recovery operation is repeated for such an unrecoverable ejection failure nozzle, the recovery operation time and the liquid accompanying the recovery operation are wasted.

  On the other hand, there are various types of nozzle ejection defects, such as those that are improved by a recovery operation such as clogging of the thickening liquid, and those that are not improved by a recovery operation such as physical damage of the nozzle.

  Therefore, there is a problem that it is necessary to reduce the useless recovery operation and to perform the recovery operation when the nozzle state is improved from the ejection failure state.

  The present invention has been made in view of the above problems, and an object thereof is to perform an efficient recovery operation.

In order to solve the above problems, an apparatus for ejecting a liquid according to the present invention includes:
A liquid discharge head having a plurality of nozzles for discharging liquid;
Discharge detection means for detecting the liquid discharge state of each nozzle of the liquid discharge head;
Means for controlling a recovery operation for recovering the state of the nozzle of the liquid discharge head,
The means for controlling is
It is determined whether or not a predetermined abnormal discharge for performing the recovery operation has occurred from the detection result of the discharge detection means,
When it is determined that the predetermined abnormal discharge has occurred, the occurrence history of the predetermined abnormal discharge is stored,
Until the occurrence history reaches a predetermined condition, perform the recovery operation,
If it is not determined that the predetermined abnormal discharge has occurred before the occurrence history reaches the predetermined condition, the stored occurrence history is discarded.

  According to the present invention, an efficient recovery operation can be performed.

It is plane explanatory drawing of the mechanism part of an example of the apparatus which discharges the liquid which concerns on this invention. It is a principal part side surface explanatory drawing similarly. FIG. 6 is an explanatory plan view for explaining the head configuration. FIG. 2 is a schematic explanatory diagram of a liquid supply / discharge system of the apparatus. It is block explanatory drawing of the control part of the apparatus. FIG. 4 is a side explanatory view of the carriage portion and the discharge detection unit in a state where the discharge detection unit faces the head. It is an external appearance perspective explanatory view of the discharge detection unit. It is a partially broken perspective explanatory view of the detection unit. It is block explanatory drawing of an example of a discharge detection part. It is explanatory drawing with which it uses for description of the detection output by the discharge detection part. It is explanatory drawing with which it uses for description of the other example of a liquid discharge detection unit. It is explanatory drawing similarly used for an effect | action description. It is a block explanatory drawing of an example of the control part which similarly concerns on discharge detection. It is explanatory drawing of an example of the image compensation printing performed when a non-ejection nozzle generate | occur | produces. It is explanatory drawing of the other example of image compensation printing similarly. It is a flowchart with which it uses for description of the process in connection with discharge detection by the control part in 1st Embodiment of this invention, and control of recovery | restoration operation | movement. It is a flowchart with which it uses for description of the process following FIG. It is explanatory drawing with which it uses for concrete description of the same embodiment. It is explanatory drawing with which it uses for concrete description of the same embodiment. It is explanatory drawing with which it uses for concrete description of the same embodiment. It is explanatory drawing with which it uses for description when not being filled by nozzle redundancy processing. It is a flowchart with which it uses for description of the process in connection with discharge detection by the control part in 2nd Embodiment of this invention, and control of recovery | restoration operation | movement. It is a flowchart with which it uses for description of the process in connection with discharge detection by the control part in 3rd Embodiment of this invention, and control of recovery | restoration operation | movement. It is explanatory drawing with which it uses for description of the example from which an alerting | reporting example differs.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. An example of an apparatus for ejecting liquid according to the present invention will be described with reference to FIGS. FIG. 1 is an explanatory plan view of the mechanism of the apparatus, FIG. 2 is an explanatory side view of the main part, and FIG. 3 is an explanatory plan view for explaining the head configuration. Note that FIG. 3 shows the head transmitted from above.

  This apparatus is a serial type apparatus, and a carriage 3 is held by a guide mechanism such as a main guide member 1 so as to be movable in the main scanning direction. The carriage 3 is reciprocated in the main scanning direction (carriage moving direction) by a main scanning motor 5 constituting a main scanning moving mechanism via a timing belt 8 spanned between the driving pulley 6 and the driven pulley 7.

  On the carriage 3, two liquid discharge units 40A and 40B (referred to as “liquid discharge unit 40” when not distinguished) are mounted. The liquid discharge unit 40 is configured by integrating a liquid discharge head 41 as liquid discharge means and a head tank 42 that supplies liquid to the liquid discharge head 41.

  As shown in FIG. 3, the liquid discharge head 41 has two nozzle rows Na and Nb in which a plurality of nozzles 41n are arranged. One nozzle row Na of the head 41 of the liquid discharge unit 40A discharges black (K) droplets, and the other nozzle row Nb discharges cyan (C) droplets. Further, one nozzle row Na of the head 41 of the liquid discharge unit 40B discharges magenta (M) droplets, and the other nozzle row Nb discharges yellow (Y) droplets.

  In addition, as a liquid discharge means, what is equipped with the several nozzle row | line | column which discharges the droplet of each color which arranged the several nozzle in the nozzle surface of one liquid discharge head etc. can also be used.

  The head tank 42 is configured to include a plurality of tank portions each corresponding to the two nozzle rows Na and Nb of each head 41, each paired with two tank portions that store liquids of the respective colors.

  On the apparatus main body side, a cartridge holder 51 to which a main tank (liquid cartridge) 50 (50y, 50m, 50c, 50k) containing liquid of each color is replaceably mounted is disposed.

  The cartridge holder 51 is provided with a liquid feed pump unit 52, and each color is supplied from the main tank 50 to the tank portion of each head tank 42 through a supply tube (also referred to as a liquid supply path) 56 of each color by the liquid feed pump unit 52. Liquid is supplied.

  On the other hand, in order to transport the paper P, a transport belt 12 that is a transport means for sucking the paper P and transporting the paper P at a position facing the head 41 of the liquid discharge unit 40 is provided.

  The conveyor belt 12 is an endless belt and is stretched between the conveyor roller 13 and the tension roller 14.

