JP2016006746A - Ink jet device and method of manufacturing electronic device by using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ink jet device that can more finely adjust the coating amount of ink.SOLUTION: In an ink jet device, a controller makes an actuator perform a series of discharge operation containing a preliminary vibration operation and a regular vibration operation. The preliminary vibration operation contains a press operation for pressing ink in a nozzle to the outside. The regular vibration operation contains a suction operation for sucking ink in the nozzle into an ink chamber and a press operation for pressing sucked ink to the outside during a period when the sucked ink is displaced to the outside due to vibration. The controller is capable of performing plural discharge operations which are different in the length of the period from the press operation of the preliminary vibration operation till the suction operation of the regular vibration operation, and selects one of the executable plural discharge operations as a discharge operation which the actuator is made to execute.

Description

  The present invention relates to an inkjet apparatus and a method for manufacturing an electronic device using the inkjet apparatus.

  In recent years, for example, it has been proposed to use a coating method for manufacturing an electronic device such as an organic EL (Electro Luminescence) element or a thin film transistor (TFT). In general, an organic EL element includes an anode, a cathode, and an organic light emitting layer, and further includes a hole injection layer, a hole transport layer, an electron injection layer, and an electron transport layer as necessary. The TFT includes a gate electrode, a gate insulating film, a semiconductor layer, a source electrode, and a drain electrode. The organic light emitting layer, hole injection layer, hole transport layer, electron injection layer, electron transport layer, and semiconductor layer each have a unique function (light emission, hole injection, hole transport, electron injection, electron transport, channel formation). Are each referred to as a functional layer. When the functional layer is formed by a coating method, an ink containing a functional material constituting the functional layer and a solvent for dissolving or dispersing the functional material is prepared, and the prepared ink is applied onto the base substrate and applied. What is necessary is just to evaporate the solvent of an ink. An ink jet apparatus can be used for applying the ink (see, for example, Patent Document 1).

  The ink jet apparatus includes a stage for placing a base substrate and an ink jet head that moves relative to the stage. By ejecting ink from the ink jet head at an appropriate timing while the ink jet head is relatively moved on the stage, ink droplets can be landed on the target position of the base substrate. The ink jet head includes an ink chamber for containing ink, a nozzle communicating with the ink chamber, and an actuator for causing ink in the nozzle to vibrate to eject ink droplets from the nozzle. For example, a piezoelectric element is used as the actuator.

International publication WO2014 / 006877

  In a normal production line, different types of products may be produced using the same inkjet device. In addition, the optimum value of the amount of ink applied to form the functional layer may differ depending on the product model. To adjust the amount of ink applied, it is assumed that the number of ink droplets is simply adjusted. However, when the amount of ink applied is adjusted by the number of ink droplets, the amount of ink applied cannot be adjusted with an accuracy finer than the volume of ink droplets (about several pl). In recent years, with the increase in definition of electronic devices, the amount of ink applied has decreased, and the number of ink droplets tends to decrease. Therefore, the influence of the volume of ink droplets on the amount of ink applied is increasing.

  An object of the present invention is to propose an ink jet apparatus capable of finely adjusting the amount of ink applied.

  An ink jet apparatus according to an aspect of the present invention includes an ink jet head and a control unit. The inkjet head includes an ink chamber for containing ink, a nozzle communicating with the ink chamber, and an actuator for vibrating the ink in the nozzle. The control unit includes a preliminary vibration operation for vibrating the ink in the nozzle in a range where the ink is not discharged from the nozzle, and a main vibration operation for vibrating the ink in the nozzle in the range where the ink is discharged from the nozzle. A series of discharge operations are executed by the actuator. The preliminary vibration operation includes a pressing operation for pressing the ink in the nozzles toward the outside. This vibration operation is a suction operation for sucking ink in the nozzle toward the ink chamber, and presses the ink sucked toward the outside during a period in which the sucked ink is displaced outward due to vibration. Pressing operation. The control unit can execute a plurality of discharge operations having different lengths from the pressing operation of the preliminary vibration operation to the suction operation of the main vibration operation, and causes the actuator to execute one of the executable discharge operations. Select as the discharge operation.

