JP2011073331A - Ejection inspecting device and ejection inspecting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve accuracy in inspecting ejection in view of causing a fall in inspection accuracy because of giving no consideration to abnormality caused by unstable ejection. <P>SOLUTION: This ejection inspecting device includes a plurality of nozzles, a detecting electrode, a power source, a detecting part and a determining part. Liquid is ejected from the plurality of nozzles. The detecting electrode faces the nozzles with a predetermined space. The power source sets the detecting electrode to predetermined electric potential. The detecting part detects the potential change of the detecting electrode caused by the ejection of liquid from the nozzles. The determining part carries out first determination processing for determining whether the magnitude of the potential change of the detecting electrode is within a range specified by a first threshold and a second threshold, and second determination processing for determining whether the number of nozzles causing the potential change of the magnitude within the range is less than the predetermined number. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a discharge inspection apparatus and a discharge inspection method.

  A liquid ejection apparatus such as an ink jet printer has been proposed in which charged ink is ejected toward a detection electrode and a liquid ejection inspection is performed based on an electrical change generated in the electrode (for example, , See Patent Document 1).

JP 2007-152888 A

  In the above-described apparatus, when ink droplets are ejected from the detection target nozzle, the output voltage is detected by the voltage detection circuit, and the output voltage is less than the predetermined threshold as a result of comparing the output voltage with the predetermined threshold. Determined that an abnormality occurred in the nozzle due to a decrease in the level of the output voltage due to current leakage.

  On the other hand, the output voltage detected by the voltage detection circuit is abrupt due to a small amount of ink droplets flying from each nozzle (decrease in the amount of ink ejected from each nozzle) and disturbance of the meniscus. In some cases, a state where the pressure drops gradually occurs, that is, unstable discharge occurs.

  However, if the output voltage is less than the predetermined threshold as a result of comparing the output voltage with a predetermined threshold despite the output voltage level being lowered due to unstable ejection, it is determined that there is an abnormality due to current leakage. It was. That is, since the abnormality due to unstable ejection was not considered at all, the inspection accuracy was lowered.

  Therefore, the present invention has been made in view of such circumstances, and an object thereof is to improve the accuracy of the discharge inspection.

  A main invention for achieving the above object includes: a plurality of nozzles that discharge liquid; a detection electrode that faces the plurality of nozzles at a predetermined interval; a power source that sets the detection electrode to a predetermined potential; A detection unit that detects a change in potential of the detection electrode caused by the discharge of liquid from the nozzle, and whether or not an abnormality has occurred in each nozzle based on a change in potential of the detection electrode detected by the detection unit A determination unit configured to determine whether the potential change of the detection electrode caused by the discharge of the liquid from the nozzle is lower by a predetermined level than the first threshold value and the first threshold value. The first determination process for determining whether or not the current is within a range defined by the second threshold, and the number of nozzles that cause the potential change having a size within the range by discharging the liquid are a predetermined number. Less than Run of the second determination process for determining the abnormality is judged whether or not occurred, a discharge inspection device.

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

1 is a block diagram illustrating a printing system. FIG. 2A is a cross-sectional view of the head. FIG. 2B is a view of the nozzle plate as seen from the nozzle surface side. It is a figure explaining a cap mechanism. It is the figure which looked at the cap from the upper part. FIG. 5A is a diagram illustrating a retracted state of the cap mechanism. FIG. 5B is a diagram for explaining the state of the cap mechanism when performing a flushing operation or a missing dot detection operation. FIG. 5C is a diagram illustrating a state in which the cap is in close contact with the nozzle surface. FIG. 6A is a diagram for explaining a missing dot detection unit. FIG. 6B is a block diagram illustrating the detection control unit. FIG. 7A is a diagram illustrating an example of a drive signal used during nozzle inspection. FIG. 7B is a diagram illustrating a voltage signal output from the amplifier when ink is ejected by the drive signal of FIG. 7A. It is a figure explaining the relationship between a nozzle row, the block used as a test | inspection unit, and the voltage signal for every block. It is a figure explaining the discharge test | inspection by a different threshold value. FIG. 10A is a diagram illustrating a voltage signal on which noise is not superimposed. FIG. 10B is a diagram illustrating a voltage signal on which noise is superimposed. 3 is a flowchart illustrating an overall operation of the printer. It is a flowchart which shows the specific procedure of dot missing detection operation. It is a flowchart which shows the specific procedure of a discharge test | inspection. FIG. 14A is a diagram illustrating superposition of noise on a voltage signal. FIG. 14B is a diagram for explaining detection of abnormality based on the frequency of the voltage signal. FIG. 15A is a diagram illustrating a modification of the missing dot detection unit. FIG. 15B is a diagram illustrating another modification of the missing dot detection unit. FIG. 16 is a diagram illustrating the relationship between the detected voltage level and the nozzle number when an abnormality due to unstable ejection occurs.

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

That is, a plurality of nozzles that discharge liquid, a detection electrode that faces the plurality of nozzles with a predetermined interval, a power source that sets the detection electrode to a predetermined potential, and liquid discharge from the nozzle A detection unit that detects a change in potential of the detection electrode; and a determination unit that determines whether an abnormality has occurred in each nozzle based on the potential change of the detection electrode detected by the detection unit. The determination unit is a range in which the magnitude of the potential change of the detection electrode caused by the discharge of the liquid from the nozzle is defined by a first threshold value and a second threshold value that is lower than the first threshold value by a predetermined level. A first determination process for determining whether the number of nozzles is within the range, and a determination as to whether the number of nozzles that cause the potential change having a magnitude within the range is less than a predetermined number. Second determination processing to be performed and The running abnormality determines whether occurring, ejection inspecting apparatus will become apparent.
According to such a discharge inspection apparatus, a discharge inspection can be performed with high accuracy.

In the ejection inspection apparatus, the determination unit may determine whether the magnitude of the potential change of the detection electrode caused by the discharge of the liquid from the nozzle is larger than a first threshold value in the first determination process. If the result is negative, the number of nozzles that have caused the change in potential below the first threshold is counted, and whether it is greater than a second threshold that is a predetermined level lower than the first threshold. When the result is negative, the number is counted as nozzles that cause the potential change below the second threshold, and the potential change below the first threshold is counted in the second determination process. The number of remaining nozzles is calculated by subtracting the number of nozzles causing the potential change below the second threshold from the number of generated nozzles, and it is determined whether or not the number of remaining nozzles is equal to or greater than a predetermined number. When affirmed The determination that an abnormality due to the leakage current generated through the detection electrode is occurring, when negative, it may be judged to be abnormal by the unstable discharge occurs.
According to such a discharge inspection apparatus, it is possible to distinguish between abnormality due to current leakage or abnormality due to unstable discharge, and it is possible to improve the accuracy of discharge inspection.

Further, in the discharge inspection apparatus, the detection unit includes a detection capacitor in which one conductor is electrically connected to the detection electrode, and the determination unit is the other conductor of the detection capacitor. It is preferable to determine the presence or absence of leakage of current generated through the detection electrode based on the potential change.
According to such a discharge inspection apparatus, a potential change component can be easily extracted.

Further, in this ejection inspection apparatus, the detection unit includes an amplifier that amplifies a potential change of the other conductor of the detection capacitor, and the determination unit is based on the potential change amplified by the amplifier, It is preferable to determine the presence or absence of current leakage that has occurred through the detection electrode.
According to such a discharge inspection apparatus, it is possible to accurately detect abnormality of the detection electrode.

In the ejection inspection apparatus, it is preferable that the detection electrode is disposed on an absorbent material that absorbs the liquid.
According to such a discharge inspection apparatus, scattering of the discharged liquid can be suppressed.

It is also clarified that the following ejection inspection method can be realized.
That is, a plurality of nozzles that discharge liquid, a detection electrode that faces the plurality of nozzles with a predetermined interval, a power source that sets the detection electrode to a predetermined potential, and liquid discharge from the nozzle A detection unit that detects a potential change of the detection electrode; and a determination unit that determines whether an abnormality has occurred in each nozzle based on the potential change of the detection electrode detected by the detection unit. In the ejection inspection method in the apparatus, it is determined whether or not the magnitude of the potential change of the detection electrode caused by the ejection of the liquid from the nozzle is larger than a first threshold value. The number of nozzles that have caused the change in potential below the first threshold is counted to determine whether it is greater than a second threshold that is a predetermined level lower than the first threshold. The number of nozzles that cause the potential change below the threshold is counted, and the number of nozzles that cause the potential change below the first threshold to generate the potential change below the second threshold The number of remaining nozzles is calculated by subtracting the number, and it is determined whether or not the number of remaining nozzles is equal to or greater than a predetermined number. If the result is affirmative, an abnormality due to leakage of current generated through the detection electrode occurs. It is also clarified that it is possible to realize a discharge inspection method in which it is determined that an abnormality has occurred due to unstable discharge when the determination is negative.