  The conveyance belt 12 rotates in the sub-scanning direction when the conveyance roller 13 is rotationally driven by the sub-scanning motor 16 via the timing belt 17 and the timing pulley 18. The conveyor belt 12 is charged (charged) by a charging roller (not shown) while rotating around, or the sheet P is sucked by a suction unit.

  Further, on one side of the carriage 3 in the main scanning direction, a maintenance / recovery mechanism 20 which is one of recovery means for maintaining / recovering the head 41 is disposed on the side of the transport belt 12. On the other side of the carriage 3 in the main scanning direction, idle discharge receivers 81 for receiving liquid preliminarily discharged (empty discharge) from the head 41 are arranged on the sides of the conveyance belt 12. The discharge for maintaining and recovering the head state is called preliminary discharge, and the discharge for achieving the original purpose of the apparatus is called main discharge.

  The maintenance / recovery mechanism 20 includes, for example, a suction cap 21 for capping the nozzle surface 41a of the head 41, a moisturizing cap 22, a wiper member 23 for wiping the nozzle surface 41a, and an empty discharge receiver 24 for receiving a spare liquid. .

  Further, in an area outside the recording area between the conveyance belt 12 and the maintenance / recovery mechanism 20 and capable of facing the head 41, an ejection detection unit 100 constituting liquid ejection detection means for detecting the ejection state of the head 41. Is arranged.

  In addition, an encoder scale 123 having a predetermined pattern is stretched between both side plates along the main scanning direction of the carriage 3, and an encoder sensor 124 formed of a transmission type photosensor that reads the pattern of the encoder scale 123 is provided on the carriage 3. Provided. These encoder scale 123 and encoder sensor 124 constitute a linear encoder (main scanning encoder) that detects the movement of the carriage 3.

  Further, a code wheel 125 is attached to the shaft of the transport roller 13 and an encoder sensor 126 including a transmission type photo sensor for detecting a pattern formed on the code wheel 125 is provided. These code wheel 125 and encoder sensor 126 constitute a rotary encoder (sub-scanning encoder) that detects the amount and position of movement of the conveyor belt 12.

  In the apparatus configured as described above, the paper P is fed onto the transport belt 12 and sucked, and is transported in the sub-scanning direction by the circumferential movement of the transport belt 12.

  Therefore, by driving the head 41 according to the image signal while moving the carriage 3 in the main scanning direction, liquid is ejected onto the stopped paper P to record one line. Then, after the sheet P is conveyed by a predetermined amount, the next line is recorded.

  Upon receiving a recording end signal or a signal that the trailing edge of the paper P reaches the recording area, the printing operation is terminated, and the paper P is discharged onto a paper discharge tray (not shown).

  Next, a liquid supply / discharge system in this apparatus will be described with reference to FIG. FIG. 4 is a schematic explanatory view of the supply / discharge system.

  First, the liquid supply from the main tank 50 to the head tank 42 is performed via the supply tube 56 by the liquid feed pump 54 of the liquid feed pump section 52 which is a liquid feed means.

  The liquid feed pump 54 is a reversible pump (reversible liquid feed means) constituted by a tube pump or the like, and a liquid feed operation for supplying a liquid from the main tank 50 to the head tank 42 and a head tank 42 to the main tank. The liquid is returned back to 50 so as to perform a reverse feeding operation.

  Further, a suction pump 27 serving as a suction means is connected to the suction cap 21 for capping the nozzle surface of the head 41 via a suction tube 26. Then, the liquid in the head tank 42 can be sucked by sucking the liquid from the nozzle 41 n through the suction tube 26 by driving the suction pump 27 in the state of being capped by the suction cap 21. The sucked waste liquid is discharged to the waste liquid tank 28.

  An air release solenoid 45 that is a member for opening and closing the air release mechanism 42A of the head tank 42 is disposed on the apparatus main body side. By operating the atmosphere release solenoid 45, the atmosphere release mechanism 42A can be opened. Further, on the apparatus main body side, a main body side sensor 46 that detects a displacement member 42B that is displaced according to the remaining amount of liquid in the head tank 42 is disposed.

  The controller 500 controls the above-described drive control of the liquid feed pump 54, the air release solenoid 45, the suction pump 27, the detection of the displacement member 42B by the main body side sensor 46, and the negative pressure forming operation of the head tank 42. Done.

  Here, the nozzle recovery operation will be described.

  As the nozzle recovery operation, for example, the nozzle surface 41a of the head 41 is capped with the suction cap 21, the suction pump 27 is driven, and the liquid is sucked and discharged from the nozzle 41n.

  This forced suction / discharge process of the liquid from the nozzle is called a cleaning operation. The cleaning operation is executed, for example, when recording is resumed after a long pause of the apparatus, or when the user recognizes a defective recording state and operates the cleaning switch every predetermined time during recording.

  Further, the nozzle recovery operation includes an operation of performing preliminary discharge (empty discharge) from the nozzle, or an operation of pressure-feeding liquid from the main tank 50 to the head 41 side by the liquid feed pump 54. Alternatively, these various recovery operations can be implemented in combination.

  Next, an outline of the control unit of this apparatus will be described with reference to FIG. FIG. 5 is a block diagram of the control unit.

  The control unit 500 includes a CPU 501 that controls the entire apparatus, a ROM 502 that stores fixed data such as various programs including a program according to the present invention executed by the CPU 501, and a RAM 503 that temporarily stores image data and the like. A control unit 500A is provided.

  In addition, the control unit 500 includes a rewritable nonvolatile memory (NVRAM) 504 for holding data while the apparatus is powered off, image processing for performing various signal processing, rearrangement, and the like on image data. In addition, an ASIC 505 for processing input / output signals for controlling the entire apparatus is provided.

  The control unit 500 includes a data transfer unit for driving and controlling the head 41, a print control unit 508 including a driving signal generating unit, and a head driver (driver IC) provided on the carriage 3 side for driving the head 41. 509.

  In addition, the control unit 500 includes a main scanning motor 5 that moves and scans the carriage 3, a sub-scanning motor 16 that rotates the conveyance belt 12, and a motor driving unit 510 that drives the maintenance / recovery motor 556 of the maintenance / recovery mechanism 20. ing. The maintenance / recovery motor 556 drives the moving mechanism 29 and the suction pump 27 that move the caps 21 and 22 and the wiper member 23 of the maintenance / recovery mechanism 20 up and down (advance and retreat).