  According to experiments by the inventors, by adjusting the length of the period from the pressing operation of the preliminary vibration operation to the suction operation of the main vibration operation (hereinafter referred to as “standby period”), the ink droplets ejected from the nozzles It was found that the volume of can be adjusted. According to the above configuration, since a plurality of ejection operations with different lengths of the standby period can be executed, the ink application amount can be adjusted more finely.

The figure which shows the mechanism part of the inkjet apparatus which concerns on embodiment of this invention. Functional block diagram of an inkjet device (A) is a partially cutaway perspective view showing a schematic configuration of the inkjet head, (b) is a cross-sectional view in which a portion of the inkjet head is enlarged. The figure which shows the waveform of the drive signal supplied to a piezoelectric element, the displacement of the liquid level of the ink in the nozzle which vibrates under the influence of the vibration of a piezoelectric element, and the behavior of an ink when an inkjet head is observed from the outside The figure which shows an example of the measurement result of the volume of the ink droplet The figure which shows the change of the volume of the ink droplet when changing the length of a waiting period FIG. 6 is a diagram in which the experimental results of FIG. 6 are arranged in order of the volume of ink droplets. It is a figure which shows the difference | error of ink required amount and ink application amount, (a) is a comparative example, (b) is an Example. The figure which shows each drive signal when changing the length of a waiting period The figure which shows an example of the table memorize | stored in the memory | storage means in a control apparatus. Flow chart showing operation of control device Partial sectional view of an organic EL display panel according to an embodiment of the present invention Plan view showing the structure of the partition wall layer Partial sectional view for explaining a method for producing an organic EL display panel Partial sectional view for explaining a method for producing an organic EL display panel The figure which shows the positional relationship of the opening part of a partition layer and a head part The figure for demonstrating the modification of preliminary vibration operation | movement The figure for demonstrating the modification of this vibration operation | movement The figure for demonstrating the modification of a pulse component Functional block diagram of an inkjet apparatus according to a modification The figure which shows an example of the table memorize | stored in the memory | storage means in a control apparatus. The flowchart which shows operation | movement of the control apparatus which concerns on a modification.

<1> One aspect of the present invention An ink jet apparatus according to one aspect of the present invention includes an ink jet head and a control unit. The inkjet head includes an ink chamber for containing ink, a nozzle communicating with the ink chamber, and an actuator for vibrating the ink in the nozzle. The control unit includes a preliminary vibration operation for vibrating the ink in the nozzle in a range where the ink is not discharged from the nozzle, and a main vibration operation for vibrating the ink in the nozzle in the range where the ink is discharged from the nozzle. A series of discharge operations are executed by the actuator. The preliminary vibration operation includes a pressing operation for pressing the ink in the nozzles toward the outside. This vibration operation is a suction operation for sucking ink in the nozzle toward the ink chamber, and presses the ink sucked toward the outside during a period in which the sucked ink is displaced outward due to vibration. Pressing operation. The control unit can execute a plurality of discharge operations having different lengths from the pressing operation of the preliminary vibration operation to the suction operation of the main vibration operation, and causes the actuator to execute one of the executable discharge operations. Select as the discharge operation. According to the above configuration, since a plurality of ejection operations with different lengths of the standby period can be executed, the ink application amount can be adjusted more finely.

  In the ink jet apparatus, the actuator may include a piezoelectric element, and the control unit may include a storage unit, a selection unit, and a signal generation unit. The storage unit stores waveform data indicating a waveform of a drive signal for driving the piezoelectric element corresponding to each of the plurality of ejection operations. The selection unit selects one of the waveform data stored in the storage unit. The signal generation unit generates a drive signal for driving the piezoelectric element based on the waveform data selected by the selection unit.