=== First Embodiment ===
<Discharge inspection device>
The discharge inspection apparatus is used in a state of being incorporated in a liquid discharge apparatus. Moreover, when using in a process, it can also be comprised as an exclusive apparatus. In the embodiment described below, a discharge inspection apparatus incorporated in a liquid discharge apparatus will be described. Specifically, an ink jet printer 1 shown in FIG. 1 (hereinafter also simply referred to as printer 1) will be described as an example. In this case, the printer 1 corresponds to a kind of liquid ejection apparatus, and also corresponds to a kind of ejection inspection apparatus.

=== Overview of Printer 1 ===
FIG. 1 is a block diagram illustrating a printing system having a printer 1 and a computer CP. The printer 1 ejects ink, which is a kind of liquid, toward a medium such as paper, cloth, or film. The medium is an object to which liquid is ejected. The computer CP is communicably connected to the printer 1. In order to cause the printer 1 to print an image, the computer CP transmits print data corresponding to the image to the printer 1.

  The printer 1 includes a paper transport mechanism 11, a carriage moving mechanism 12, a drive signal generation circuit 13, a head unit 14, a dot dropout detection unit 15, a cap mechanism 16, a detector group 17, and a printer-side controller 18.

  The paper transport mechanism 11 transports the paper in the transport direction. The carriage moving mechanism 12 moves the carriage CR (see FIG. 3) to which the head unit 14 is attached in a predetermined movement direction (for example, the paper width direction).

  The drive signal generation circuit 13 generates a drive signal COM (see FIG. 7). This drive signal COM is applied to the head HD (piezo element PZT, see FIG. 2A) during printing on the paper. The drive signal COM is also applied to the head HD at the time of dot missing inspection for inspecting dot missing or at the time of flushing operation for recovering the ejection performance of the nozzle. The waveform of the drive signal COM is appropriately determined at each time of printing, dot missing inspection, and flushing operation. That is, the drive signal COM having a waveform suitable for each operation is generated. Here, the drive signal COM includes the ejection pulse PS. The ejection pulse PS is a waveform (potential change pattern) that causes the piezoelectric element PZT to perform a predetermined operation in order to eject droplet-like ink from the nozzle. Since the drive signal COM includes the ejection pulse PS, the drive signal generation circuit 13 corresponds to a pulse generation unit.

  The head unit 14 has a head HD and a head controller HC. The head HD discharges ink toward the paper. The head controller HC controls the head HD based on the head control signal from the printer-side controller 18. For example, the application of the drive signal COM to the head HD is controlled. The missing dot detection unit 15 detects whether ink is ejected from each nozzle Nz. The cap mechanism 16 performs a suction operation for sucking ink from each nozzle Nz in order to suppress the evaporation of the ink solvent from the nozzle Nz or to restore the discharge capability of the nozzle Nz. The detector group 17 includes a plurality of detectors that monitor the status of the printer 1. Detection results by these detectors are output to the printer-side controller 18. The printer-side controller 18 performs overall control in the printer 1.

=== Main Parts of Printer 1 ===
Next, the main part among the above-described parts will be described.

<About Head HD>
As shown in FIG. 2A, the head HD includes a case 21, a flow path unit 22, and a piezo element unit 23. The case 21 is a member for accommodating and fixing the piezo element unit 23. The case 21 is made of a nonconductive resin material such as an epoxy resin. A flow path unit 22 is joined to the front end surface of the case 21.

  The flow path unit 22 includes a flow path forming substrate 221, a nozzle plate 222, and a vibration plate 223. The nozzle plate 222 is bonded to one surface of the flow path forming substrate 221, and the diaphragm 223 is bonded to the other surface. The flow path forming substrate 221 has a pressure chamber 224, an ink supply path 225, and voids and grooves that become the common ink chamber 226. The flow path forming substrate 221 is made of, for example, a silicon substrate. The nozzle plate 222 is provided with a nozzle group including a plurality of nozzles Nz. The nozzle plate 222 is made of a conductive plate-like member, for example, a thin metal plate. The nozzle plate 222 is connected to a ground line and has a ground potential. This ground potential corresponds to the first potential or another predetermined potential lower than the predetermined potential. The ink ejected from each nozzle Nz becomes a ground potential.

  The nozzle group will be described. The nozzle group illustrated in FIG. 2B has a plurality of nozzle rows in which nozzles Nz are provided at a 1/180 inch pitch. Each nozzle row can determine the type of ink to be ejected. This head HD is provided with six nozzle rows. Specifically, in order from the left side of FIG. 2B, the black ink nozzle row Nk, the yellow ink nozzle row Ny, the cyan ink nozzle row Nc, the magenta ink nozzle row Nm, the light cyan ink nozzle row Nlc, and the light magenta ink nozzle row Nlm. It is. Each nozzle row ejects ink of the same color as the name assigned to the nozzle row. Each nozzle row is composed of the same number of nozzles Nz. In this head HD, one nozzle row is composed of 180 nozzles Nz.

  The diaphragm 223 has a double structure in which a resin elastic film 228 is laminated on a support plate 227 made of, for example, a stainless steel plate. A diaphragm portion 223 a is provided at a portion corresponding to each pressure chamber 224 in the diaphragm 223. The diaphragm portion 223a is deformed by the piezo element PZT included in the piezo element unit 23, and changes the volume of the pressure chamber 224. Note that the piezo element PZT and the nozzle plate 222 are electrically insulated by the presence of the elastic film 228, the adhesive layer, and the like.

  The piezo element unit 23 includes a piezo element group 231 and a fixed plate 232. The piezo element group 231 has a comb shape. Each of the comb teeth is a piezo element PZT. The tip surface of each piezo element PZT is bonded to an island portion 227a included in the corresponding diaphragm portion 223a. The fixing plate 232 supports the piezo element group 231 and serves as a mounting portion for the case 21.

  The piezo element PZT is a kind of electromechanical conversion element, and corresponds to an element that operates to give a pressure change to the liquid in the pressure chamber 224. The illustrated piezo element PZT expands and contracts in the longitudinal direction of the element in accordance with the potential change pattern of the applied drive signal COM. When the piezo element PZT contracts, the diaphragm portion 223a is pulled and the pressure chamber 224 is expanded. On the contrary, when the piezo element PZT is extended, the diaphragm portion 223a is pushed and the pressure chamber 224 contracts. The ink in the pressure chamber 224 undergoes a pressure change due to a change in the volume of the pressure chamber 224. By utilizing this pressure change, it is possible to eject droplet-like ink (hereinafter also referred to as ink droplets) from the nozzle Nz. For example, when the pressure chamber 224 is once expanded and then rapidly contracted, the ink in the pressure chamber 224 is pressurized and ink droplets can be ejected from the nozzle Nz.

<About the cap mechanism 16>
As shown in FIGS. 3 and 4, the cap mechanism 16 includes a cap 31 that forms a space where the nozzle group faces, and a slider member 32 that supports the cap 31 and is movable obliquely up and down.

  The cap 31 has a rectangular bottom portion (not shown) and a side wall portion 311 that stands up from the periphery of the bottom portion, and has a thin box shape with an open upper surface facing the nozzle plate 222. The nozzle group faces the space surrounded by the bottom and the side wall 311 when capping.

  In this space, a sheet-like moisturizing member 312 made of a porous material such as felt or sponge is arranged. Since ink lands on the moisturizing member 312, scattering can be suppressed, and the ink solvent evaporated from the moisturizing member 312 during the capping stays in the space. Thereby, evaporation of the ink solvent from the nozzle Nz can be suppressed. Further, a detection electrode 313 is disposed on the surface of the moisturizing member 312. This detection electrode 313 is used in a dot drop detection operation described later, and has a high potential of about 600 V to 1 kV during this operation. This high potential corresponds to a second potential or a predetermined potential. The illustrated detection electrode 313 includes a frame portion 313a provided in a double rectangular shape, a diagonal portion 313b that connects the diagonal portions of the frame portion 313a, and a cross portion that connects the midpoints on each side of the frame portion 313a. 313c. With this structure, it is uniformly charged over a wide range. In this embodiment, the ink solvent is water, which is a kind of conductive liquid. For this reason, when the detection electrode 313 is set to a high potential while the moisturizing member 312 is moist, the surface of the moisturizing member 312 has the same potential. Even in this respect, the battery is uniformly charged over a wide range.

  A waste liquid tube 314 is connected to the space of the cap 31. A suction pump (not shown) is connected to the middle of the waste liquid tube 314. As this suction pump, for example, a tube pump that pushes fluid (air, liquid, etc.) in the tube downstream by sandwiching the tube with a roller is used. The operation of this suction pump is controlled by the printer-side controller 18. When the suction pump is operated, the space of the cap 31 becomes negative pressure. Thereby, ink and air can be sucked from the cap 31 side. The sucked ink is stored in a waste liquid storage unit (not shown).