  In addition, the control unit 500 includes a supply system driving unit 512 that drives the liquid feeding pump 54. In addition, the control unit 500 includes a discharge detection unit 515 that performs discharge detection by the discharge detection unit 100.

  The control unit 500 is connected to an operation panel 514 for inputting and displaying information necessary for the apparatus.

  The control unit 500 has an I / F 506 for transmitting and receiving data and signals to and from the host side. A predetermined information is sent from an information processing apparatus such as a personal computer or a printer driver 601 side of the host 600 such as an image reading apparatus. Send and receive data.

  The CPU 501 of the control unit 500 reads and analyzes the print data in the reception buffer included in the I / F 506, performs necessary image processing, data rearrangement processing, and the like in the ASIC 505, and prints the image data. The data is transferred from the unit 508 to the head driver 509.

  The print control unit 508 transfers the above-described image data as serial data, and outputs a transfer clock, a latch signal, a control signal, and the like necessary for transferring the image data and confirming the transfer to the head driver 509.

  The print control unit 508 includes a drive signal generation unit including a D / A converter that converts D / A conversion of drive pulse pattern data stored in the ROM 502, a voltage amplifier, a current amplifier, and the like. A drive waveform composed of one drive pulse or a plurality of drive pulses is generated and output to the head driver 509.

  The head driver 509 selects a driving pulse constituting a driving waveform provided from the print control unit 508 based on image data corresponding to one line of the head 41 input serially, and applies pressure to the pressure generating unit of the head 41. And the head 41 is driven. At this time, by selecting part or all of the pulses constituting the drive waveform or all or part of the waveform elements forming the pulses, for example, dots of different sizes such as large drops, medium drops, and small drops Can be sorted out.

  The I / O unit 513 acquires information from the temperature sensor 572 and other various sensor groups 570 attached to the apparatus, extracts information necessary for controlling the apparatus, and uses it for various controls.

  In this apparatus, a liquid discharge detection unit that detects whether or not liquid is discharged from the nozzle 41a of the head 41 is configured by the discharge detection unit 100, the discharge detection unit 515, and the main control unit 500A.

  Next, the configuration of the discharge detection unit 100 will be described with reference to FIGS. 6 is a side view of the carriage portion and the discharge detection unit in a state where the discharge detection unit faces the head, FIG. 7 is an external perspective view of the discharge detection unit, and FIG. 8 is a partially broken perspective view of the detection unit. It is explanatory drawing.

  The discharge detection unit 100 includes a box-shaped holder member 103 in which a receiving member 102 that receives the liquid discharged from the head 41 is integrally formed. The upper surface wall portion of the holder member 103 is a receiving member 102, and the upper surface of the holder member 103 is a receiving surface 102 a to which the liquid discharged from the head 41 adheres.

  And in the holder member 103, the electrode plate 101 which is an electrode member is arrange | positioned on the opposite side (back surface) to the receiving surface 102a to which the liquid of the receiving member 102 adheres. As a result, the electrode plate 101 is covered with the receiving member 102. In this embodiment, the electrode plate 101 is disposed in contact with the back surface of the receiving member 102.

  The holder member 103 is an insulating member made of an insulating material such as plastic, including a portion that becomes the receiving member 102. It is preferable that the upper surface to be the receiving surface 102a of the receiving member 102 is subjected to water repellent treatment.

  The electrode plate 101 is a conductive metal plate, and is formed of, for example, SUS304, a copper alloy with Ni plating, or Pd plating.

  The electrode plate 101 is connected to the discharge detection unit 515 via a lead wire 109.

  Further, the holder member 103 has an opening 110 on the end side in the wiping direction by the wiper member 201. Then, a wiper cleaner 111 which is a cleaning member for removing and cleaning waste liquid (liquid attached to the wiper member 201) from the wiper member 201 is formed in a part (edge portion) of the opening 110. Yes.

  The holder member 103 is provided with a waste liquid tube 112 that forms a flow path from the lower side of the opening 110 to a waste liquid tank (not shown). Further, it is preferable that a suction pump is disposed in the flow path leading to the waste liquid tank so that the waste liquid accumulated at the bottom of the opening 110 is forcibly discharged to the waste liquid tank.

  On the other hand, the carriage 3 is provided with a wiping unit 200 that is a wiping means including a wiper member 201 that moves and wipes the liquid adhering to the receiving surface 102a of the receiving member 102 along the nozzle arrangement direction.

  The wiper member 201 is attached to a timing belt 223 that is wound between the driving pulley 221 and the driven pulley 222. Then, the drive pulley 221 is rotationally driven through the worm gear 224 and the gear 225 by the drive motor 203 which is a drive source attached to the carriage 3, so that the wiper member 201 moves in the direction of arrow A together with the timing belt 223.

  Further, the wiping unit 200 includes a wiper retracting cover 204 that covers the wiper member 201 at the retracted position. When the wiper member 201 is not used, the wiper member 201 is stored in the wiper retracting cover 204. Thereby, it is possible to prevent a small amount of waste liquid adhering to the wiper member 201 from being scattered during the carriage operation.

  Next, an example of the discharge detection unit will be described with reference to FIGS. FIG. 9 is an explanatory block diagram of the ejection detection unit, and FIG. 10 is an explanatory diagram for explaining detection output by the ejection detection unit.

  The discharge detection unit 515 includes a high voltage power source 701 that applies a high voltage VE (for example, 750 V) to the electrode plate 101. The high voltage power source 701 is on / off controlled by the main controller 500A.

  In addition, a band-pass filter (BPF) 702 that inputs a signal associated with an electrical change when the liquid discharged on the receiving surface 102a of the receiving member 102 adheres, an amplifier (AMP) 703 that amplifies the signal, and an amplified signal And an AD converter (ADC) 704 for A / D conversion. The conversion result of the ADC 704 is input to the main controller 500A.

