JP2016163972A - Liquid droplet jet device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid droplet jet device which can remove air bubbles.SOLUTION: A liquid droplet jet device includes: a liquid droplet jet head having a plurality of pressure chambers which communicate with a plurality of nozzles for discharging a liquid, and a plurality of piezoelectric elements which drive the pressure chambers; and a control part which carries out recovery processing including driving of the piezoelectric elements by applying a voltage on the piezoelectric elements at a predetermined first frequency, and driving of the piezoelectric elements by applying a voltage on the piezoelectric elements at a second frequency different from the first frequency when a predetermined condition is satisfied.SELECTED DRAWING: Figure 8

Description

    Embodiments described herein relate generally to a droplet ejecting apparatus.

  The droplet ejecting apparatus is used for manufacturing various display devices such as a liquid crystal display device, an electron emission display device, a plasma display device, and an electrophoretic display device in addition to manufacturing various printed materials. The droplet ejecting apparatus includes, for example, a droplet ejecting head that ejects droplets from a plurality of nozzles toward an application target. The droplet ejection head is driven by a common chamber to which, for example, a liquid coating material is supplied, a plurality of pressure chambers communicating with the common chamber, a plurality of piezoelectric elements for applying pressure to the plurality of pressure chambers, and a plurality of piezoelectric elements A plurality of electrodes for applying a voltage and a nozzle plate having nozzles at positions corresponding to the pressure chambers are provided. In a droplet ejecting apparatus, if bubbles are mixed in the vicinity of a pressure chamber or a nozzle, the accuracy of ejection is affected. Therefore, a technique for reliably removing bubbles is required.

JP 2008-296515 A

  The problem to be solved by the present invention is to provide a liquid droplet ejecting apparatus capable of removing bubbles.

  A droplet ejecting apparatus according to an embodiment includes a droplet ejecting head including a plurality of pressure chambers communicating with a plurality of nozzles that eject liquid, and a plurality of piezoelectric elements that drive the pressure chambers, and a predetermined condition If the piezoelectric element satisfies the condition, a voltage is applied to the piezoelectric element at a predetermined first frequency to drive the piezoelectric element, and a voltage is applied to the piezoelectric element at a second frequency different from the first frequency. And a controller that performs a recovery process including driving the piezoelectric element.

FIG. 2 is a block diagram illustrating a configuration of a liquid droplet ejecting apparatus according to the embodiment. FIG. 3 is a perspective view illustrating a configuration of a liquid droplet ejecting head according to the embodiment. FIG. 3 is a perspective view showing a part of the liquid droplet ejecting head. Sectional drawing which follows the AA line of FIG. 3 of the droplet discharge head. Explanatory drawing which shows operation | movement of the piezoelectric element which concerns on the same embodiment. FIG. 6 is an explanatory diagram showing a pressure distribution when a piezoelectric element is driven at a fundamental frequency in a pressure chamber of the droplet ejecting head according to the embodiment. Explanatory drawing which shows pressure distribution at the time of driving a piezoelectric element by the double frequency of the fundamental frequency in the pressure chamber of the droplet discharge head. 6 is a flowchart illustrating a method for controlling the droplet ejecting apparatus according to the embodiment. 9 is a flowchart showing a method for controlling a droplet ejecting apparatus according to a second embodiment. Block diagram of a droplet ejecting apparatus according to a third embodiment The figure which shows the example of the voltage waveform which concerns on the same embodiment. FIG. 6 is a perspective view illustrating a configuration of a liquid droplet ejecting head according to another embodiment.

    Hereinafter, the configuration of the droplet ejecting apparatus 1 according to the first embodiment will be described with reference to FIGS. 1 to 8. In the figure, arrows X, Y, and Z indicate three directions orthogonal to each other. In each drawing, the configuration is appropriately enlarged, reduced, or omitted for explanation. FIG. 1 is a block diagram showing the configuration of the droplet ejecting apparatus 1. FIG. 2 is a perspective view showing a configuration of the droplet ejecting head 10, and FIG. 3 is a perspective view showing a part of the droplet ejecting head 10. FIG. 4 is a cross-sectional view of the droplet ejecting head 10.