  The slider member 32 is positioned on the platen PL side by being pulled by a spring (not shown) in a state where the carriage CR is out of the home position (retracted state shown in FIGS. 3 and 5A). In this retracted state, the cap 31 is positioned at a position sufficiently lower than the surface of the nozzle plate 222 (hereinafter also referred to as the nozzle surface). When the carriage CR moves to the home position side, the slider member 32 moves against the pulling force of the spring. This is because the carriage CR contacts the contact portion 321 provided on the slider member 32 and moves the contact portion 321 to the home position side. As the slider member 32 moves, the portion on the support shaft 322 side rises along the guide slot 323. Further, the portion on the cap 31 side is lifted by the rotation of the arm portion 324.

  As the carriage CR moves toward the home position, the cap 31 moves toward the nozzle surface while maintaining a state of facing the nozzle surface. That is, it moves obliquely upward. As shown in FIG. 5B, when the carriage CR reaches a position slightly before the home position, the opening edge of the cap 31 (the upper end of the side wall portion 311) does not touch the nozzle surface but moves to the immediate vicinity of the nozzle surface. To do. Further, as shown in FIG. 5C, when the carriage CR reaches the home position, the opening edge of the cap 31 comes into contact with the nozzle surface. At this time, the nozzles Nz constituting the nozzle group face the space of the cap 31.

  The cap mechanism 16 changes its position according to the operation and state of the printer 1. For example, during a normal printing operation, the cap 31 is in a retracted state as shown in FIG. 5A. When the power is turned off or during a long pause, as shown in FIG. 5C, the upper end of the cap 31 is brought into close contact with the nozzle surface to suppress evaporation of the ink solvent from the nozzle Nz. In order to recover the discharge capability of the nozzles Nz, the upper end of the cap 31 is brought into close contact with the nozzle surface even when a suction operation for sucking ink from each nozzle Nz (corresponding to a suction recovery operation) is performed. Increase sex. That is, when the suction pump is operated in this close contact state, the space of the cap 31 can be negative. This negative pressure acts on the nozzle Nz. For this reason, the ink in the head HD can be sucked into the space of the cap 31 through the nozzle Nz. Further, in order to recover the discharge capability of the nozzle Nz, when performing a flushing operation (corresponding to the discharge recovery operation) in which ink droplets are continuously discharged from each nozzle Nz, as shown in FIG. A slight gap is left between 31 and 31.

  Regarding the recovery operation for recovering the discharge capability of the nozzle Nz, there is a fine vibration operation in addition to the above-described suction operation and flushing operation. The micro-vibration operation moves the meniscus (the free surface of the ink exposed at the nozzle Nz) to the ejection side and the drawing side by applying a pressure change that does not eject ink droplets to the ink in the pressure chamber 224. In this operation, the thickened ink in the vicinity of the nozzle is dispersed by stirring. Regarding these suction operation, flushing operation, and fine vibration operation, the degree of recovery of the discharge capability of the nozzle Nz is the highest in the suction operation and the lowest in the fine vibration operation. Further, the amount of ink consumed in each operation is the largest in the suction operation and the smallest in the fine vibration operation. Since each recovery operation has such a characteristic difference, the printer 1 uses each recovery operation properly according to the state difference.

<About the missing dot detection unit 15>
The missing dot detection unit 15 specifies the nozzle Nz that causes missing dots by inspecting whether or not ink is ejected from each nozzle Nz constituting the nozzle group. As shown in FIG. 6A, the missing dot detection unit 15 includes a high voltage power supply unit 41, a limiting resistor 42, a detection resistor 43, a detection capacitor 44, an amplifier 45, a smoothing capacitor 46, and a detection control unit 47. Among these, each part excluding the high-voltage power supply unit 41 corresponds to a kind of inspection part for inspecting liquid ejection.

  The high-voltage power supply unit 41 is a type of power supply that brings the detection electrode 313 to a predetermined potential. The high-voltage power supply unit 41 of this embodiment is configured by a DC power supply of about 600 V to 1 kV, and the operation is controlled by a control signal from the detection control unit 47. The limiting resistor 42 and the detection resistor 43 are disposed between the output terminal of the high-voltage power supply unit 41 and the detection electrode 313. In the present embodiment, the limiting resistor 42 and the detection resistor 43 have the same resistance value and are connected in series. Specifically, the resistance value of the limiting resistor 42 is 1.6 MΩ, one end thereof is connected to the output terminal of the high-voltage power supply unit 41, and the other end is connected to one end of the detection resistor 43. The resistance value of the detection resistor 43 is also 1.6 MΩ, and the other end is connected to the detection electrode 313.

  The detection capacitor 44 is an element for extracting a potential change component of the detection electrode 313, and one conductor is connected to the detection electrode 313 and the other conductor is connected to the amplifier 45. By interposing the detection capacitor 44, the bias component (DC component) of the detection electrode 313 can be removed, and the handling of the signal can be facilitated. The detection capacitor 44 in this embodiment has a capacity of 4700 pF. The amplifier 45 amplifies and outputs a signal (potential change) appearing at the other end of the detection capacitor 44. The amplifier 45 of this embodiment is configured with a gain of 4000 times. As a result, the potential change component can be acquired as a voltage signal having a change width of about 2 to 3V. The set of the detection capacitor 44 and the amplifier 45 corresponds to a kind of detection unit, and detects a potential change of the detection electrode 313 caused by ejection of the ink droplet. The smoothing capacitor 46 suppresses a rapid change in potential. The smoothing capacitor 46 of this embodiment has one end connected to a signal line connecting the limiting resistor 42 and the detection resistor 43 and the other end connected to the ground. And the capacity | capacitance is 0.1 micro F.

  The detection control unit 47 is a part that controls the missing dot detection unit 15. As shown in FIG. 6B, the detection control unit 47 includes a register group 47a, an AD conversion unit 47b, a voltage comparison unit 47c, and a control signal output unit 47d. The register group 47a includes a plurality of registers. Each register stores a determination result for each nozzle Nz, a voltage threshold for determination, and the like. The AD converter 47b converts the amplified voltage signal (analog value) output from the amplifier 45 into a digital value. The voltage comparison unit 47c compares the magnitude of the amplitude value based on the amplified voltage signal with a voltage threshold value. The control signal output unit 47d outputs a control signal for controlling the operation of the high-voltage power supply unit 41. The operation of the missing dot detection unit 15 will be described later.

<Regarding the printer-side controller 18>
The printer-side controller 18 performs overall control in the printer 1. That is, the control target unit is controlled based on the print data received from the computer CP and the detection result from each detector, and an image is printed on the paper. Further, the printer-side controller 18 performs a dot missing detection operation in association with an initial operation associated with power-on or in association with execution of a printing operation.

As shown in FIG. 1, the printer-side controller 18 includes an interface unit 18a, a CPU 18b, and a memory 18c. The interface unit 18a exchanges data with the computer CP. The CPU 18 b performs overall control of the printer 1. The memory 18c secures an area for storing a computer program, a work area, and the like. The CPU 18b controls each control target unit according to the computer program stored in the memory 18c. For example, the CPU 18b controls a suction pump included in the paper transport mechanism 11, the carriage moving mechanism 12, and the cap mechanism 16. In addition, a head control signal for controlling the operation of the head HD is transmitted to the head controller HC, and a control signal for generating the drive signal COM is transmitted to the drive signal generation circuit 13. Further, it communicates with the detection control unit 47 of the missing dot detection unit 15 to transmit / receive necessary information.

=== Dot missing detection operation ===
Next, the missing dot detection operation by the missing dot detection unit 15 and the like will be described.

<About missing dot detection>
As described above, in this printer 1, the nozzle plate 222 is connected to the ground to make the ground potential (first potential, other predetermined potential), and the detection electrode 313 disposed on the cap 31 is as high as about 600 V to 1 kV. The potential (second potential, predetermined potential) is set. The nozzle plate 222 and the detection electrode 313 are arranged with a predetermined interval d (see FIG. 6A), and ink droplets are ejected from the detection target nozzle Nz. Then, an electrical change caused on the detection electrode 313 side due to the ejection of the ink droplet is detected. That is, a periodic change in potential generated in the detection electrode 313 is acquired via the detection capacitor 44 and the amplifier 45. If the maximum amplitude Vmax, which is the difference between the highest voltage VH and the lowest voltage VL shown in FIG. 7B, is greater than a predetermined threshold (see first threshold TH1, described later, etc.), ink is ejected. Judge.

  The principle of detection will be described. A capacitor is formed by arranging the nozzle plate 222 and the detection electrode 313 at a predetermined interval d. As shown in FIG. 6A, by contacting the nozzle plate 222 connected to the ground, the ink extending in a columnar shape from the nozzle Nz also becomes the ground potential. The presence of such ink is in agreement with locally reducing the electrode spacing of the capacitor and increases the capacitance. As the capacitance increases, the amount of charge that can be stored between the nozzle plate 222 and the detection electrode 313 increases. When the electrostatic capacity increases or the decreased electrostatic capacity returns in this way, the charge moves from the high-voltage power supply unit 41 to the detection electrode 313 side through the limiting resistor 42 and the like. That is, a current flows toward the detection electrode 313. When such a current (also referred to as a discharge inspection current If for convenience) flows, the potential of the detection electrode 313 is changed by the detection resistor 43. The change in the potential of the detection electrode 313 also appears as a change in the potential of the other conductor (conductor on the amplifier 45 side) in the detection capacitor 44. Therefore, it is possible to determine whether or not an ink droplet has been ejected by monitoring the potential change of the other conductor.