In a method for manufacturing an electronic device having a functional layer according to one embodiment of the present invention, an ink containing a functional material constituting the functional layer and a solvent for dissolving or dispersing the functional material is applied and the solvent is evaporated. Thus, a functional layer is formed. The ink application is performed using the ink jet apparatus according to one embodiment of the present invention.
An ink jet apparatus according to another aspect of the present invention includes a first ink jet head, a second ink jet head, and a control unit. The first inkjet head includes an ink chamber for storing ink, a nozzle communicating with the ink chamber, and an actuator for vibrating the ink in the nozzle. The second inkjet head includes an ink chamber for containing ink, a nozzle communicating with the ink chamber, and an actuator for vibrating the ink in the nozzle. The control unit includes a preliminary vibration operation for vibrating the ink in the nozzle in a range where the ink is not discharged from the nozzle, and a main vibration operation for vibrating the ink in the nozzle in the range where the ink is discharged from the nozzle. A series of first and second ejection operations are executed by the actuators of the first and second inkjet heads, respectively. The preliminary vibration operation in the first and second ejection operations includes a pressing operation of pressing the ink in the nozzles toward the outside. This vibration operation in the first and second ejection operations includes a suction operation for sucking ink in the nozzles toward the ink chamber, and a suction operation in which the sucked ink is displaced outward due to vibration. Pressing operation for pressing the ink toward the outside. The length of the period from the pressing operation of the preliminary vibration operation to the suction operation of the main vibration operation in the first discharge operation is adjusted to the first time length. The length of the period from the pressing operation of the preliminary vibration operation in the second ejection operation to the suction operation of the main vibration operation is adjusted to a second time length different from the first time length.

  In the production process of the product, the first ink is applied by the first ink jet head to form the first functional layer, and the second ink jet head is applied to form the second functional layer. There are things to do. For example, when the first functional layer is a hole transport layer and the second functional layer is an organic light emitting layer, or the first functional layer is any one of a plurality of colors such as red, green, and blue In the organic light emitting layer, the second functional layer may be an organic light emitting layer having a color different from the first functional layer among a plurality of colors such as red, green, and blue. At this time, the appropriate application amounts of the first and second inks may be different due to differences in the film thicknesses of the first and second functional layers and differences in the concentrations of the first and second inks. is there. In such a case, it is desirable that the application amounts of the first and second inks are finely adjusted. The inventors' experiments have shown that the volume of ink droplets ejected from the nozzles can be adjusted by adjusting the length of the waiting period. When the ink application amount is appropriately adjusted using this, it may be desirable to make the length of the standby period different between the first and second inkjet heads. According to the above configuration, since the length of the waiting period differs between the first and second inkjet heads, it is possible to apply appropriate amounts of the first and second inks, respectively. Note that the above configuration is naturally applied to an ink jet apparatus including three or more ink jet heads. When three or more inkjet heads are present, one of the three or more inkjet heads is interpreted as the first inkjet head and is different from the first inkjet head among the three or more inkjet heads. One inkjet head is interpreted as a second inkjet head. At this time, the length of the waiting period may be different between the first and second inkjet heads. Further, when there are three or more inkjet heads, it is sufficient that at least two inkjet heads have different waiting periods, and it is not necessary that all three or more inkjet heads have different waiting periods.

  In the ink jet apparatus, the actuators of the first and second ink jet heads may include a piezoelectric element. The control unit may include a storage unit and a signal generation unit. The storage unit includes first waveform data indicating a waveform of a first drive signal for driving a piezoelectric element included in the first inkjet head corresponding to the first ejection operation, and the second ejection operation. Corresponding to the second waveform data indicating the waveform of the second drive signal for driving the piezoelectric element included in the second inkjet head. The signal generation unit generates a first drive signal based on the first waveform data stored in the storage unit, and generates a second drive signal based on the second waveform data stored in the storage unit. Generate.

According to another aspect of the present invention, there is provided a method for manufacturing an electronic device having a functional layer, wherein an ink containing a functional material constituting the functional layer and a solvent for dissolving or dispersing the functional material is applied and the solvent is evaporated. To form a functional layer. Ink application is performed using an ink jet apparatus according to another aspect of the present invention.
<2> Embodiment 1
<2-1> Configuration of Inkjet Device FIG. 1 is a diagram showing a mechanism part of the inkjet device according to the embodiment of the present invention. FIG. 2 is a functional block diagram of the ink jet apparatus.