  As shown in FIG. 1, the droplet ejecting apparatus 1 includes a droplet ejecting head 10 that ejects droplets, a head moving mechanism 21 that moves the droplet ejecting head 10, and an object that supports an ejected object in a movable manner. The object moving mechanism 22 and the control apparatus 30 which controls operation | movement of each part of the droplet ejecting apparatus 1 are provided.

  The droplet ejecting head 10 shown in FIGS. 2 to 5 is a so-called share mode share wall type droplet ejecting head 10. The droplet ejecting head 10 includes a piezoelectric substrate 11 having a plurality of grooves 16 forming the pressure chamber C1, a nozzle plate 12 provided on a side surface of the piezoelectric substrate 11 and having a plurality of nozzles communicating with the pressure chamber C1. And a cover plate 13 that covers the piezoelectric substrate 11 via a pressure chamber C1 and a common chamber C2 formed on the pressure chamber C1. A flow path including a plurality of pressure chambers C <b> 1 communicating with the nozzles and a common chamber C <b> 2 that is a space communicating with the plurality of pressure chambers C <b> 1 is configured inside the droplet ejecting head 10.

  In the droplet ejecting apparatus 1, the droplet ejecting head 10 is disposed such that the X direction is along the vertical direction and the nozzle 12 a faces downward, and during printing, an object to be printed below the droplet ejecting head 10. Is transported. Therefore, the pressure chamber C1 is disposed along the vertical direction, and the common chamber C2 continues above the pressure chamber C1.

The piezoelectric substrate 11 includes a laminated piezoelectric body 15 in a region on one side. The laminated piezoelectric body 15 is configured by laminating a first piezoelectric member and a second piezoelectric member. The first piezoelectric member and the second piezoelectric member are polarized so that their polarization directions are opposite to each other, and are bonded via an adhesive layer 25. For example, PZT (lead zirconate titanate) is used as the first piezoelectric member or the second piezoelectric member.
A plurality of grooves 16 are formed in parallel on the surface of the piezoelectric substrate 11. The groove 16 opens on one side and upper side of the piezoelectric substrate 11 and is formed to have a predetermined length from one end of the piezoelectric substrate 11. The groove 16 has an elongated shape whose longitudinal direction is along the X direction when viewed from above, and has a predetermined depth. In view of the processing, the bottom surface is curved as shown in FIG. The plurality of grooves 16 constitute a pressure chamber C1. Electrodes 17 are formed on the inner bottom surface and both side surfaces of the pressure chamber C <b> 1 constituted by the grooves 16.

  The electrode 17 is formed from the inside of the groove 16 to the upper surface of the piezoelectric substrate 11 and is connected to a wiring pattern 18 formed on the upper surface of the piezoelectric substrate 11.

  The pillar-shaped portion remaining between the plurality of grooves 16 in the laminated piezoelectric body 15 constitutes the piezoelectric element 19. The piezoelectric element 19 becomes a plurality of capacitive loads that apply pressure for ink introduction and ink ejection to the pressure chamber C1. Each piezoelectric element 19 includes a first piezoelectric element 19a and a second piezoelectric element 19b stacked. The base end portions of the plurality of piezoelectric elements 19 are continuous, and the piezoelectric substrate 11 has a comb-shaped cross section. In one region, a plurality of elongated piezoelectric elements 19 are arranged side by side in the Y direction via a plurality of grooves 16.

  A wiring pattern 18 is formed on the upper surface of the substrate 11. The upper surface portion of the other side of the substrate 11 is not covered with the cover plate 13 and is exposed. A circuit board 23 having a drive circuit for driving the droplet ejecting head 10 is mounted on the upper surface of the other side. The circuit of the circuit board 23 is connected to the electrode 17 in the pressure chamber C <b> 1 through the wiring pattern 18.