  When the main controller 500A detects ejection, the nozzle surface 41a of the head 41 and the receiving member 102 are opposed to each other, the high voltage VE is applied to the electrode plate 101, and a potential difference is generated between the nozzle surface 41a and the electrode plate 101. give. At this time, the nozzle surface 41a of the head 41 is negatively charged, and the electrode plate 101 is positively charged.

  In this state, the detection liquid is ejected from the head 41 one nozzle at a time.

  At this time, since the discharged liquid droplets are discharged from the nozzle surface 41a of the head 41 charged negatively, the liquid is also negatively charged. When the negatively charged liquid adheres to the receiving surface 102a of the receiving member 102 made of an insulating member and approaches the positively charged electrode plate 101, the voltage of the high voltage VE applied to the electrode plate 101 is very small. Fluctuates.

  Therefore, the fluctuation (AC component) is extracted by the band pass filter 702, amplified by the amplifier circuit 703, A / D converted by the ADC 704, and input to the main controller 500A as a measurement result (detection result).

  For example, as shown in FIG. 10B, when a waveform (discharge waveform) for continuously discharging five drops of liquid is given as shown in FIG. 10A, when the nozzle is normally discharging, as shown in FIG. Detection output (AC component) can be obtained.

  Therefore, the main control unit 500A determines whether or not the measurement result (variation) exceeds a preset threshold value, and when the measurement result exceeds the threshold value, the main control unit 500A is discharging (discharge is present, normal discharge is performed). ), And when it does not exceed the threshold, it is determined that there is no ejection (no ejection).

  Here, when ejecting one nozzle at a time, it takes about 0.5 to 10 msec to determine ejection / non-ejection of one nozzle. Therefore, by giving waveforms to be ejected simultaneously to two nozzles, comparing the detection output with two threshold values, if both nozzles are ejected, if one nozzle has not been ejected, both are not ejected. The case can also be determined.

  After the determination of ejection / non-ejection for all nozzles is completed, the high voltage VE applied to the electrode plate 101 is turned off.

  In addition, since a high voltage is applied to the electrode plate 101, the insulation between the electrode plate 101 and the device casing having a potential of 0 V (GND) cannot be maintained, for example, when the environment is a high humidity environment where condensation occurs. In some cases, noise is superimposed on the detection output.

  In this way, when noise is superimposed on the detection output, the discharge detection operation is not performed or the maintenance operation based on the detection result is performed until the environment is improved or the time until the attached waste liquid dries. Do not do it.

  Further, in the above configuration, since the electrode plate 101 is covered with the holder 103 of the insulating member, even if a liquid adheres to the holder 103 and it drops down in the gravity direction, the electrode plate 101 Insulation with the device casing having a potential of 0 V (GND) is maintained, and noise due to poor insulation does not occur.

  Next, another example of the liquid discharge detection unit will be described with reference to FIGS. FIG. 11 is an explanatory diagram for explaining the liquid discharge detection unit, and FIG. 12 is an explanatory diagram for explaining the operation.

  The discharge detection unit 100 condenses the light emitted from the light emitting unit 191 formed of a laser diode through the collimator lens 192 and emits it as laser light 193. The scattered light 194 generated by the laser light 193 being scattered by the droplet 301 is received by the light receiving unit 195 made of a photodiode, converted into a voltage, and output. Note that although a method of receiving scattered light is used here, a method of directly receiving the laser light 193 may be used.

  By comparing this output voltage with a predetermined threshold value, it is possible to detect whether or not the nozzle 41n that discharges the liquid droplet is normal discharge (whether or not it is discharged).

  For example, the relationship between the degree of drying of the liquid in the nozzle 41n and the droplet volume of the ejected droplet is such that the droplet volume decreases as the degree of drying increases.

  Therefore, as shown in FIG. 12, when the droplets 301 are sequentially ejected from each nozzle 41a of the head 41, for example, the droplet volume of the droplet 302 ejected from the sixth nozzle 41a from the left in FIG. Let it be less.

  At this time, the output voltage (droplet detection output) V1 of the light receiving unit 195 when the droplet 302 from the nozzle 41a is detected is as shown by a solid line in FIG. That is, the output voltage V1 when the droplet 302 is detected is lower than the output voltage V0 in the normal ejection state indicated by the broken line in FIG. 12 by the differential voltage ΔV.

  Here, the difference voltage ΔV between the normal output voltage V0 and the actual output voltage V1 corresponds to the droplet volume, and the voltage ΔV increases when the droplet volume becomes smaller than the predetermined droplet volume.

  Therefore, for example, when the difference voltage ΔV between the actual output voltage V1 and the regular output voltage V0 is compared with a predetermined value (threshold value) based on an allowable drop volume fluctuation range, The nozzle that has ejected the liquid droplets can be determined as no ejection (non-ejection), and when it is less than the threshold, it can be determined that there is ejection (normal ejection).

  Next, an example of a control portion related to ejection detection in this example will be described with reference to the block explanatory diagram of FIG.

  The main control unit 500A instructs the discharge detection determination unit 802 of the discharge detection unit 515 to start the discharge detection operation at a predetermined discharge detection start timing. At this time, the main controller 500A moves the carriage 3 to a position where the predetermined head 41 corresponds to the ejection detection unit 100, and sequentially receives liquid from the nozzles 41n of the head 41 while receiving the determination result of the ejection detection determination unit 802. Control to eject drops.

  The ejection detection determination unit 802 drives and controls the light emitting unit 191 via the I / F 801 to emit the laser light 193 as described above, inputs the light reception output from the light receiving unit 195, and as described above, drops volume. Is calculated, the difference voltage ΔV is compared with a predetermined threshold value to determine the presence or absence of ejection, and the determination result is given to the main control unit 500A.

  The liquid discharge detection can also be performed by, for example, outputting a predetermined pattern and reading this with a scanner to determine the presence or absence of discharge.

  Next, different examples of image compensation printing performed when a non-ejection nozzle occurs will be described with reference to the explanatory diagrams of FIGS.

  The first example shown in FIG. 14 is an example in which image compensation is performed by multi-scan processing. For example, as shown in FIG. 14A, for a dot row 325 in which nozzle omission occurs due to a non-ejection nozzle in the first scan, for example, as shown in FIG. The dot row 326 is printed using a normal discharge nozzle.