  As shown in FIGS. 1 and 2, the ink jet device 1000 includes an ink jet table 20, a head unit 30, and a control device 15. Although the inkjet apparatus 1000 is illustrated as a configuration in which one inkjet head 301 is provided in one head unit 30, the present invention is not limited to this. For example, a mode in which a plurality of inkjet heads 301 are provided, such as a mode in which a plurality of inkjet heads 301 are provided in one head unit 30 or a mode in which a plurality of head units 30 each provided with one or a plurality of inkjet heads 301 are provided. It is good.

  As shown in FIG. 2, the control device 15 includes a CPU 150, a storage unit 151 (including a nonvolatile memory such as an HDD and a semiconductor memory), a display unit (display) 153, an input unit 152, and a signal generation unit 154. . Specifically, the control device 15 can use a computer. The storage unit 151 stores a control program for driving the inkjet table 20 and the head unit 30 connected to the control device 15. When driving the inkjet apparatus 1000, the CPU 150 performs predetermined control based on an instruction input by the operator through the input unit 152 and each control program stored in the storage unit 151. The signal generation unit 154 generates a drive signal based on a command from the CPU 150.

<2-2> Inkjet Table As shown in FIG. 1, the inkjet table 20 is a so-called gantry work table. As a specific configuration, columnar stands 201A, 201B, 202A, and 202B are disposed at the four corners of the upper surface of the plate-like base 200. A fixed stage ST for placing a base substrate to be coated is disposed in an inner region surrounded by the stands 201A, 201B, 202A, 202B.

The guide shafts 203A and 203B are supported in parallel along the Y direction by the stands 201A, 201B, 202A and 202B. The linear motors 204 and 205 are inserted through the guide shafts 203A and 203B, respectively, and are movable along the guide shafts 203A and 203B.
The gantry unit 210 is mounted on the linear motors 204 and 205 so as to bridge the guide shafts 203A and 203B. The gantry unit 210 has a guide groove 211 formed along the X direction. The moving body 220 includes an L-shaped pedestal, and is supported by the gantry unit 210 so as to be slidable along the guide groove 211. The sliding of the moving body 220 is performed by the servo motor 221.

  The head unit 30 is attached to the moving body 220. The head unit 30 can be scanned in the Y direction by moving the gantry unit 210 along the guide shafts 203A and 203B. Further, by moving the moving body 220 along the guide groove 211 of the gantry unit 210, the head unit 30 can be scanned in the X direction. These scans are controlled by the control device 15 and the scan control unit 213 shown in FIG. The CPU 150 outputs a command to the scanning control unit 213 according to the control program, and the scanning control unit 213 controls the driving of the linear motors 204 and 205 and the servo motor 221 according to the command.

<2-3> Head Unit The head unit 30 includes an inkjet head 301 and a support unit 302. The ink jet head 301 is fixed to the moving body 220 via the support portion 302.
3A is a partially cutaway perspective view showing a schematic configuration of the inkjet head 301, and FIG. 3B is an enlarged cross-sectional view of a portion of the inkjet head 301, and FIG. It is a BB 'arrow sectional view in). The inkjet head 301 includes a nozzle plate 301i, a vibration plate 301h, an outer peripheral wall 301c, a partition wall 301d, and a piezoelectric element 3010. The nozzle plate 301i and the diaphragm 301h are disposed to face each other with a gap. The outer peripheral wall 301c is a frame-like member disposed in the gap between the nozzle plate 301i and the vibration plate 301h. The partition wall 301d is disposed in an internal space formed by the nozzle plate 301i, the vibration plate 301h, and the outer peripheral wall 301c, and divides the internal space into a plurality of ink chambers 301e and one reservoir 301g. Each ink chamber 301e communicates with a reservoir 301g through a flow path 301f. The nozzle plate 301 i has a plurality of nozzles 3031. Each nozzle 3031 has a one-to-one correspondence with each ink chamber 301e and communicates with the corresponding ink chamber 301e. Each piezoelectric element 3010 has a one-to-one correspondence with each ink chamber 301e, and is disposed at a position corresponding to the ink chamber 301e on the vibration plate 301h. As shown in FIG. 3B, the piezoelectric element 3010 includes electrodes 3011 and 3012 and a piezoelectric layer 3013 between the electrodes 3011 and 3012. The piezoelectric element 3010 serves as an actuator that vibrates according to a drive signal. The reservoir 301g temporarily stores the ink supplied through the ink supply hole 301h1. The ink stored in the reservoir 301g is supplied to each ink chamber 301e through each flow path 301f. The ink 40 supplied to each ink chamber 301e is ejected from each nozzle 3031 under the influence of vibration of each piezoelectric element 3010.