  The piezoelectric element driving circuit 37 applies a predetermined voltage to the electrodes connected to the piezoelectric elements of the respective pressure chambers in accordance with an ejection command from the piezoelectric element driving unit 34 in the control device 30. The piezoelectric element driving power source 38 is connected to the piezoelectric element driving circuit 37 and supplies power necessary for driving the piezoelectric element 19.

  The cover plate 13 is a rectangular plate member having an ink supply port 13a that communicates with the common chamber C2 and allows ink to flow from the outside. The cover plate 13 is disposed to face the upper surface of the piezoelectric substrate 11 and covers a region where the groove 16 is formed. The cover plate 13 is disposed to face the substrate 11 via a common chamber C2 formed in communication with the plurality of pressure chambers C1.

  The nozzle plate 12 has a rectangular shape with a predetermined thickness, and is provided on one side surface of the substrate 11 so as to cover one end side of the groove 16. In the nozzle plate 12, a nozzle row having a plurality of nozzles 12a penetrating in the thickness direction is formed. The plurality of nozzles 12a are respectively disposed at positions corresponding to the plurality of pressure chambers C1.

  By the substrate 11, the cover plate 13, and the nozzle plate 12, a plurality of pressure chambers C1 arranged in parallel in the Y direction are formed in the liquid droplet ejecting head 10, and each pressure chamber C1 is formed above the plurality of pressure chambers C1. A flow path including a common chamber C2 that is a space that communicates with the common chamber C2 is formed. A region on one side in the X direction of a plurality of pressure chambers C1 arranged in parallel in the Y direction is covered with the cover plate 13, and a region on the other side communicates with the adjacent common chamber C2.

  FIG. 1 is a block diagram showing a control system of the droplet ejecting apparatus 1 according to the present embodiment. The control device 30 includes a control unit 31 including a controller, a detection unit 32 that detects an ejection state of the droplet ejection head 10, a determination unit 33 that determines whether or not a bubble removal processing condition is satisfied, and a droplet ejection head A piezoelectric element driving unit 34 for driving the piezoelectric element, and a moving mechanism driving unit 35 for driving the moving mechanism and the object moving mechanism unit.

  The detection unit 32 detects detection information related to conditions under which the droplet ejection device 1 performs bubble removal processing as recovery processing. For example, in the present embodiment, the detection unit 32 is configured by an automatic recognition device that combines an ejection state detection mechanism 36 such as a camera and an image processing device. The detection unit 32 acquires, for example, an image of the ejection target after droplet ejection by a camera.

  The determination unit 33 detects an ejection abnormality of the droplet ejection head 10 based on the detection result of the detection unit 32 and transmits a signal corresponding to the detection result to the control unit 31. For example, in this embodiment, it is determined whether a preset condition is satisfied based on an image captured by a camera. For example, the image of the ejection target after the droplet ejection acquired by the detection unit 32 is compared with a reference image registered in advance. Thereby, insufficient or excessive injection, misalignment, etc. are determined.

  The control unit 31 has a function of controlling the operations of the droplet ejecting head 10, the head moving mechanism 21, and the object moving mechanism 22 in accordance with various programs to perform the droplet ejecting operation. Moreover, the control part 31 is provided with the function to perform a bubble removal process, when satisfy | filling a bubble removal process condition. Specifically, the bubble removal process is performed by applying a first voltage to the piezoelectric element 19 to drive the piezoelectric element 19 and applying a second voltage different from the first voltage to the piezoelectric element 19. 19 is provided.

  A control method of the droplet ejecting apparatus 1 according to the present embodiment will be described with reference to the flowchart of FIG.

  A printing process in which printing is performed by ejecting a liquid coating material (ejection material) from the nozzle 12a in the droplet ejecting apparatus 1 will be described. The control unit 31 detects an instruction input to start printing, for example, by an operator input operation (ST1). When there is an input for instructing the start of printing (YES in ST1), the droplet ejecting head 10, the head moving mechanism, and the object moving mechanism are driven as a printing process (ST2).