  The second example shown in FIG. 15 is an example in which image compensation is performed by nozzle redundancy processing. As shown in FIG. 15 (a), the normal nozzles adjacent to both sides of the liquid droplets 328 that are originally ejected from the non-ejection nozzles are not normally used without printing the corresponding nozzles determined as non-ejection nozzles. By ejecting droplets 329 and 330 having a larger droplet volume, as shown in FIG. 5B, the portion that should be originally printed by the non-ejection nozzle is made inconspicuous.

  Next, processing relating to ejection detection and recovery operation control by the control unit in the first embodiment of the present invention will be described with reference to the flowcharts of FIGS. 16 and 17.

  In this apparatus, the process of FIG. 16 is entered at a predetermined discharge detection timing. The discharge detection timing is, for example, when the power is turned on, before printing, during printing, after printing, after intentional recovery processing by the user, after recovery from device abnormality (after recovery from jamming or interruption of recovery processing), liquid For example, after a return from the end of the cartridge, after a predetermined time has elapsed.

  Further, abnormal discharge refers to abnormal discharge (discharge failure) such as discharge failure, discharge bend, numerous missing nozzles, and mixed colors.

  Of the abnormal ejections, abnormal ejection that can ensure image quality by the above-described image compensation control (processing) without performing the recovery operation is referred to as “mild abnormal ejection”. On the other hand, the abnormal discharge that performs the recovery operation described above is referred to as “severe abnormal discharge”, and this “severe abnormal discharge” is referred to as “predetermined abnormal discharge” in the present invention. In other words, a severe abnormal discharge is also an abnormal discharge that stops performing the recovery operation as will be described later when the recovery operation does not recover even after a predetermined number of times of recovery operation.

  In FIGS. 16 and 17, “k” is a stored value of the number of occurrences of severe abnormal ejection as the history of occurrence of severe abnormal ejection. The occurrence history of severe abnormal ejection is stored in, for example, the VRAM 504 or the like. “M” is a value for specifying a head. Since this apparatus includes two heads 41, m = 1 or 2.

  First, referring to FIG. 16, n = 1 is set (step S1: hereinafter referred to simply as “S1”). Then, a discharge detection operation is performed on the head 41 that needs to detect discharge (this is expressed as “head (m)”) (S2). Thereafter, m = 1 is set (S3).

  Then, the determination target head is set to the head (m) (S4), and it is determined whether all the nozzles 41n of the determination target head (m) are normally ejected (S5).

  Here, when all of the nozzles 41n are normally ejected, “k”, which is the number of occurrences as the occurrence history of severe abnormal ejection, is reset to zero (k = 0) (S6).

  As a result, even if severe abnormal ejection has occurred, if normal ejection is detected by subsequent ejection detection, the history of occurrence of severe abnormal ejection, which is abnormal ejection performing the recovery operation, is discarded. That is, if the occurrence history of severe abnormal ejection (occurrence number k) is not determined as severe abnormal ejection in subsequent ejection detection until k> threshold as a predetermined condition, the severe abnormal ejection is determined. Occurrence history is discarded (deleted).

  Thereafter, a process of using the determination target head (m) as the normal print head (m) is performed (S7).

  On the other hand, when all the nozzles of the determination target head (m) are not normally ejected, that is, when there are ejection failure nozzles (abnormal ejection nozzles) such as non-ejection nozzles, it is determined whether or not they are severely abnormal ejection. (S8).

  At this time, if it is not a severe abnormal discharge, that is, if it is an abnormal discharge that is not so high as to perform a recovery operation (a mild abnormal discharge), “k”, which is the number of occurrences of the occurrence of a severe abnormal discharge, is reset to zero. (K = 0) (S9).

  As a result, even if a severe abnormal discharge has occurred, if a slight abnormal discharge is detected in the subsequent discharge detection, the occurrence history of the severe abnormal discharge that is an abnormal discharge that performs the recovery operation is discarded. . That is, if the occurrence history of severe abnormal ejection (occurrence number k) is not determined as severe abnormal ejection in subsequent ejection detection until k> threshold as a predetermined condition, the severe abnormal ejection is determined. Occurrence history is discarded (deleted).

  Thereafter, it is determined whether or not n <2 (S10). Here, if n <2, the process of using the determination target head (m) as the image compensation print head (m) is performed (S11). If n <2, the determination target head (m) is image compensated. Processing to be used as the print head (m) is performed (S12).

  On the other hand, if it is a severe abnormal discharge, it is determined whether or not n <2 (S13). Here, if n <2, k = k + 1 is set (S14), and “1” is added to the number of occurrences as the occurrence history of severe abnormal discharge.

  Thereafter, the determination target head (m) is reserved as a head (m) scheduled to be cleaned (recovery operation) (S15).

  If n <2, the process proceeds to the next step S16 without performing these processes.

  After the determination on the determination target head (m) is completed as described above, m = m + 1 is set (S16).

  Next, referring to FIG. 17, it is determined whether or not there is a next head to be subjected to ejection detection (S17), and when there is a head to be subjected to ejection detection, the process returns to step S4, and the head to be judged is set as the head. (M).

  On the other hand, when there is no head to be subjected to ejection detection next, it is determined whether or not there is a head (m) that requires a recovery operation (for example, a cleaning operation) (S18).

  Here, when there is a head (m) that requires a recovery operation, it is determined whether or not k> threshold (S19). That is, it is determined whether or not the number k of occurrences of severe abnormal ejection has exceeded a predetermined threshold value.

  If k> threshold is not satisfied, the recovery operation is performed for all the heads (m) reserved for the recovery operation (S20). Thereafter, n = n + 1 is set (S21), the process returns to step S2, and the process shifts to a process of performing ejection detection on the necessary head (m).

  On the other hand, if k> threshold, the reservation of all the recovery operations is canceled for all the heads (m) reserved for the recovery operation (S22), and the process ends.

  If there is no head (m) that requires a recovery operation, the process is terminated as it is.

  A program for causing a computer to perform the above processing by the control unit is stored and held in the ROM 502 of the main control unit 500A.