The ejection of ink is controlled by the control device 15 and the ejection control unit 300 shown in FIG. CPU 150 outputs a command to signal generation unit 154 according to the control program. The signal generation unit 154 generates a drive signal for driving the piezoelectric element 3010 according to the command. The drive signal is amplified by the ejection control unit 300 and supplied to the piezoelectric element 3010.
<2-4> Drive Signal FIG. 4 shows the waveform of the drive signal supplied to the piezoelectric element, the displacement of the ink level in the nozzle that vibrates under the influence of the vibration of the piezoelectric element (interface between ink and air). FIG. 5 is a diagram illustrating the behavior of ink when the inkjet head is observed from the outside.

  The drive signal includes a DC bias component having a DC bias voltage and a pulse component having a pulse voltage. In the present embodiment, the drive signal includes a preliminary vibration pulse component, a main vibration pulse component, and a damping vibration pulse component as pulse components. The piezoelectric element 3010 performs a series of ejection operations due to the pulse component. The discharge operation includes a preliminary vibration operation caused by the preliminary vibration pulse component, a main vibration operation caused by the main vibration pulse component, and a damping vibration operation caused by the damping vibration pulse component. In the present embodiment, when the voltage of the pulse component decreases, the volume of the ink chamber 301e expands and the ink in the nozzle 3031 is sucked toward the ink chamber 301e. Conversely, the voltage of the pulse component is When rising, the volume of the ink chamber 301e contracts, and the ink in the nozzle 3031 is pressed outward. That is, the voltage drop of the pulse component corresponds to a suction operation of sucking the ink in the nozzle 3031 toward the ink chamber 301e, and the pressure operation of pressing the ink in the nozzle 3031 toward the outside is caused by the voltage increase of the pulse component. It corresponds to.

  The preliminary vibration pulse component of the drive signal includes a voltage drop and a voltage rise. That is, the preliminary vibration operation executed by the piezoelectric element 3010 includes a suction operation and a pressing operation. The ink in the nozzle 3031 starts a natural vibration with the suction operation as a trigger. The half period T of the natural vibration of the ink is determined by the structure of the inkjet head 301 and the physical properties of the ink. The liquid level of the ink in the nozzle 3031 is periodically displaced due to the natural vibration of the ink. The length of the period (preliminary vibration period) from the suction operation to the pressing operation of the preliminary vibration operation is adjusted to a length (1T) that is one time the half cycle T of the natural vibration of the ink in the nozzle 3031. That is, the pressing operation of the preliminary vibration operation is executed within a period in which the ink level in the nozzle 3031 is displaced outward. Thereby, it is possible to efficiently apply a pressing force to the ink in the nozzle 3031 and to vibrate the ink efficiently. The preliminary vibration operation is executed for the purpose of vibrating the ink in the nozzle 3031 within a range where the ink is not ejected from the nozzle 3031. Therefore, the amplitude of the preliminary vibration pulse component is adjusted so that the ink in the nozzle 3031 is not ejected.

  The main vibration pulse component of the drive signal includes a voltage drop and a voltage rise. That is, the main vibration operation executed by the piezoelectric element 3010 includes a suction operation and a pressing operation. It is desirable that the pressing operation of the vibration operation is executed within a period in which the ink level in the nozzle 3031 is displaced outward. Accordingly, it is possible to efficiently apply a pressing force to the ink in the nozzle 3031 and to efficiently eject the ink. In the present embodiment, the pressing operation of the vibration operation is further performed at a timing at which the displacement of the ink liquid surface becomes zero even during the period in which the ink liquid surface is displaced outward. At the timing when the ink liquid surface displacement becomes zero, the ink liquid surface displacement speed becomes maximum. Therefore, the efficiency of applying a pressing force to the ink in the nozzle 3031 is maximized. Specifically, the length of the period from the suction operation to the pressing operation of the main vibration operation is adjusted to a length (1T) that is one time the half cycle T of the natural vibration of the ink in the nozzle 3031. This vibration operation is executed for the purpose of vibrating the ink in the nozzle 3031 in a range where ink is ejected from the nozzle 3031. Therefore, the amplitude of the vibration pulse component is adjusted to a size at which the ink in the nozzle 3031 is ejected.