  Specifically, as a driving process for the droplet ejecting head 10, the control unit 31 applies a driving voltage to the driving element via the wiring pattern 18 by the driving circuit of the droplet ejecting head 10, for example, to drive the pressure chamber. A potential difference is applied to the electrode 17 in C1 and the electrodes 17 on both sides. Then, the first piezoelectric element 19 and the second piezoelectric element 19 are deformed in directions opposite to each other, and the drive element is bent and deformed by deformation of both the piezoelectric elements 19. As an example, as shown in FIG. 5 (a), the piezoelectric element 19 is deformed in the direction in which the volume of the pressure chamber C1 to be driven increases, and the pressure chamber C1 is set to a negative pressure, thereby allowing ink to enter the pressure chamber C1. Lead. Subsequently, as shown in FIG. 5B, the piezoelectric element 19 is deformed in the direction in which the volume of the pressure chamber C1 is reduced, and the pressure in the pressure chamber C1 is pressurized, whereby a droplet is discharged from the nozzle 12a. By repeating the above bending deformation alternately, droplets are continuously discharged from the nozzle 12a.

  In ST2, the control unit 31 drives the head moving mechanism and the object moving mechanism simultaneously with the driving of the liquid droplet ejecting head 10, thereby causing the nozzle 12a of the liquid droplet ejecting head 10 to face a predetermined position of the object. Adjust the position so that.

  Among the causes that cause the ejection abnormality of the droplet ejecting apparatus 1, there is a mixture of bubbles. When bubbles are generated in the pressure chamber C1, the nozzle 12a corresponding to the pressure chamber C1 cannot be ejected. For this reason, it is necessary to remove bubbles from the pressure chamber C1.

  During the printing process, the control unit 31 causes the detection unit 32 to detect detection information (ST3). Then, based on the detection result, the determination unit 33 determines whether or not a condition for performing the bubble removal process is satisfied (ST4). If it is determined that the condition for performing the bubble removal process is not satisfied (No in ST4), the printing process is continued. Then, it waits for a print completion instruction (ST5) and continues until there is a print completion instruction.

  When it is determined that the condition for performing the bubble removal process is satisfied (YES in ST4), printing is stopped (ST6) and the bubble removal process is performed.

  After the printing is stopped, the control unit 31 generates a stationary wave in the ink in the pressure chamber C1 and moves the bubbles in order to remove the bubbles (ST7, ST8). Specifically, when the control unit 31 determines that an ejection abnormality has occurred based on an image from the detection unit 32, the control unit 31 applies a voltage at a first frequency to the piezoelectric element 19 to drive the piezoelectric element 19 ( ST7), a second drive for driving the piezoelectric element 19 by applying a voltage at the second frequency to the piezoelectric element 19 and (ST8) are sequentially performed.

  In the droplet ejecting head 10, the resonance frequency that generates a standing wave in the ink in the pressure chamber C1 is generally a value belonging to ultrasonic vibration. For the bubbles in the ultrasonic irradiation field, primary Bjerkens forces, which is a force that causes translational motion, acts. Experiments show that when the piezoelectric element 19 is driven at a frequency corresponding to the fundamental frequency among the resonance frequencies in the pressure chamber C1, the direction of movement of the bubbles changes depending on where the bubbles are in the pressure chamber C1. It was. In addition, when a standing wave is generated in order to move bubbles, there is no need to accompany ink ejection. Specifically, by suppressing the voltage that generates a standing wave to a voltage that does not cause droplet ejection, bubbles in the pressure chamber C1 can be removed without ejecting ink. Thereby, the consumption of ink accompanying the removal of bubbles can be suppressed. In the present embodiment, as an example, the first frequency is the fundamental frequency of the resonance frequencies in the pressure chamber C1, and the second frequency is twice the fundamental frequency.