  Next, the present embodiment will be specifically described with reference to FIGS.

  In the present embodiment, as described above, it is determined from the result of the discharge detection whether the discharge is normal discharge, mild abnormal discharge, or severe abnormal discharge (S5, S8). Based on the determination result, as the post-discharge detection operation (the operation of the apparatus after discharge detection), if normal discharge, the process proceeds to normal printing (S7), and if it is mild abnormal discharge, printing by image compensation is performed. (S11), and if it is a severe abnormal discharge, the process proceeds to a process for executing a recovery operation (recovery process) (S20).

  Here, it is known from the discharge detection result that the abnormal discharge is severe in the case of shifting to the recovery process (process for performing the recovery operation) in the post-discharge detection operation. At this time, a history of occurrence of severe abnormal discharge is stored in the apparatus (S14).

  Then, based on this history, before performing the recovery process, it is determined whether it is a case of returning from abnormal ejection or a case of not returning (S19).

  The criterion for determining whether or not to return is, for example, whether or not severe abnormal ejection has occurred a certain number of times in succession. When severe abnormal ejection occurs continuously and exceeds a certain threshold, if the subsequent ejection detection result is severe abnormal ejection, the recovery process is not performed in the operation after ejection detection (S22).

  For example, in the example shown in FIG. 18, the threshold value is set to 3 times. Accordingly, when the discharge detection result is severe discharge abnormality until the first, second, and third discharge detection results, in step S19, k> threshold value (three times) is not satisfied, and the recovery operation is performed.

  Then, when the fourth detection result in which k> 3 in step S19 is a severe discharge abnormality, all the recovery operation reservations are canceled (S22), and the subsequent recovery processing (processing for performing recovery operation) Is prohibited.

  As a result, for example, if an abnormal discharge that cannot be recovered by the recovery process occurs due to a head failure, etc., liquid is not consumed more than necessary, and downtime until output occurs. Will not do.

  Note that the criterion for determining whether or not to return from severe abnormal discharge may be, for example, the case where a history of abnormal discharge continuously from the same nozzle continues.

  Further, the first, second,... Discharge detection result in the number of discharge detections in FIG. 18 may be a continuous discharge detection operation, or at a certain discharge detection timing, for example, a printing operation or a power ON operation other than the discharge detection. Alternatively, the number of times of discharge detection when the discharge detection operation is performed discontinuously across the gap may be used.

  On the other hand, even if severe abnormal discharge has occurred, if the next discharge detection result shifts to normal discharge or mild abnormal discharge, the history of occurrence of severe abnormal discharge is discarded (S6, S9).

  The improved discharge state is because there is a high possibility of self-recovery by recovery processing or the like.

  In such a case, since it was a case that returned even during severe abnormal discharge, the execution of the recovery process according to the next discharge detection result is permitted.

  Even if severe abnormal discharge occurs again continuously, the recovery process is permitted until a certain value is exceeded (S19, S20).

  By doing so, it is possible to restore abnormal ejection that can be recovered by the recovery process.

  For example, in the example shown in FIG. 19, since the first and second discharge detection results are both severe abnormal discharges and k> threshold (three times), recovery processing is performed in each post-discharge detection operation. ing.

  After that, the discharge detection result of the third discharge detection operation is improved to mild abnormal discharge. Therefore, the recovery process is carried out by resetting the occurrence history (k) of severe abnormal discharge (S9) (S19, S20).

  In addition, after the discharge detection result after the fourth discharge detection operation, severe abnormal discharge is detected again, but in this case, k> threshold (three times) is not satisfied. Recovery processing is performed.

  Further, for example, in the example shown in FIG. 20, since the first and second discharge detection results are both severe abnormal discharges and k> threshold (three times), the recovery process is performed in each post-discharge detection operation. We are carrying out.

  Subsequent discharge detection results from the discharge detection operation are improved to normal discharge in the third time. Therefore, the recovery process is carried out by resetting the occurrence history (k) of severe abnormal discharge (S9) (S19, S20).

  In addition, after the discharge detection result after the fourth discharge detection operation, severe abnormal discharge is detected again, but in this case, k> threshold (three times) is not satisfied. A recovery process is performed.

  Next, the abnormal ejection that performs the recovery operation (severe abnormal ejection) and the abnormal ejection that does not perform the recovery operation (mild abnormal ejection) are distinguished, for example, as follows.

  For example, in image compensation by multi-scan processing, when the number of abnormal nozzles is small, the number of scans that the carriage scans for image compensation is small, but when the number of abnormal nozzles is large, the number of scans that the carriage scans for image compensation Increases and takes time to output. Therefore, in such a case, it is preferable to move to the recovery process rather than performing image compensation.

  Also, in the image compensation by nozzle redundancy processing, if abnormal nozzles are continuous, even if the droplets ejected from both adjacent nozzles are enlarged, the portion that should have been filled may be filled for image compensation. White streaks may be noticeable.

  This point will be described with reference to FIG. FIG. 21 is an explanatory diagram for explaining the case where the nozzle redundancy processing is not performed.

  Here, when one nozzle (denoted as 1ch) is a non-ejection nozzle, the non-ejection nozzle portion can be filled by performing redundancy processing on the ejection droplets from adjacent nozzles. On the other hand, when two consecutive nozzles (denoted as 2ch) are non-ejection nozzles, the portion between the non-ejection nozzles cannot be filled even if the droplets ejected from both adjacent nozzles are enlarged. White streaks occur.

  Therefore, in such a case, it is preferable to move to the recovery process rather than performing image compensation.

  On the other hand, when the number of non-ejection nozzles is small, image defects can be alleviated, and printing by image compensation processing is performed. As a result, an output product close to normal (with reduced image defects) can be obtained without performing automatic recovery processing or recovery processing according to a user instruction. For this reason, the liquid used in the recovery process is not consumed, and the downtime corresponding to the recovery process does not occur.

  These determinations can be made based on abnormal discharge patterns incorporated in advance.

  For example, it is possible to determine whether the number of abnormal ejection, continuity with adjacent nozzles of abnormal ejection, abnormal ejection patterns (how to escape) are conspicuous as compared to the actual image to be drawn, and the like.