  FIG. 7A is a diagram illustrating an example of the drive signal COM used when inspecting the nozzle Nz. FIG. 7B is a diagram illustrating the voltage signal SG output from the amplifier 45 when ink is ejected with the drive signal COM in FIG. 7A. In this inspection, a drive signal COM having a plurality of ejection pulses PS is used. That is, the drive signal generation circuit 13 repeatedly generates the drive signal COM shown in FIG. This repetition period T is determined as the time required for inspection of one nozzle Nz. The repetition period T of this embodiment is set to a period corresponding to 1 kHz. The drive signal COM illustrated has a first half part generated in the first half period TA and a second half part generated in the second half period TB. In the first half, a plurality of ejection pulses PS are generated at predetermined intervals. In this example, 20 to 30 ejection pulses PS are generated at intervals equivalent to 50 kHz. In the latter half portion, a constant potential portion that is constant at an intermediate potential is generated.

  When such a drive signal COM is applied to the piezo element PZT, ink droplets are continuously ejected from the nozzle Nz corresponding to the piezo element PZT 20 to 30 times at a cycle of 50 kHz. As a result, the amplifier 45 outputs a voltage signal SG whose voltage level changes periodically. The detection controller 47 makes a determination based on the voltage signal SG. If the maximum amplitude Vmax (difference between the maximum voltage VH and the minimum voltage VL) is larger than the first threshold value TH1, ink is ejected from the detection target nozzle Nz. It is determined that Here, since ink droplets are continuously ejected at a high frequency of 50 kHz for detection, the potential change obtained can be increased, and the accuracy of detection and determination can be increased. In the printer 1, 3V is set as the first threshold value TH1. For this reason, when the amplitude of the voltage signal SG is larger than 3V, the detection control unit 47 functioning as a determination unit determines that there is no missing dot due to the nozzle Nz, and stores the result in a predetermined register.

  As described with reference to FIG. 2B, the head HD used in the printer 1 is provided with six nozzle rows Nk to Nlm. Each nozzle row Nk to Nlm is composed of 180 nozzles Nz. For this reason, 1080 (180 × 6 columns) nozzles Nz are to be inspected in one dot missing detection operation. As shown in FIG. 8, in this printer 1, 15 nozzles Nz (corresponding to a predetermined number of nozzles) constitute one block, and inspection is performed in block units. That is, one nozzle row is divided into 12 blocks. A dummy inspection period during which ink droplets are not ejected is provided between the inspection period of a certain block and the inspection period of the next block (also referred to as a non-ejection dummy period for convenience). This non-ejection dummy period is provided as a period for confirming whether noise is acting on the detection electrode 313. Here, when it is determined that noise is acting on the detection electrode 313, the block is inspected again. As a result, it is possible to suppress the influence of short-period noise generated by mechanical shock or the like.

  When the inspection has been completed for all the nozzles, the detection control unit 47 selects an operation based on the inspection result. That is, when ink is normally ejected from all the nozzles Nz, it is determined that there are no nozzles Nz that cause missing dots, and the inspection is terminated. In this case, the detection control unit 47 transmits information to the printer-side controller 18 that there is no nozzle Nz that causes missing dots. A printing operation is performed based on this information. Further, the detection control unit 47 determines that there is a nozzle Nz that causes missing dots when non-ejection of ink droplets is detected for some of the nozzles Nz. In this case, the detection control unit 47 transmits information indicating that there is a nozzle Nz that causes missing dots to the printer-side controller 18. Based on this information, a recovery operation for recovering the discharge capability of the nozzle Nz is performed after the end of the dot missing detection operation. The missing dot detection operation will be described later in detail.

<Detection of abnormality in detection electrode 313>
In the dot missing detection unit 15 described above, the detection electrode 313 is charged to a high potential of 600 V to 1 kV. The detection electrode 313 is disposed in a box-shaped cap 31 having an open upper surface, and an abnormality such as a short circuit may occur when a conductive foreign object comes into contact. In addition, a wiper 33 for wiping the nozzle surface is provided near the cap 31 (see FIGS. 3 and 5B). An abnormality may also occur through the ink attached to the wiper 33. If an abnormality occurs in the detection electrode 313, there is a possibility that ink ejection cannot be detected normally.

  In order to detect an abnormality in the detection electrode 313, a voltage dividing circuit is generally provided in a power supply line for charging the detection electrode 313. That is, the power supply voltage is divided by a voltage dividing circuit, and a detection voltage having a voltage level suitable for detection is acquired. The abnormality of the detection electrode 313 is detected by digitally converting the voltage value of the detection voltage.

  However, when detection is performed using a voltage dividing circuit, there is a problem in that charge as a signal source to be used for dot dropout detection leaks through the voltage dividing circuit and detection sensitivity is lowered. In addition, there is a cause of noise (noise) in the resistance element itself, and there is a problem that current noise and thermal noise increase by providing many resistance elements. It is difficult to completely remove such noise in a circuit that handles a high voltage signal.

  In view of such circumstances, the missing dot detection unit 15 does not monitor the voltage level using the voltage dividing circuit, and based on the change in the electrical state caused by the discharge inspection current If, the detection electrode 313. An abnormality is detected. That is, the potential change of the other conductor of the detection capacitor 44 is amplified by the amplifier 45, and based on the magnitude of the amplitude in the obtained voltage signal SG, it is determined whether the detection electrode 313 is normal or not. To do. Specifically, it is determined whether or not the detection electrode 313 is at a predetermined high potential (600 V to 1 kV) that is a kind of the second potential. Hereinafter, this point will be described.

  As shown in FIGS. 7B and 8, in the printer 1, when the maximum amplitude Vmax in the obtained voltage signal SG is 3 V or more for all the nozzles Nz, it is determined that the block has no missing dots. Here, when an abnormality such as a short circuit occurs in the detection electrode 313, depending on the form of the short circuit, the detection electrode 313 and the ground are equivalent to a state connected by a resistor. At the time of this abnormality, the maximum amplitude Vmax becomes small for all the nozzles Nz.

  The dot missing detection unit 15 pays attention to the fact that the maximum amplitude Vmax becomes small for all the nozzles Nz at the time of abnormality, and defines a second threshold value TH2 that is lower than the first threshold value TH1 by a predetermined voltage level. That is, as shown in FIG. 9, in the printer 1, when the maximum amplitude Vmax for all the nozzles Nz is equal to or less than the first threshold value TH1, the threshold value is changed to the second threshold value TH2 and the inspection is performed again. Then, in the inspection period excluding the non-ejection dummy period, the detection control unit 47 determines that the maximum amplitude Vmax for all the nozzles Nz is equal to or smaller than the first threshold value TH1 and is larger than the second threshold value TH2, in other words, an amplifier. When the magnitude of the potential change amplified by 45 is within the range defined by the first threshold value TH1 and the second threshold value TH2, it is determined that current leakage has occurred due to a short circuit or the like. This determination result is output to the printer-side controller 18. The printer-side controller 18 performs processing such as stopping the operation of the printer 1 in response to the determination result.

  The second threshold value TH2 in the printer 1 is set lower than the first threshold value TH1 by a predetermined level. Specifically, it is set to 2.5V, which is 0.5V lower than the first threshold value TH1. Here, the second threshold value TH2 is set to a value higher than the noise that normally occurs in the non-ejection dummy period (the potential change amplified by the amplifier 45, which corresponds to the potential change that usually occurs in the non-ejection period of ink). It is done. As described above, the resistance element has a noise factor. Since this noise is amplified by the amplifier 45, it becomes a certain level. As in this embodiment, by setting the second threshold value TH2 higher than the noise that normally occurs in the non-ejection dummy period, it is difficult to be affected by the noise. Thereby, the detection accuracy of an electrical change caused by ink ejection can be increased.

<Abnormality detection considering unstable discharge>
Unstable ejection occurs, for example, when the ink ejection amount at each nozzle Nz is reduced. The dot missing detection unit 15 can perform discharge detection as follows by paying attention to the fact that the maximum amplitude Vmax temporarily becomes extremely small for some of the nozzles Nz at the time of abnormality due to unstable discharge.

  FIG. 16 is a diagram illustrating the relationship between the detected voltage level and the nozzle number when an abnormality due to unstable ejection occurs. As shown in FIG. 2, one nozzle row is composed of 180 nozzles. For this reason, in each of the states A to I in FIG. 16, the change in the detected voltage level is shown to linearly decrease from nozzle # 1 toward nozzle # 180. This is merely a simple representation that the voltage levels of all the nozzles included in one nozzle row are not the same level, and that there is a variation in the voltage level of each nozzle. Therefore, the voltage change between the nozzles is not limited to such a linear change, and can be illustrated in a state where the values are irregularly distributed.