  FIG. 6 shows the pressure distribution in the pressure chamber C1 when driven at the first frequency and the moving direction of the bubbles. This pressure distribution is obtained by estimating the pressure distribution in the pressure chamber C1 from the theory of primary Bjerkness forces. Here, in the pressure chamber C1, the pressure rises from one side in the X direction where the nozzle is disposed toward the other end side to a predetermined position in the center of the pressure chamber C1, reaches a peak position, and further on the other end side. The distribution is such that the pressure decreases toward the end. In general, if the inside of the pressure chamber C1 is an ideal one-end opening and other end-closing pipe, the pressure is maximum at the closing end and the pressure is zero at the opening end. However, in the inkjet head having the configuration according to the present embodiment, In the pressure distribution, since the nozzle on one end side is opened, it is considered that the pressure does not become the maximum because the boundary condition of the closed end is not perfect on the nozzle side of the pressure chamber C1.

In FIG. 6, the position corresponding to the antinode of the standing wave of the pressure distribution, that is, the peak position P1 where the pressure is switched from rising to falling is the position where the moving direction of the bubbles is switched. When there is a bubble at the peak position P1, the bubble does not move to either the nozzle side or the common chamber C2 side and stays there. Bubbles in the range indicated by A1 on the common chamber C2 side from the peak position P1 move toward the common chamber C2. Bubbles in the range indicated by A2 on the nozzle side from the peak position P1 move in the direction of the nozzle.
In order to prevent bubbles from staying, in this embodiment, the stationary wave is changed to move the bubbles, and the peak position is shifted. That is, the piezoelectric element 19 is driven by switching to a second frequency different from the first frequency. For example, after the piezoelectric element 19 is driven at the fundamental frequency as the first frequency, the piezoelectric element 19 is subsequently driven at a frequency twice the fundamental frequency as the second frequency.

  FIG. 7 shows the pressure distribution in the pressure chamber C1 and the moving direction of the bubbles when the piezoelectric element 19 is driven as the second frequency at twice the fundamental frequency obtained in the experiment.

  In FIG. 7, the position corresponding to the antinode of the standing wave of the pressure distribution, that is, the peak position P2 where the pressure switches from rising to falling is the position where the moving direction of the bubbles is switched. When there is a bubble at the peak position P2, the bubble does not move to either the nozzle side or the common chamber C2 side and stays there. Bubbles in the range indicated by A3 on the common chamber C2 side from the peak position P2 move toward the common chamber C2. Bubbles in the range indicated by A4 on the nozzle side from the peak position P2 move in the direction of the nozzle 12a.

  In ST7, when the frequency is switched and driven, the pressure distribution in the pressure chamber C1 changes, and the position where it hits the antinode of the standing wave, that is, the peak position where the pressure switches from rising to falling changes. Therefore, by switching the frequency, the bubbles stagnating at the peak position P1 when driven at the first frequency move in either the common chamber C2 side or the nozzle 12a side when driven at the second frequency. It will be. Note that the peak position P2 exists even when driven at the second frequency, but since the bubble that was originally at that position has already been moved when driven at the first frequency, the second peak position P2 is reached. Air bubbles do not stay on the surface.

  The bubbles that move from the pressure chamber C1 to the common chamber C2 side do not affect the discharge. On the other hand, the bubbles that have moved to the nozzle 12a side are discharged from the nozzle 12a by pressurizing the ink in the pressure chamber C1 and causing the ink to flow out of the nozzle. At this time, since the bubble has already moved to the vicinity of the nozzle opening of the nozzle 12a by driving the piezoelectric element 19, the amount of ink used for discharging can be minimized. Therefore, the loss of the coating material for discharging and time can be reduced as compared with the case of discharging the bubbles in the pressure chamber C1.

  By the above bubble removal processing of ST7 and ST8, all the bubbles existing over the entire length of the pressure chamber C1 are reliably moved to the common chamber C2 side or the nozzle side.

  After performing the first drive of ST7 and the second drive of ST8, for example, for a certain period of time, the process returns to ST3 again.