  The damping pulse component of the drive signal includes a voltage drop. That is, the vibration damping operation of the piezoelectric element 3010 includes a suction operation. It is desirable that the suction operation of the vibration damping operation is executed within a period in which the ink level is displaced outward due to the vibration of the ink in the nozzle 3031. Thereby, a suction force can be efficiently applied to the ink in the nozzle 3031 and the ink can be efficiently damped.

  It is to be noted that the volume of ink droplets ejected from the nozzle 3031 is adjusted by adjusting the length of the period (standby period) from the pressing operation of the preliminary vibration operation to the suction operation of the main vibration operation through experiments by the inventors. Was found to be adjustable. Based on this, in the present embodiment, the control device 15 is capable of performing a plurality of ejection operations having different lengths of the standby period, and causing the piezoelectric element 3010 to perform one of the plurality of executable ejection operations. Let's select it as an action. In the example of FIG. 4, the length of the standby period is adjusted to be five times the half cycle of the natural vibration of the ink in the nozzle 3031. Hereinafter, the experiment will be described in detail, and then the operation for the control device 15 to generate the drive signal will be described.

  In addition, when measuring the length of the half cycle of the natural vibration, there is an inevitable measurement error. It is also conceivable that the amplitude of the natural vibration of the ink is attenuated with the lapse of time from the time when the preliminary vibration operation is completed, and the half cycle of the natural vibration is changed accordingly. Therefore, the “half cycle of natural vibration” itself includes some errors. In consideration of these, in this specification, “the length of the half cycle of the natural vibration” includes not only the theoretical value but also an error of about ± 10% with respect to the theoretical value.

Also, as shown in FIG. 4, the waveform of the drive signal may become dull depending on the signal transfer characteristics. In this specification, the length of a period shall be measured based on the voltage drop and the start time of a voltage rise.
<2-5> Experiment The inventors observed changes in the volume of ink droplets when the length of the waiting period was changed.

  In the experiment, even when the length of the standby period is changed, the flying speed of the ink droplet is adjusted so as not to change. The reason why the flying speed of the ink droplet is kept constant is that an appropriate range exists for the flying speed of the ink droplet from the viewpoint of the landing accuracy of the ink droplet. When the flying speed of the ink is low, the ink droplets are easily affected by the air flow, and the landing accuracy is lowered. On the contrary, when the flying speed of the ink is high, the length of the tail connected to the trailing edge of the ink droplet becomes longer and thinner depending on the speed. It becomes easy to decompose in the air into droplets. Since the small and light droplets are easily affected by the air flow, the landing accuracy also decreases in this case. For these reasons, it is desirable to maintain the flying speed of the ink droplets within an appropriate range. In this experiment, adjustment of the flying speed of the ink droplet is realized by adjusting the amplitude of the vibration operation. Specifically, the flying speed of the ink droplet was 5 m / s. As shown in the photograph of the behavior of the ink in FIG. 4, immediately after the ink is ejected, the ejected ink is connected to the ink in the nozzle by the tail. Thereafter, the tail is cut and the ejected ink is turned into droplets. In this specification, the “flying speed” refers to the speed of ink droplets that are in the process of being ink droplets and flying in the air.

FIG. 5 is an example of a measurement result of the volume of ink droplets. As shown in FIG. 5, there is some variation in the volume of ink droplets from nozzle to nozzle. In the experiment, the volume of each of the 150 ink droplets was measured, and an average value of these was calculated, and this was regarded as the volume of the ink droplet.
FIG. 6 is a diagram illustrating changes in the volume of ink droplets when the length of the standby period is changed. In this experiment, the amplitude of the preliminary vibration pulse component was set to 20% of the amplitude of the main vibration pulse component. The viscosity of the ink is 12 mPa · s. The flying speed of the ink droplet is adjusted to 5 m / s. In the figure, for reference, only one measurement result is illustrated when the amplitude of the preliminary vibration pulse component is 40% of the amplitude of the main vibration pulse component.