  FIG. 16 shows that when the detection voltage (the amplitude of the signal from the amplifier 45) is larger than 3 V (first threshold value TH1), the nozzle having this detection voltage is included in the ejection region. . The nozzles included in the ejection area have no missing dots and eject ink droplets normally.

  On the other hand, when the detected voltage is smaller than 2.5 V (second threshold TH2), the nozzle having this detected voltage is included in the non-ejection region. That is, since there is a nozzle Nz that does not eject ink droplets, it is determined that there is a missing dot.

  Next, A in FIG. 16 indicates that the detection voltage is 3 V or more for all the nozzles # 1 to # 180. That is, the detection control unit 47 determines that there is no missing dot and ink droplets are normally ejected because the maximum amplitude Vmax is 3 V or more for all the nozzles Nz.

  B indicates that the detected voltage exceeds 3 V except for one nozzle among all nozzles # 1 to # 180.

  This is because the detection voltage level for almost all the nozzles is greater than 3V, but an abnormality due to unstable ejection has occurred in only one nozzle, so the detection voltage level suddenly drops, and the reduced voltage level is 3V ( The state is included in a range defined by the first threshold value TH1) and 2.5V (second threshold value TH2).

  In this state, since the number of nozzles included in such a range is 1 (X = 1, Y = 0), the detection control unit 47 has an XY value of 1 and is smaller than a predetermined number (for example, 3). Therefore, it is determined that unstable ejection has occurred.

  Here, the variable X is the number of nozzles having a detection voltage level lower than 3V, and the variable Y is the number of nozzles having a detection voltage level lower than 2.5V. Therefore, XY is the number of nozzles having a value included in a range in which the detection voltage level is defined by 3V (first threshold value TH1) and 2.5V (second threshold value TH2). The predetermined value is a preset value and corresponds to the third threshold value. A specific dot drop detection operation will be described later with reference to FIG.

  C indicates that the detection voltage is 3 V or more except for one nozzle (# 180) among all nozzles # 1 to # 180.

  This is an initial stage in which an abnormality due to a current leak has started to occur, and the detection voltage level of each nozzle has decreased as a whole. The voltage level for one nozzle (# 180) is included in a range defined by 3V (first threshold value TH1) and 2.5V (second threshold value TH2).

  In this state, since the number of nozzles included in such a range is 1 (X = 1, Y = 0), the detection control unit 47 has an XY value of 1 and is smaller than a predetermined number (for example, 3). Therefore, it is determined that unstable ejection has occurred.

  D indicates that the detection voltage is 3 V or more except for several nozzles (for example, three nozzles) out of all nozzles # 1 to # 180.

  This is an abnormal state in which current leakage has further progressed, and as a result of the overall decrease in the detection voltage level of each nozzle, the voltage levels for several nozzles are 3V (first threshold TH1) and 2.5V (second The state is included in the range defined by the threshold value TH2).

  In this state, since the number of nozzles included in this range is 3 (X = 3, Y = 0), the detection control unit 47 has an XY value of 3, which is greater than or equal to a predetermined number (eg, 3). Therefore, the detection control unit 47 determines that current leakage has occurred.

  E is a stage in which current leakage further progresses from the state of D, and as a result of the overall decrease in the detection voltage level of each nozzle, the voltage level for several nozzles (for example, five nozzles) is 3 V (first threshold value). This state is included in a range defined by TH1) and 2.5V (second threshold TH2). In addition, only one nozzle is in an abnormal state due to unstable ejection, and the voltage level is rapidly reduced. The reduced voltage level is included in a non-ejection region lower than 2.5V.

  In this state, the detection control unit 47 has 5 (X = 5) nozzles included in the range defined by 3V and 2.5V, and the number of nozzles at a level smaller than 2.5V is 1 ( Since Y = 1), the value of XY is 4, which is greater than or equal to a predetermined number (for example, 3), so it is determined that current leakage has occurred.

  F is a state in which the voltage levels for all the nozzles are included in a range defined by 3V (first threshold value TH1) and 2.5V (second threshold value TH2). In this state, since the number of nozzles included in the range defined by 3V and 2.5V is 180 (X = 180, Y = 0), the detection control unit 47 has an XY value of 180. Therefore, since it is equal to or greater than a predetermined number (for example, 3), it is determined that current leakage has occurred.

  G is a state in which current leakage has further progressed from the state of F, and an abnormality due to unstable ejection has occurred in only one nozzle. The detection voltage level for almost the entire nozzle is included in the range defined by 3V and 2.5V, but for one nozzle, the voltage level suddenly drops due to unstable ejection, and the reduced voltage level is , Included in a non-ejection region lower than 2.5V.

  In this state, the detection control unit 47 has 179 nozzles (X = 179) included in the range defined by 3V and 2.5V, and the number of nozzles at a level smaller than 2.5V is 1 ( Since Y = 1), the value of XY is 178, which is greater than or equal to a predetermined number (for example, 3), so it is determined that a current leak has occurred.

  H is a state in which current leakage has further progressed from the G state, and the detection voltage level for almost the entire nozzle is included in the range defined by 3 V and 2.5 V, but detection for three nozzles. The voltage is included in a non-ejection area lower than 2.5V.

  In this case, the number of nozzles included in the range defined by 3V and 2.5V is 177 (X = 177), and the number of nozzles at a level smaller than 2.5V is 3 (Y = 3), the value of XY is 174, which is greater than or equal to a predetermined number (for example, 3), so it is determined that current leakage has occurred.

  I shows a state in which the detection voltage level of all the nozzles Nz is included in a non-ejection region lower than 2.5V. Since the detection control unit 47 is smaller than the maximum amplitude Vmax 2.5 V for all the nozzles Nz, it determines that there is a missing dot, that is, no ink droplets are ejected.

  As described above, when the maximum amplitude Vmax for the nozzle Nz is equal to or smaller than the first threshold value TH1 and larger than the second threshold value TH2, in other words, the magnitude of the potential change amplified by the amplifier 45 is large. Even in the range defined by the first threshold value TH1 and the second threshold value TH2, it is possible to determine whether current leakage or unstable ejection has occurred, thereby improving inspection accuracy. Can be made.

<Non-ejection dummy period>
Next, the non-ejection dummy period will be described. This non-ejection dummy period is a period for confirming whether noise is acting on the detection electrode 313. As shown in FIG. 8, in the printer 1, a non-ejection dummy period is provided between the inspection period of a certain block and the inspection period of another block. This non-ejection dummy period is set to a length comparable to the period required for the inspection of one nozzle Nz. If determined in this way, it is possible to process the discharge inspection and the presence / absence of noise for each nozzle Nz at regular intervals, and the processing for period management can be reduced. In the printer 1, 15 nozzles Nz belong to one block. For this reason, the non-ejection dummy period appears every 15 periods (the 16th period, the 32nd period,...). Thus, since the number of nozzles Nz belonging to one block is made constant and the non-ejection dummy period appears periodically, it can be easily recognized whether it is the non-ejection dummy period in terms of control.

  The detection control unit 47 determines that noise is acting on the detection electrode 313 when the maximum amplitude in the non-ejection dummy period exceeds a specified level. For example, when the maximum amplitude exceeds the first threshold value TH1, it is determined that noise is acting on the detection electrode 313. If it is determined that noise is acting, the detection control unit 47 performs dot missing detection again for a block that is considered to be affected by noise. For example, suppose that the signal shown in FIG. 10B is obtained because the noise acts during the period when the signal of FIG. 10A is obtained if no noise acts. In this case, the missing dot detection is performed again for the block corresponding to the non-ejection dummy period in which noise is detected. For example, when noise exceeding the first threshold value TH1 is detected in the non-ejection dummy period, the missing dot detection is performed again for the block.

  By the way, the noise detection accuracy can be increased by increasing the number of the non-ejection dummy periods. On the other hand, if the number is too large, it takes time to detect missing dots. In the printer 1, the number of nozzles Nz belonging to one block is determined in consideration of the detection accuracy and the time required for the detection operation, and a non-ejection dummy period is provided between the blocks. That is, the number of nozzles Nz belonging to one block is set to 15, and a non-ejection dummy period is provided between the blocks. As a result, the problem that the inspection period becomes excessively long is suppressed while obtaining the necessary detection accuracy.

<About hardware abnormality detection>
In this printer 1, the detection electrode 313 is set to a high potential (second potential, predetermined potential) of about 600 V to 1 kV, but a hardware abnormality typified by disconnection may occur. If such an abnormality can be detected along with the missing dot detection operation, it is convenient from the viewpoint of suppressing erroneous detection, from the viewpoint of protecting hardware, and from the viewpoint of improving processing efficiency.

  In view of such circumstances, in the printer 1, in the dot missing detection operation, when the maximum amplitude Vmax of the voltage signal SG from the amplifier 45 is less than a specified level (for example, less than the second threshold value) for all the nozzles Nz. The recovery operation of the nozzle Nz is performed. After this recovery operation, the missing dot detection operation is performed again, and if the amplitude of the signal from the amplifier 45 is still less than the specified level for all the nozzles Nz, it is determined that an abnormality has occurred in the hardware. In other words, if it is determined that all nozzles Nz cannot eject ink before performing the recovery operation, and it is determined that all nozzles Nz cannot eject ink even after performing the recovery operation, the hardware It is determined that an abnormality has occurred. This determination is based on an event in which at least one of the nozzles Nz constituting the nozzle group is recovered by performing the recovery operation.