According to the liquid droplet ejecting apparatus 1 according to the present embodiment, when air bubbles are mixed in the pressure chamber C1, the air bubbles are prevented from staying, the air bubbles causing the ejection abnormality are reliably removed, and promptly The jet can be recovered. Moreover, it is possible to reliably remove bubbles over the entire length by switching the frequency. Accordingly, it is possible to provide the liquid droplet ejecting apparatus 1 that can reliably remove the air bubbles and realize high productivity and yield even when the ejection abnormality occurs due to the air bubbles. Moreover, the highly reliable liquid droplet ejecting apparatus 1 can be provided by preventing non-ejection due to bubbles.
[Second Embodiment]
The operation of the droplet ejecting apparatus 1 and the droplet ejecting apparatus 1 according to the second embodiment of the present invention will be described below with reference to FIG. FIG. 9 is a flowchart showing the operation of the droplet ejecting apparatus 1 according to the second embodiment. In the present embodiment, the droplet ejecting apparatus 1 performs a standby operation and a first drive operation as the bubble removal process when the condition for performing the bubble removal process is satisfied. Since the other apparatus configuration and operation procedure are the same as those of the droplet ejecting apparatus 1 according to the first embodiment, a duplicate description is omitted.

  In the present embodiment, the control unit 31 has a function of controlling the operations of the droplet ejecting head 10, the head moving mechanism 21, and the object moving mechanism 22 to perform the droplet ejecting operation. The control unit 31 has a function of causing the bubble removal process to be performed when it is determined that the condition for performing the bubble removal process is satisfied based on the detection result of the detection unit 32. Specifically, in the bubble removal process, the piezoelectric element 19 is driven by applying a first voltage to the piezoelectric element 19 and the apparatus waits for a predetermined time before driving the piezoelectric element 19 by applying the first voltage. And comprising.