  The horizontal axis of FIG. 6 represents the length of the standby period as a multiple of the half period T of the natural vibration of the ink in the nozzle 3031. According to the figure, when the length of the standby period is adjusted to an odd multiple of the half period T of the natural vibration, there is a tendency that the ink is made smaller than when adjusted to an even multiple. For example, in the case of 3 times, the ink droplets are smaller than in the case of 2 times and 4 times in the vicinity. In the case of 5 times, the ink droplets are smaller than in the case of 4 times and 6 times in the vicinity.

Further, according to the figure, it can be seen that, even when the length of the standby period is an even multiple of the half period T of the natural vibration, the volume of the ink droplet changes when the multiple is changed.
Similarly, it can be seen that even when the length of the standby period is an odd multiple of the natural vibration half period T, the volume of the ink droplets changes when the multiple is changed. For example, when the case of 1 × is used as a reference, when the size is 3 ×, the ink can be made into small droplets, and when the size is 5 ×, the ink can be further made into small droplets. However, the larger the multiple, the smaller the ink droplets become. For example, in the case of 7 times, the volume of the ink droplet becomes larger than in the case of 5 times. Thus, when the length of the waiting period is increased by an odd multiple of the natural vibration half period T, the volume of the ink droplets decreases, but there is a tendency for the volume to increase after a certain multiple. .

FIG. 7 is a diagram in which the experimental results of FIG. 6 are arranged in the order of the volume of ink droplets. According to this, the volume of the ink droplet is a minimum of 4.52 pl and a maximum of 4.88 pl.
FIG. 8 is a diagram showing an error between the required ink amount and the ink application amount, where (a) shows a comparative example and (b) shows an example. In the inkjet apparatus of the comparative example, the length of the standby period is fixed (in this example, the multiple is 1 time). In the inkjet apparatus of the embodiment, the length of the standby period can be arbitrarily adjusted. In addition, two types of products produced using an inkjet device are assumed. The amount of ink necessary to form the functional layer of model A (required ink amount) is 46 pl, and the amount of ink necessary to form the functional layer of model B (required ink amount) is 30 pl. is there.

As shown in FIG. 8A, in the comparative example, the ink application amount (product of the volume of ink droplets and the number of droplets) in the case of model A is 46.8 pl. At this time, the error between the required ink amount and the ink application amount is 1.7%. In the case of model B, the amount of ink applied is 28.1 pl. At this time, the error between the required ink amount and the ink application amount is 6.3%.
On the other hand, as shown in FIG. 8B, in the embodiment, in the case of the model A, the volume of the ink droplet is 4.59 pl by setting the length of the standby period to three times the half cycle of the natural vibration. It is adjusted. At this time, the amount of ink applied is 45.9 pl. The error between the required ink amount and the ink application amount is 0.2%. In the case of model B, the volume of the ink droplet is adjusted to 4.88 pl by setting the length of the standby period to twice the half period of the natural vibration. At this time, the amount of ink applied is 29.3 pl. The error between the required ink amount and the ink application amount is 2.3%.

In this way, in the embodiment, the length of the waiting period can be arbitrarily adjusted, so that the volume of the ink droplet can be finely adjusted. As a result, the error between the required ink amount and the ink application amount can be reduced. can do.
Hereinafter, the reason why the volume of the ink droplet changes will be discussed with reference to FIG.
In FIG. 9, the drive signal a includes a preliminary vibration pulse component as a pulse component, and does not include the main vibration pulse component. The ink level is vibrated by the drive signal a.