  By adopting such a configuration, it is possible to detect hardware abnormality using the configuration used for dot dropout detection, so that the configuration of the apparatus can be simplified. In addition, since a hardware abnormality can be detected in connection with the operation of detecting missing dots, processing efficiency can be improved. A specific procedure for detecting the abnormality will be described later.

=== Operation of Printer 1 ===
<Overall operation>
Next, the operation of the printer 1 having the above-described configuration will be described. FIG. 11 is a flowchart showing the overall operation of the printer 1. This operation is performed under the control of the printer-side controller 18. For this reason, the computer program stored in the memory 18c has a code for realizing this operation.

  Upon receiving the print command (S11), a missing dot detection operation is performed (S12). The specific procedure of the dot missing detection operation will be described later, but the content of the operation is as described above. Briefly, an operation for ejecting ink droplets is performed for each nozzle Nz and an operation for detecting ejected ink droplets is performed. When the missing dot detection operation is performed, a determination is made based on the result (S13). That is, the printer-side controller 18 determines that there is no missing dot when ink droplets are normally ejected from all the nozzles Nz constituting the nozzle group. On the other hand, if there is a nozzle Nz that has not ejected ink droplets, it is determined that there is a missing dot. If it is determined that there is no missing dot, a printing operation is performed (S14). On the other hand, when it is determined that there is a missing dot, the missing dot recovery operation is performed on the condition that the number of repetitions of the missing dot detection operation is less than the predetermined number (N in S15) (S16). This dot missing recovery operation is, for example, a suction operation or a flushing operation. In this manner, when dot missing is detected, the recovery operation is performed in conjunction. Thereby, dot omission can be suppressed effectively. When the missing dot recovery operation ends, the missing dot detection operation is performed again (S12).

  On the other hand, if the number of repetitions of the missing dot detection operation has reached the predetermined number (Y in S15), it is determined whether or not there is a current leak (S17). Here, the case where the number of repetitions reaches the predetermined number means a case where dot missing is not eliminated even after the dot missing recovery operation (S16) is performed a predetermined number of times (Y in S13). For this reason, if it is determined that the current leak through the detection electrode 313 has not been eliminated (Y in S17), it is considered that there is a current leak that is difficult to eliminate by the recovery operation or the like. Therefore, a series of processing is terminated as abnormal termination due to current leakage. On the other hand, if there is no current leakage (N in S17), the user is allowed to select a subsequent operation (S18). That is, the user is allowed to select whether to perform printing regardless of whether the missing dot has not been eliminated or to forcibly terminate without printing. In this case, the printer-side controller 18 displays a message on a display (not shown). Then, the user operates an operation unit (not shown) to select a subsequent process. This selection result is output to the printer-side controller 18. If the user selects forced termination, the printer-side controller 18 terminates the series of processes as abnormal termination due to the user's selection. If the user selects printing, a printing operation is executed (S14).

  When one unit of printing operation, for example, printing operation on one sheet of paper or a series of printing operations corresponding to one job is completed, the printer-side controller 18 confirms whether there is data to be continuously printed (S19). If there is data to be continuously printed, the presence / absence of a function abnormality flag is confirmed (S20). This function abnormality flag is a flag that is set when the inspection cannot be normally performed due to the influence of noise or the like in the dot missing detection operation performed previously. The setting of the function abnormality flag will be described in the discharge inspection described later. If the function abnormality flag is set (Y in S20), the dot missing detection operation is performed before the printing operation (S14) (S12). As a result, the dot missing detection operation that has been ended halfway in the previous time can be performed again at an appropriate timing, and the detection reliability can be improved. If the function abnormality flag is not set (N in S20), the printer-side controller 18 determines whether or not a predetermined time has elapsed since the previous dot dropout inspection operation was performed (S21). If the predetermined time has elapsed (Y in S21), the missing dot detection operation is performed again (S12). On the other hand, if the predetermined time has not yet elapsed (N in S21), a printing operation is performed (S14). With such a configuration, it is possible to suppress a problem that the missing dot detection operation is not performed over a long period of time. For example, when one unit of printing operation is an operation of repeatedly printing 100 or more sheets or an operation of printing a high-definition image on a large sheet, a dot missing detection operation is performed at an appropriate timing. (S12). For this reason, the malfunction that a dot missing image is printed can be suppressed.

<About missing dot detection operation>
Next, a specific procedure of the missing dot detection operation (S12) will be described. FIG. 12 is a flowchart showing a specific procedure of the missing dot detection operation. This dot missing detection operation is performed in a state in which the carriage CR is moved to the inspection position (position shown in FIG. 5B).

  In this dot missing detection operation, first, the detection control unit 47 sets the first threshold value TH1 (S31).

  As described above, the first threshold value TH1 is a threshold value for determining whether or not ink droplets are normally ejected, and is set to 3 V, for example.

  If the first threshold value TH1 is set, a discharge inspection is performed (S32). The specific procedure of this ejection inspection will be described later, but the contents of the operation are as described above.

  Briefly, ink droplets are ejected while switching the nozzle Nz to be inspected, and whether or not ink droplets are ejected is determined for each nozzle Nz based on the maximum amplitude Vmax of the voltage signal SG from the amplifier 45. . The determination result is stored in the register of the detection control unit 47.

  If the discharge inspection is performed, a determination based on the detected voltage is performed (S33). In the discharge inspection (S32), the detection voltage (the amplitude of the signal from the amplifier 45) is compared with the first threshold value TH1, and the detection results for all the nozzles Nz are obtained by referring to the comparison results for the individual nozzles Nz. It is determined whether or not the voltage is higher than a first threshold value TH1 (S34).

  Here, when the detection voltages for all the nozzles Nz are higher than the first threshold value TH1 (Y in S34), it is determined that there is no missing dot, that is, there is no non-ejection nozzle. In this case, information indicating no missing dots is set in the register, and the process returns from this missing dot detection operation. Further, when the detection voltage for some of the nozzles Nz is equal to or lower than the first threshold TH1, it is determined that there is a missing dot, that is, there is a non-ejection nozzle. In this case, the missing dot information is set in the register, and the number of nozzles (X) is also stored as missing nozzles of the first threshold TH1. If the all missing dot flag (described later) has been set in the previous processing, the flag is cleared at this stage. This is because it is considered that the ink ejection failure has been recovered by the dot dropout recovery operation (S16).

  On the other hand, when the condition of step S34 is not satisfied, it is considered that a hardware abnormality such as current leakage or disconnection through the detection electrode 313, unstable ejection, or the like has occurred.

  In this case, the detection control unit 47 sets the second threshold value TH2 (S35). As described above, the second threshold value TH2 is a threshold value for determining whether or not an abnormality of the detection electrode 313 due to a short circuit or the like (abnormality due to current leakage) has occurred, and is set to 2.5 V, for example. .

  If the second threshold value TH2 is set, the ejection inspection is performed again (S36), and the determination based on the detected voltage is performed (S37).

  In this determination, in the ejection inspection (S36), the detection voltage (amplitude of the signal from the amplifier 45) is compared with the second threshold value TH2, and all the nozzles are referred to by referring to the comparison results for the individual nozzles Nz. It is determined whether or not the detected voltage for Nz is higher than the second threshold value TH2. Here, when the detection voltage for some of the nozzles Nz is equal to or lower than the second threshold TH2, it is determined that there is a missing dot, that is, there is a non-ejection nozzle. In this case, the missing dot information is set in the register, and the number of nozzles (Y) is also stored as missing nozzles of the second threshold TH2.

  Next, the remaining number of nozzles (XY) obtained by subtracting the number of missing nozzles (Y) of the second threshold TH2 from the number of missing nozzles (X) of the first threshold TH1 is obtained. The number of remaining nozzles (XY), that is, the number of nozzles having a detection voltage level within a range defined by the first threshold value (3 V) and the second threshold value (2.5 V) is set in advance. A predetermined number (for example, 3) is compared, and it is determined whether or not the remaining number of nozzles (XY) is equal to or larger than the predetermined number (S38).

  If this condition is satisfied (Y in S38), it is considered that an abnormality in current leakage through the detection electrode 313 has occurred as described above. For this reason, abnormal termination processing due to current leakage is performed. For example, power supply to the detection electrode 313 is stopped, and a message indicating that an abnormality has occurred is displayed on the display.

  When this condition is not satisfied (N in S38), it is considered that an abnormality due to unstable ejection has occurred, not an abnormality in current leakage through the detection electrode 313. For this reason, even if an abnormality has occurred, it is considered that ink droplets have been ejected normally. In this case, information indicating no missing dots is set in the register, and the process returns from this missing dot detection operation.

  The printer 1 can also detect that there is a hardware abnormality on the condition that ink droplets are not ejected from all the nozzles Nz before and after the dot missing recovery operation (recovery process).