  Specifically, the number of abnormal ejection nozzles is compared with a threshold value. If the number of abnormal ejection nozzles is greater than the threshold value, it is determined that the abnormal ejection is severe (predetermined abnormal ejection), and the recovery operation is performed. If the number of nozzles is less than or equal to the threshold value, it is determined that there is a slight abnormal discharge, and a printing process by image compensation is performed.

  Alternatively, it is determined whether or not a nozzle adjacent as a pixel is missing depending on the printing method. For example, when abnormal discharge nozzles continue a predetermined number of pixels on the image, severe abnormal discharge (predetermined abnormal discharge) has occurred. Determine and implement recovery action.

  Next, processing relating to discharge detection and recovery operation control by the control unit in the second embodiment of the present invention will be described with reference to the flowchart of FIG.

  In the present embodiment, as the processing in step S8 in the first embodiment, it is determined whether or not image compensation printing is possible, and when image compensation printing is possible, light abnormal ejection is performed and image compensation printing is performed. When it is not possible, processing similar to that in the first embodiment is performed as severe abnormal ejection. Note that the processing of FIG. 17 is applied to the present embodiment as it is, and therefore the steps of FIG. 17 are used in the description.

  Therefore, for example, if one abnormal discharge nozzle exists and image compensation printing cannot be performed as a result of the first discharge detection, “k” is incremented (+1) through steps S5 and S8 (S13). , S14), and thereafter, a recovery operation is performed (S21 in FIG. 17).

  After completion of the recovery operation, discharge detection is performed, and the discharge state is reconfirmed (S5, S8). As a result, when all the nozzles are normally ejected, or when image compensation printing is possible, k is reset (k = 0) (S6, S9).

  On the other hand, if image compensation printing is still not possible, the process ends because n = 2 in the determination process of step S13.

  At this time, k holds the same value, so the same processing as described above is applied also at the next ejection detection. However, if k exceeds the threshold value in step S19 in FIG. 17, since all reservations for the recovery operation are canceled, the recovery operation is not performed.

  In other words, k continues to be incremented (+1) and maintained while abnormal ejection that cannot compensate for the image (severe abnormal ejection) continues.

  However, as a result of the next ejection detection, when all the nozzles are normally ejected or image compensated printing is possible, k is reset, and the history of occurrence of severe abnormal ejection is discarded (deleted). .

  For example, when a discharge failure occurs due to a physical failure of the head, there is no expectation of recovery even if recovery processing by cleaning is performed. However, in order to distinguish from normal recoverable discharge failures, it is possible to analyze whether abnormal discharge that cannot be recovered or abnormal discharge that can be recovered by analyzing whether continuous abnormal discharge is severe or not. Judgment is being made.

  Next, processing relating to discharge detection and recovery operation control by the control unit in the third embodiment of the present invention will be described with reference to the flowchart of FIG.

  In this embodiment, the process of notifying the user that there is an abnormal ejection nozzle after canceling the reservation of all the heads reserved for the recovery operation in step S22 in the first embodiment or the second embodiment. Perform (S23).

  As a notification example, as shown in FIG. 24 (a), since there is a possibility that a defect may occur in the output product, a notification recommending the implementation of the recovery process is given. As a result, the user can suppress the printing of the output material having the ejection failure by performing the recovery process.

  In addition, as shown in FIG. 24B, it is a method of recommending a recovery process by designating a head in which ejection failure occurs. As a result, the user can suppress the printing of the output material having the ejection failure by performing the recovery process on the necessary head.

  In addition, as shown in FIG. 24C, when there is a possibility that an output product may be defective, for example, a service person is instructed to instruct contact with a designated contact. As a result, even if a head failure occurs, the image forming apparatus can be used normally by performing a predetermined response, for example, replacing the failed head.

  In the present application, the “device that discharges liquid” means a device that includes a liquid discharge head or a liquid discharge unit and drives the liquid discharge head or the liquid discharge unit to discharge the liquid. The apparatus for ejecting liquid includes an apparatus capable of ejecting liquid to an object to which liquid can adhere (a liquid adhesion target), and an apparatus for ejecting liquid toward the air or liquid.

  This "device for discharging liquid" includes a liquid discharge head or a liquid discharge unit, a control means for controlling the liquid discharge operation, means for feeding, transporting and discharging a liquid adhesion target, other pre-processing devices, An apparatus called a post-processing apparatus can be included.

  In addition, the “device for ejecting liquid” includes a recording device, a printing device, an image forming device, a droplet ejecting device, a liquid ejecting device, a treatment liquid applying device, a three-dimensional modeling device, and a device that produces fine particles by a jet granulation method. , Printers, multifunction printers (MFPs), and 3D printers.

  Further, the “apparatus for ejecting liquid” is not limited to an apparatus in which significant images such as characters and figures are visualized by the ejected liquid. For example, what forms a pattern etc. which does not have a meaning in itself, and what forms a three-dimensional image are also included.

  The above-mentioned “thing to which liquid adheres” means that liquid can adhere even temporarily. The material of the “member to which the liquid adheres” may be any material such as paper, thread, fiber, fabric, leather, metal, plastic, glass, wood, ceramics, or the like that can be adhered even temporarily.

  “Liquid” also includes ink, treatment liquid, DNA sample, resist, pattern material, binder, modeling liquid, and the like.

  Further, the “device for ejecting liquid” includes both a serial type device that moves the liquid ejection head and a line type device that does not move the liquid ejection head, unless otherwise specified.

  The “liquid ejection unit” is an integrated unit of a liquid ejection head and other functional parts and mechanisms, and means an assembly of parts related to liquid ejection. For example, the “liquid discharge unit” includes a head tank, a carriage, a supply mechanism, a maintenance mechanism, and a main scanning movement mechanism arbitrarily combined with a liquid discharge head.

  Here, that the liquid discharge head and another functional component / mechanism are integrated is, for example, fixed by a fastening member, adhesion or heat caulking, or connected by a tube or the like (one is connected to the other). Including those that are slidably engaged). Further, the liquid ejection head and another functional component / mechanism are not limited to those directly fixed, connected, or engaged, but are fixed, connected, or engaged via an intermediate member. Also good.