Hereinafter, the configuration and operation of the droplet ejecting apparatus 1 according to the present embodiment will be described with reference to FIG.
In the present embodiment, as shown in FIG. 9, when a condition that requires bubble removal processing is detected (Yes in ST4), printing is stopped (ST6), and the control unit 31 removes bubbles. (ST11, ST12) are performed.
Specifically, the control unit 31 waits for a predetermined time when the detection unit 32 detects an ejection abnormality (ST11), and then drives the piezoelectric element 19 by applying a voltage to the piezoelectric element 19 at the first frequency. (ST12)
Here, in the droplet ejecting apparatus 1 according to the present embodiment, the droplet ejecting head 10 is attached such that the X direction is along the vertical direction and the nozzle is vertically downward. Therefore, the pressure chamber C1 is disposed along the vertical direction, and the common chamber C2 continues above the pressure chamber C1. In this case, the bubbles generated in the pressure chamber C1 move in the direction opposite to the gravity, that is, in the direction of the common chamber C2 by the buoyancy. Here, for example, in the case of driving at the first frequency, if the bubble has moved to the area A2 in FIG. 6 in advance, the bubble is moved into the common chamber C2 by driving the piezoelectric element 19 at the fundamental frequency. Can be moved. That is, it suffices to wait before driving for the time required for the bubbles to move to the area A2, and it is possible to reduce the stop time of the head and prevent the productivity from being lowered.
For example, according to an experiment, bubbles having a diameter of about 0.08 mm in the pressure chamber C1 having a cross-sectional area perpendicular to the extending direction of the pressure chamber C1 along the X in the drawing and having a cross-sectional area of 0.024 mm ² are Ascend at a speed of / s. If the length of the pressure chamber C1 is 1 mm, it takes about 19 seconds for bubbles in the vicinity of the nozzle to move to the common chamber C2. However, if it moves to the range of A2 shown in FIG. 6, that is, near the center of the pressure chamber C1, the bubbles can be moved to the common chamber C2 by driving the piezoelectric element 19 at the fundamental frequency. Therefore, in the case of the droplet ejecting apparatus 1 according to the present embodiment, the standby time can be set to about 9.5 seconds. Due to ST11 and ST12, the bubbles mixed in the pressure chamber C1 are surely moved into the common chamber C2 by the movement by standby and the movement by driving, and the bubble removal processing is completed. Thereafter, similarly to the first embodiment, the process returns to ST3 and the subsequent processing is performed.
According to the liquid droplet ejecting apparatus 1 according to the present embodiment, when air bubbles are mixed in the pressure chamber C1, the air bubbles are prevented from staying, the air bubbles causing the ejection abnormality are reliably removed, and promptly The jet can be recovered. Moreover, it is possible to reliably remove bubbles over the entire length by driving after waiting for a certain time when removing bubbles. Accordingly, it is possible to provide the liquid droplet ejecting apparatus 1 that can reliably remove the air bubbles and realize high productivity and yield even when the ejection abnormality occurs due to the air bubbles. Moreover, the highly reliable liquid droplet ejecting apparatus 1 can be provided by preventing non-ejection due to bubbles.
[Third Embodiment]
Hereinafter, operations of the droplet ejecting apparatus 1 and the droplet ejecting apparatus 1 according to the third embodiment of the present invention will be described with reference to FIGS. 10 and 11. In the droplet ejecting apparatus 1 according to the present embodiment, the detection unit 32 acquires a waveform from the piezoelectric element driving power source 38 connected to the piezoelectric element driving circuit 37, and the determination unit 33 sets the bubble removal processing condition based on the waveform. It is determined whether or not it satisfies. Other apparatus configurations and operation procedures are the same as those of the droplet ejecting apparatus 1 according to the first embodiment or the second embodiment.
The detection unit 32 has a function of acquiring a voltage waveform from the piezoelectric element driving power source 38 through the piezoelectric element driving circuit 37. The determination unit 33 has a function of determining whether or not the abnormal injection is based on the acquired voltage waveform. As a detection process of ST3, the control unit 31 acquires a voltage waveform from the piezoelectric element driving power source 38 through the driving circuit 21 of the piezoelectric element 19. In ST4, the determination unit 33 performs signal processing on the voltage value of the piezoelectric element 19 to determine whether or not the injection is good. An example of the acquired voltage waveform is shown in FIG. In this figure, the solid line indicated as OK is a waveform at the time of normal injection, and the broken line indicated as NG is a waveform when an injection abnormality occurs. For example, the injection start is detected from the waveform change at the time indicated by the time t1, and the voltage value V3 at the time t3 when a predetermined time t2 is set in advance is set to the threshold value Vth set in advance based on the waveform at the time of normal injection. Compare. As a result of the comparison, for example, in the voltage waveform of FIG. 11, when V3> Vth, it is determined that the injection is abnormal.
The liquid droplet ejecting apparatus 1 according to the present embodiment also has the same effects as those of the first and second embodiments. In addition, since the voltage waveform is obtained from a power source that reflects the voltage of each drive circuit, only one input circuit is required, and the circuit can be simplified.
In addition to the bubble removal process similar to the first embodiment that is driven by switching the frequency between the first frequency and the second frequency, the present embodiment waits for a certain time and then drives at a predetermined frequency. The present invention can also be applied to the bubble removal process similar to the second embodiment.
In addition, the said embodiment is an illustration and can be changed suitably. For example, in the first embodiment, the ejection abnormality is detected from the information of the camera as the detection unit 32, and the bubble removal process is performed when there is an ejection abnormality based on the detection result. It is not a thing.

For example, it is possible to visually inspect the injection result for the injection target after injection and detect an injection abnormality based on an operator's input operation. In this case, the input device by the operator functions as the detection unit 32. As another embodiment, the operation time or the number of times of injection may be set, and the bubble removal process may be performed every time or number of times. In this case, the detection unit 32 includes an arithmetic device and a storage device having a function of counting the operating time of the injection device or the number of injections. As another embodiment, a predetermined timing or device that is likely to cause ejection abnormality due to bubbles, such as when the droplet ejecting apparatus 1 is started, when the droplet ejecting head 10 is replaced, when ink is filled, or when ink is replaced, etc. This processing status may be set as a condition for performing the bubble removal processing. In this case, an input device on which an operator performs an input operation, a storage device that stores predetermined timing, a timer device that detects the status of the device, and the like function as the detection unit 32.
In addition, the aspect which performs a bubble removal process based on these fixed conditions is driven at the first frequency after waiting for a certain period of time in addition to the bubble removal process similar to the first embodiment which is driven by switching the frequency. The present invention can also be applied to the bubble removal process similar to the second embodiment. Even in these cases, even when there is a bubble having a position or size that does not affect the ejection, the bubble can be eliminated and the occurrence of non-ejection due to the bubble can be prevented.