  From the standpoint of reliably detecting an abnormality, it can be said that in the missing dot recovery operation, it is desirable to perform the recovery operation with the highest degree of recovery among a plurality of types of recovery operations with different levels of recovery.

  In this printer 1, it can be said that it is desirable to perform a suction operation. On the other hand, from the viewpoint of suppressing the ink consumption, a recovery operation other than the recovery operation with the highest ink consumption among the multiple types of recovery operations with different ink consumption may be performed. This is desirable. In this printer 1, since the ink consumption by the suction operation is the largest, it can be said that it is desirable to perform the flushing operation and the fine vibration operation.

  Here, comparing the flushing operation with the micro-vibration operation, the flushing operation is an operation for forcibly ejecting ink droplets from the head HD, and the degree of recovery of the ejection capability is stronger than the micro-vibration operation. Since the recovery operation here is performed based on the fact that ink droplets are not ejected from all the nozzles Nz, if the balance between increasing the certainty of detection and suppressing the amount of ink consumed is considered. It can be said that the flushing operation is preferable to the fine vibration operation.

  In addition, when performing a flushing operation or a fine vibration operation, it is preferable to consider a non-use period during which ink droplets are not ejected. That is, when the non-use period is equal to or longer than the determination period in which the influence (for example, ejection failure) due to ink thickening appears significantly, it is preferable to perform the recovery operation with the highest degree of recovery. The printer 1 preferably performs a suction operation. By doing in this way, the malfunction which misidentifies the ejection failure resulting from the thickening of an ink as a hardware abnormality can be suppressed.

<Discharge inspection>
Next, a specific procedure of the discharge inspection (S32) will be described. FIG. 13 is a flowchart showing a specific procedure of the discharge inspection. In this ejection inspection, first, a nozzle row to be inspected is determined (S51). As described in FIG. 2B, the head HD is provided with six nozzle rows. Of these six nozzle rows, one nozzle row is determined as the nozzle row to be inspected. If the nozzle row to be inspected is determined, the block to be inspected is determined (S52). As described with reference to FIG. 8, one block includes 15 nozzles Nz. Therefore, 12 blocks are included in one nozzle row. Here, of the 12 blocks, one block to be inspected is determined. For example, the first block composed of the first to fifteenth nozzles Nz is selected.

  When the block to be inspected is determined, ink droplet ejection and voltage signal SG are detected for that block (S53). As described with reference to FIGS. 7A, 7B, and 8, ink droplets are continuously ejected 20 to 30 times from one nozzle Nz belonging to the block. Then, an electrical change caused by ejection of these ink droplets, that is, a change in electrical state caused by the ejection inspection current If is acquired using the detection capacitor 44 and the amplifier 45. In this embodiment, the maximum amplitude Vmax is acquired in association with each nozzle Nz. If the maximum amplitude Vmax is obtained, a comparison with a threshold value is performed. For example, in the detection operation in step S32 in the dot missing detection operation, the detection voltage is compared with the first threshold value TH1. Further, in the detection operation of step S36, the detection voltage is compared with the second threshold value TH2. The comparison result is stored in a register of the detection control unit 47. For example, when the register for the comparison result is 1 bit, the comparison result is stored with two types of contents such as “higher than threshold” and “below threshold”. When this register is 2 bits, the comparison result is stored with three types of contents such as “higher than threshold”, “same as threshold”, and “lower than threshold”.

  Further, in the ejection process or the like in step S53, determination of the maximum amplitude Vmax in the non-ejection dummy period is also performed. That is, it is determined whether or not the maximum amplitude Vmax in the non-ejection dummy period is higher than the threshold value. Here, when the maximum amplitude Vmax is higher than the threshold value, it is considered that the maximum amplitude Vmax is given by noise. For this reason, abnormality information indicating detection abnormality is set in the corresponding register. This information is referred to in the presence / absence determination of abnormality detection (S54). That is, in this process, it is determined whether or not abnormality information is set in the register. If the abnormality information has not been set (N in S54), the inspection result for the block to be inspected is held assuming that the detection has been performed normally (S55). That is, the comparison result is held for each nozzle Nz belonging to the block to be inspected. If the inspection result is held, it is confirmed whether the block to be inspected is the final block (S56), and if it is not the final block, the above-described processing is performed for the next block (S52). If it is the last block, it is confirmed whether it is the last nozzle row (S57). If it is not the last nozzle row, the above-described processing is performed for the next nozzle row (S51). If it is the last nozzle row, the inspection result of the nozzle row is held (S58), and the process returns from this ejection inspection.

  On the other hand, if it is determined in step S54 that there is a detection abnormality, in other words, if abnormality information has been set (Y in S54), the number of repetitions of the ejection processing, etc. (S53) for that block has reached a predetermined number. If there is no such condition (N in S59), the ejection process for the block (S53) is performed again. Thereby, when the short noise resulting from a mechanical vibration arises, the false detection resulting from this noise can be suppressed. The predetermined number of times can be arbitrarily determined. In determining the predetermined number of times, the number of nozzles Nz belonging to one block, the type of noise to be detected, and the like are considered. In the printer 1, the predetermined number of times is set to 130 in consideration of these.

  When the number of detection abnormality repetitions reaches a predetermined number (Y in S59), the carriage CR is moved (S60). This movement of the carriage CR is a process of temporarily moving the carriage CR from a position for inspection (for example, the position of FIG. 5B) to a position on the printing region side (for example, the position of FIG. 5A) and then returning it to the position for inspection. It is. By performing this process, there are cases where an abnormality caused by a mechanical factor can be resolved. For example, there may be a case where the short circuit state between the wiper 33 or the detection electrode 313 and the nozzle plate 222 due to foreign matter can be eliminated. After the movement of the carriage CR (S60), on the condition that this movement has not reached the predetermined number of times (N in S61), the ejection process for the block (S53) is performed again. Thereby, when the short circuit by the wiper 33 or a foreign material arises, this short circuit can be eliminated in a timely manner.

  If the detection abnormality is not resolved even after the carriage CR is moved a predetermined number of times (Y in S61), it is confirmed whether or not the function abnormality flag is set in the register (S62). If not set (N in S62), the function abnormality flag is set in the register (S63), and the process returns from the discharge inspection. In this case, the operation shifts to the printing operation (S14) without performing the missing dot detection operation of the other blocks. This is based on the idea that the detection abnormality may be eliminated by performing the printing operation. That is, in the printing operation, various operations such as movement of the carriage CR, conveyance of the paper, and ejection of ink droplets from each nozzle Nz are performed. On the other hand, if the function abnormality flag has already been set (Y in S62), it is determined that an abnormality has occurred, and the series of processing ends. This is based on the idea that there is a high possibility that some abnormality has occurred because the detection abnormality is not eliminated even if the printing operation is interposed.

=== Other Embodiments ===
Each of the above embodiments is intended to facilitate understanding of the present invention and is not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof. In particular, the embodiments described below are also included in the present invention.

<Detection of abnormalities>
In the above-described embodiment, the leakage of current from the detection electrode 313 is performed based on the results of the discharge inspection based on the first threshold TH1 (3V) and the discharge inspection based on the second threshold TH2 (2.5V). . This current leakage was assumed to occur through a leakage resistance of about 1 MΩ due to ink. Here, there are various types of noise, and current leakage may occur due to the presence of a good conductor such as metal. In this case, noise having a frequency higher than that of the detection signal may be superimposed on the detection signal shown in the upper part of FIG. 14A as shown in the lower part.

  And it is preferable to detect the leakage of the electric current by a good conductor at an early stage. In addition, when noise disappears before the non-ejection dummy period arrives, accurate detection cannot be performed for the block. In such a case, it is effective to detect current leakage based on the frequency of the detection signal. For example, if a signal with a frequency higher than the frequency of the detection signal that should be originally obtained (corresponding to the reference frequency) is obtained in the detection period for one nozzle, it is assumed that noise that cannot be overlooked has occurred. Is determined to have occurred. Here, the detection signal is a signal amplified by the amplifier 45 and corresponds to a potential change in the other conductor of the detection capacitor 44.

  For example, in the example of FIG. 14B, as indicated by a thick line, a portion having an amplitude greater than or equal to the first threshold TH1 to be obtained in the detection period TNz for one nozzle is one cycle. Therefore, it is determined that an abnormality has occurred when a portion having an amplitude equal to or greater than the first threshold value TH1 is detected for two cycles or more in the detection period for one nozzle, that is, when the frequency is doubled or more. To do.

  With this configuration, noise can be found early, and even noise that disappears before the non-ejection dummy period arrives can be handled. The detection of noise in the non-ejection dummy period and the detection of noise in the detection period for one nozzle may be combined and it may be determined as abnormal when noise is detected in both periods. In this case, the certainty of detection can be improved.