  For example, the liquid discharge unit may include a unit in which the liquid discharge head and the head tank are integrated by fixing the liquid discharge head and the head tank with a fastening member or bonding. Moreover, the liquid discharge head and the head tank are connected to each other by a tube or the like, and the liquid discharge head and the head tank are integrated. Further, a unit in which a unit including a filter is added between the head tank and the liquid discharge head can be given to these liquid discharge units.

  Moreover, the liquid discharge head and the carriage are fixed by a fastening member or adhesion, and the liquid discharge head and the carriage are integrated. Moreover, the liquid discharge head and the carriage are fixed through an attaching member to be attached, and the liquid discharge head and the carriage are integrated.

  Further, the liquid discharge head and the scanning movement mechanism can be integrated by slidably engaging (or attached) with a guide member that constitutes a part of the scanning movement mechanism. Further, the liquid discharge head, the carriage, and the main scanning movement mechanism are integrated by slidably engaging (or attaching) the carriage, to which the liquid discharge head is mounted, with a guide member that constitutes a part of the scanning movement mechanism. Can be mentioned.

  Further, the liquid discharge head may be a unit in which the cap, which is a part of the maintenance mechanism, is fixed with a fastening member or the like, and the liquid discharge head and the maintenance mechanism are integrated. An example in which a cap, which is a part of a maintenance mechanism, is fixed to a carriage to which a liquid ejection head is attached by a fastening member or the like, and the liquid ejection head, the carriage, and the maintenance mechanism are integrated.

  Moreover, a tube for supplying a liquid from the outside to the inside of the liquid discharge head is connected to the liquid head, and the liquid discharge head and the supply mechanism are integrated. In addition, by attaching the flow path component connected to the tube to the liquid discharge head, a liquid discharge head and a supply mechanism can be integrated through the flow path component. Further, by attaching a head tank to which the tube is connected to the liquid discharge head, a liquid discharge head, a head tank, and a supply mechanism can be integrated.

  The main scanning movement mechanism is a mechanism for moving the liquid ejection head in the main scanning direction. For example, the main scanning movement mechanism is configured by combining a liquid ejection head or a guide member for guiding a carriage, a drive source, and a carriage movement mechanism. The guide member alone is also included in the main scanning movement mechanism.

  The supply mechanism is a mechanism for supplying liquid stored outside the liquid discharge head to the liquid discharge head. For example, the supply mechanism includes a loading unit and a tube for mounting the liquid cartridge. Further, a single tube and a single loading unit are included in the supply mechanism.

The maintenance mechanism is a mechanism for maintaining and recovering the performance of the liquid ejection head. For example, the maintenance mechanism is a combination of at least two of a cap, a wiper member, a suction means such as a suction pump leading to the cap, and an idle discharge receiver.
-Please supplement the function of the maintenance mechanism to explain what the maintenance mechanism maintains.

  Further, examples of the “liquid discharge unit” include a liquid discharge head, a carriage, a main scanning movement mechanism, a maintenance mechanism, and a supply mechanism that are integrated.

  The “liquid discharge head” is not limited to the pressure generating means to be used. For example, in addition to the piezoelectric actuator as described in the above embodiment (a multilayer piezoelectric element may be used), a thermal actuator using an electrothermal conversion element such as a heating resistor, a diaphragm and a counter electrode are included. An electrostatic actuator or the like may be used.

  In addition, the terms “image formation”, “recording”, “printing”, “printing”, “printing”, “modeling” and the like in the terms of the present application are all synonymous.

3 Carriage 12 Conveying Belt 13 Conveying Roller 20 Maintenance / Recovery Mechanism 21 Suction Cap 40 Liquid Discharge Unit 41 Liquid Discharge Head 100 Liquid Discharge Unit 500 Control Unit 515 Discharge Detection Unit

Claims (6)

A liquid discharge head having a plurality of nozzles for discharging liquid;
Discharge detection means for detecting the liquid discharge state of each nozzle of the liquid discharge head;
Means for controlling a recovery operation for recovering the state of the nozzle of the liquid discharge head,
The means for controlling is
It is determined whether or not a predetermined abnormal discharge for performing the recovery operation has occurred from the detection result of the discharge detection means,
When it is determined that the predetermined abnormal discharge has occurred, the occurrence history of the predetermined abnormal discharge is stored,
Until the occurrence history reaches a predetermined condition, perform the recovery operation,
If it is not determined that the predetermined abnormal discharge has occurred before the occurrence history reaches the predetermined condition, the stored occurrence history is discarded. apparatus. The apparatus for ejecting liquid according to claim 1, wherein the recovery operation is not performed after the occurrence history reaches a predetermined condition. 3. The liquid according to claim 1, wherein the predetermined abnormal discharge is determined to occur when the number of the nozzles in which the discharge failure is detected by the discharge detection unit is a predetermined number or more. Discharge device. 3. The liquid according to claim 1, wherein it is determined that the predetermined abnormal discharge has occurred when a predetermined number of pixels are continuously displayed on the image of the nozzle in which the discharge failure is detected by the discharge detection unit. A device that discharges. The apparatus for ejecting liquid according to claim 1, wherein the occurrence history of the predetermined abnormal discharge is the number of occurrences of the predetermined abnormal discharge. A liquid discharge head having a plurality of nozzles for discharging liquid;
And a discharge detection means for detecting a liquid discharge state of each nozzle of the liquid discharge head, causing a computer to perform a process of controlling a recovery operation for recovering the state of the nozzle of the liquid discharge head in a liquid discharge apparatus. A program for
A process of determining whether or not a predetermined abnormal discharge for performing the recovery operation has occurred from a detection result of the discharge detection means;
When it is determined that the predetermined abnormal discharge has occurred, a process of storing an occurrence history of the predetermined abnormal discharge;
Until the occurrence history reaches a predetermined condition, a process of performing the recovery operation;
When it is not determined that the predetermined abnormal discharge has occurred before the occurrence history becomes a predetermined condition, the processing for discarding the stored occurrence history is performed by a computer. program.

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