Further, the conditions for performing the bubble removal process are not limited to the above-described embodiment, and may be, for example, at the time of replacement of the injection target.
Further, the structure of the droplet ejecting head 10 is not limited to the above embodiment. For example, a circulation type droplet ejecting head 10A shown in FIG. 12 may be used as another embodiment. The droplet ejecting head 10A includes an ink circulation unit 40 in a common chamber C2. The circulation unit 40 includes, for example, a pump 41 and a filter 42 not shown. The circulation unit 40 circulates the ink in the common chamber C <b> 2 by the pump 41. The ink pressurized by the pump 41 enters the common chamber C2 from the supply port 13c provided in the cover plate 13 by the circulation unit 40, passes through the common chamber C2, and from the discharge port 13d provided in the cover plate. Exit and return to pump 41. In the present embodiment, by providing a filter or the like for catching bubbles in the middle of the circulation path, the bubbles in the common chamber C2 are surely excluded, and the bubbles in the common chamber C2 flow into the ink chamber and eject ink. Can be prevented.

  In addition, although some embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1 ... Droplet ejecting apparatus, 10 ... Droplet ejecting head, 10A ... Droplet ejecting head, 11 ... Piezoelectric substrate, 12 ... Nozzle plate, 12a ... Nozzle, 13 ... Cover plate, 13a ... Ink supply port, 13c ... Supply port , 13d ... discharge port, 15 ... laminated piezoelectric material, 16 ... groove, C1 ... pressure chamber, C2 ... common chamber, 17 ... electrode, 18 ... wiring pattern, 19 ... piezoelectric element, 21 ... head moving mechanism, 22 ... object A moving mechanism, 30 ... a control device, 31 ... a control unit, 32 ... a detection unit, 33 ... a determination unit, 34 ... a piezoelectric element driving unit, 35 ... a moving mechanism driving unit, 40 ... a circulation unit.

Claims (5)

A liquid droplet ejecting head comprising: a plurality of pressure chambers communicating with a plurality of nozzles that discharge liquid; and a plurality of piezoelectric elements that drive the pressure chambers;
When a predetermined condition is satisfied, a voltage is applied to the piezoelectric element at a predetermined first frequency to drive the piezoelectric element, and a voltage is applied to the piezoelectric element at a second frequency different from the first frequency. And driving the piezoelectric element to perform a recovery process. A liquid droplet ejecting head comprising: a plurality of pressure chambers communicating with a plurality of nozzles that discharge liquid; and a plurality of piezoelectric elements that drive the pressure chambers;
When the predetermined condition is satisfied, the control unit performs a recovery process including waiting for a predetermined time and driving the piezoelectric element by applying a voltage to the piezoelectric element at a predetermined frequency after waiting for the predetermined time And a liquid droplet ejecting apparatus.   The controller detects ejection abnormality of the droplet ejecting head, starts up the droplet ejecting apparatus, replaces the droplet ejecting head, charges ink, replaces ink, and a predetermined operating time. The droplet ejecting apparatus according to claim 1, wherein the recovery process is performed every time and every predetermined number of times of ejection. The control unit detects voltage values from the plurality of piezoelectric elements,
The droplet ejecting apparatus according to claim 1, wherein the recovery process is performed when the detected voltage value satisfies a predetermined condition. The droplet ejecting head includes a common chamber communicating with the plurality of pressure chambers;
The liquid droplet ejecting apparatus according to claim 1, further comprising a circulation unit that circulates the discharge material in a flow path including the common chamber.

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