<About the second threshold TH2>
In the above-described embodiment, one type of second threshold value TH2 is set. Here, regarding the second threshold TH2, a plurality of types may be determined by different voltage values. For example, an upper second threshold value lower than the first threshold value TH1 and a lower second threshold value lower than the upper second threshold value are determined. With such a configuration, it is possible to increase the accuracy of detection of the abnormality of the detection electrode 313 due to a short circuit or the like and the detection of hardware abnormality.

<About missing dot detection operation>
In the above-described embodiment, the example in which the dot missing detection operation (S12) is performed in response to the reception of the print command has been described. Here, the dot missing detection operation may be performed at the power-on timing. With this configuration, the printing operation is not performed even if the detection abnormality in the missing dot detection operation corresponding to the power-on is not resolved (N in S62). If the detection error is not resolved even in the dot missing detection operation corresponding to the reception of the first print command, an abnormal stop based on the function abnormality flag is performed (Y in S62). For this reason, the malfunction that a useless printing is performed can be suppressed.

<About hardware abnormality detection>
The hardware abnormality detection may be performed step by step from a type of recovery operation that consumes less ink (liquid). For example, the fine vibration operation, the discharge inspection, the flushing operation, the discharge inspection, the suction operation, and the discharge inspection may be performed in this order. In this case, if the ejection of the ink droplets can be detected by the ejection inspection performed after the fine vibration operation, the subsequent recovery process does not need to be performed, so that the ink consumption can be suppressed. And finally, since suction operation is performed, the certainty of detection can also be improved.

  Further, from the viewpoint of suppressing ink consumption, the flushing operation may be performed for some of the nozzles Nz. This is because hardware abnormality such as disconnection can be detected if there is even one nozzle Nz capable of ejecting ink.

<About the missing dot detection unit 15>
In the above-described embodiment, the potential change of the detection electrode 313 caused by the ejection of the ink droplet is extracted by the detection capacitor 44, but the present invention is not limited to this configuration. Any other configuration may be used as long as the potential change of the detection electrode 313 can be extracted.

  Further, the missing dot detection unit 15 may be configured as shown in FIGS. 15A and 15B. Briefly, in FIG. 15A, the high-voltage power supply unit 41 is connected to the nozzle plate 222, and the detection electrode 313 is connected to the ground. FIG. 15B detects a change in the electrical state caused by the movement of charges on the nozzle plate 222 side (a kind of ejection inspection current If) caused by the ejection of ink droplets. Even with these configurations, ejection of ink droplets can be detected.

<Regarding the configuration in which the liquid is grounded>
In the above-described embodiment, the conductive liquid is set to the ground potential by setting the conductive nozzle plate 222 to the ground potential (first potential, other predetermined potential). However, the present invention is not limited to this configuration. . That is, it is sufficient that the conductive liquid can be set to the ground potential. For example, a conductive member that is provided on a wall surface such as the ink flow path or the pressure chamber 224 and is electrically connected to the ink in the nozzle Nz may be provided, and this conductive member may be set to the ground potential. The ink is not limited to the ground potential, and any potential difference necessary for detection may be required between the ink and the detection electrode 313. That is, a slight bias may be given.

<Nozzle surface>
In the above-described embodiment, the head HD in which the surface of the nozzle plate 222 is the nozzle surface has been described as an example. Here, in the case of the head in which the nozzle is provided integrally with the flow path forming substrate, the surface of the member provided with the nozzle is the nozzle surface.

<Discharge inspection device>
In the above-described embodiment, the discharge inspection apparatus mounted on the printer 1 has been described. However, the present invention is not limited to this configuration. For example, it can also be configured as a dedicated inspection device for inspecting the head unit 14.

<About liquid ejection device>
In the above-described embodiment, the printer 1 has been described as an example of the liquid ejecting apparatus. Here, the liquid ejecting apparatus is not limited to the printer 1. For example, color filter manufacturing apparatus, dyeing apparatus, fine processing apparatus, semiconductor manufacturing apparatus, surface processing apparatus, three-dimensional modeling machine, liquid vaporizer, organic EL manufacturing apparatus (particularly polymer EL manufacturing apparatus), display manufacturing apparatus, film formation The same technology as that of the present embodiment may be applied to various liquid ejection devices to which inkjet technology such as a device and a DNA chip manufacturing device is applied. These methods and manufacturing methods are also within the scope of application.

1 printer, 11 paper transport mechanism, 12 carriage moving mechanism,
13 drive signal generation circuit, 14 head unit,
15 missing dot detector, 16 cap mechanism,
17 detector group, 18 printer side controller,
21 cases, 22 flow path units, 221 flow path forming substrates,
222 nozzle plate, 223 diaphragm,
223a diaphragm part, 224 pressure chamber,
225 ink supply path, 226 common ink chamber, 227 support plate,
227a island, 228 elastic film, 23 piezo element unit,
231 piezoelectric element group, 232 fixing plate, 31 cap,
311 side wall, 312 moisturizing member, 313 detection electrode,
313a frame part, 313b diagonal part, 313c cross part,
32 slider member, 321 contact portion, 322 support shaft,
324 arm part, 33 wiper, 41 high voltage power supply unit,
42 limiting resistance, 43 sensing resistance,
44 detection capacitor, 45 amplifier, 46 smoothing capacitor,
47 detection control unit, 47a register group, 47b AD conversion unit,
47c voltage comparison unit, 47d control signal output unit,
CP computer, CR carriage, PL platen,
HD head, HC head controller, PZT piezo element,
T repetition period, COM drive signal, PS discharge pulse,
SG voltage signal, TH1 first threshold, TH2 second threshold

Claims (6)

A plurality of nozzles for discharging liquid;
A detection electrode facing the plurality of nozzles at a predetermined interval;
A power source for setting the detection electrode to a predetermined potential;
A detection unit for detecting a change in potential of the detection electrode caused by discharge of the liquid from the nozzle;
A determination unit that determines whether or not an abnormality has occurred for each nozzle based on a change in potential of the detection electrode detected by the detection unit;
With
The determination unit
Whether or not the magnitude of the potential change of the detection electrode caused by the discharge of the liquid from the nozzle is within a range defined by the first threshold value and a second threshold value that is lower than the first threshold value by a predetermined level. A first determination process for determining
A second determination process for determining whether or not the number of nozzles that have caused the potential change of a size within the range is less than a predetermined number;
To determine whether or not an abnormality has occurred. The discharge inspection apparatus according to claim 1,
The determination unit
In the first determination process,
Determining whether the magnitude of the potential change of the detection electrode caused by the discharge of the liquid from the nozzle is greater than a first threshold;
When the result is negative, the number is counted as the nozzle that caused the potential change below the first threshold,
Determining whether it is greater than a second threshold that is a predetermined level lower than the first threshold;
When the result is negative, the number is counted as a nozzle that causes the potential change below the second threshold,
In the second determination process,
The number of remaining nozzles is calculated by subtracting the number of nozzles causing the potential change below the second threshold from the number of nozzles causing the potential change below the first threshold, and the remaining number of nozzles is predetermined. Determine if it is greater than or equal to the number,
When the determination is affirmative, it is determined that an abnormality has occurred due to leakage of the current generated through the detection electrode, and when the determination is negative, the discharge inspection device determines that an abnormality has occurred due to unstable discharge. . The discharge inspection apparatus according to claim 1 or 2,
The detection unit has a detection capacitor in which one conductor is electrically connected to the detection electrode,
The determination unit is an ejection inspection device that determines whether an abnormality has occurred in each nozzle based on a potential change of the other conductor of the detection capacitor. A discharge inspection apparatus according to any one of claims 1 to 3,
The detection unit includes an amplifier that amplifies a potential change of the other conductor of the detection capacitor;
The determination unit is an ejection inspection apparatus that determines whether or not an abnormality has occurred for each nozzle based on a potential change amplified by the amplifier. The discharge inspection apparatus according to any one of claims 1 to 4,
The discharge inspection apparatus, wherein the detection electrode is disposed on an absorbing material that absorbs the liquid. A plurality of nozzles that discharge liquid, a detection electrode that faces the plurality of nozzles at a predetermined interval, a power source that sets the detection electrode to a predetermined potential, and the detection that is caused by the discharge of liquid from the nozzle In an apparatus comprising: a detection unit that detects a potential change of the electrode for detection; and a determination unit that determines whether an abnormality has occurred for each nozzle based on the potential change of the detection electrode detected by the detection unit A discharge inspection method,
Determining whether the magnitude of the potential change of the detection electrode caused by the discharge of the liquid from the nozzle is greater than a first threshold;
When the result is negative, the number is counted as the nozzle that caused the potential change below the first threshold,
Determining whether it is greater than a second threshold that is a predetermined level lower than the first threshold;
When the result is negative, the number is counted as a nozzle that causes the potential change below the second threshold,
The number of remaining nozzles is calculated by subtracting the number of nozzles causing the potential change below the second threshold from the number of nozzles causing the potential change below the first threshold, and the remaining number of nozzles is predetermined. Determine if it is greater than or equal to the number,
When the determination is positive, it is determined that an abnormality has occurred due to leakage of the current generated through the detection electrode, and when the determination is negative, it is determined that an abnormality has occurred due to unstable discharge. .

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