  The drive signal b is a case where the length of the standby period is one time the half period T of the natural vibration. The pressing operation of the vibration operation is executed within a period in which the liquid level of the ink in the nozzle is displaced outward (time t3). That is, the direction of the pressing force by the pressing operation is the same as the direction of the displacement of the liquid level of the ink in the nozzle. Accordingly, the ink in the nozzle is assisted by the pressing operation and is smoothly discharged to the outside. The drive signal c is a case where the length of the standby period is twice the half period T of the natural vibration. The pressing operation of this vibration is executed within a period in which the ink level in the nozzle is displaced toward the ink chamber (time t4). That is, the direction of the pressing force by the pressing operation is opposite to the direction of the displacement of the liquid level of the ink in the nozzle. Therefore, the ink in the nozzle initially resists the pressing operation. However, after that, the ink in the nozzles is ejected to the outside with its displacement direction reversed without resisting the pressing operation. When the length of the waiting period is an even multiple of the half period T of the natural vibration, it is necessary to reverse the direction of ink displacement in the nozzles, so that a large pressing force is required (amplitude A2). Since such a large pressing force is applied, it is considered that the amount of ink pushed out from the nozzle increases, leading to an increase in the size of ink droplets. On the other hand, when the length of the waiting period is an odd multiple of the natural vibration half cycle T, the ink in the nozzles is smoothly ejected to the outside, so that the volume of the ink droplets is considered to be small. It is done.

  Further, even when the length of the waiting period is an odd multiple of the half period T of the natural vibration, the volume of the ink droplet changes depending on the multiple. The multiple of the drive signal b is 1 time. The multiple of the drive signal d is 5 times. The multiple of the drive signal e is 7 times. The vibration of the ink in the nozzle is started by a preliminary vibration operation and gradually attenuates with the passage of time. At the time of the pressing operation of the drive signal b (time t3), the amplitude of the ink vibration is kept relatively large. For this reason, when a pressing force is applied to the ink in the nozzle by the pressing operation of this vibration operation, the ink in the nozzle tends to be pushed out excessively. Further, at the time of the pressing operation of the drive signal e (time t9), the amplitude of ink vibration is attenuated. Therefore, it is necessary to relatively increase the amplitude A7 of the pressing operation of the main vibration operation. In this case, since a large pressing force is applied to the ink in the nozzle, the ink in the nozzle tends to be pushed out excessively. On the other hand, at the time of the pressing operation of the driving signal d (time t7), the amplitude of the vibration of the ink is attenuated from the time of the pressing operation of the driving signal b (time t3). It is not attenuated as much as the time of the pressing operation (time t9). Therefore, the amplitude A5 of the pressing operation of the vibration operation is smaller than the amplitude A1 and larger than the amplitude A7, and at this time, the ink in the nozzles is pushed out appropriately. For this reason, when the length of the waiting period is increased by an odd multiple of the half period T of the natural vibration, the volume of the ink droplets decreases and the volume tends to increase after a certain multiple. Conceivable.

  The same tendency was confirmed when the viscosity of the ink was 3.4 mPa · s and 8.5 mPa · s. According to the above principle, it is considered that the same tendency appears even if the structure of the ink jet head and the physical properties of the ink are changed. Therefore, it is considered that the same effect can be obtained with any viscosity, not limited to 3.4 mP · s, 8.5 mPa · s, and 12 mPa · s. It is effective in the range of at least 3 mPa · s to 13 mPa · s.

<2-6> Operation FIG. 10 is a diagram illustrating an example of a table stored in the storage unit in the control device. The table defines the product model and the waveform of the drive signal. The waveform of the drive signal is defined by the unit waveform and the number of repetitions. The unit waveform data represents a unit waveform as digital data, and is, for example, a data string in which several thousand pieces of 8-bit data indicating voltage values are arranged. The repetition count data indicates the number of repetitions of the unit waveform. The signal generation unit 154 sequentially samples 8-bit data in the unit waveform data, and sequentially converts the sampled data from digital to analog. Thereby, a unit drive signal based on the unit waveform data is generated. The signal generation unit 154 repeats this process as many times as indicated in the repetition count data. As a result, a drive signal in which the unit drive signal is repeated is generated. According to this table, when each of the models A, B, and C is produced, the length of the standby period of the drive signal is three times, two times, and five times the half cycle of the natural vibration.

  FIG. 11 is a flowchart showing the operation of the control device. The control device 15 is on standby until a model designation instruction is received from the operator (step S101: No). The model designation is instructed through the input means 152 in the product control device 15, for example. As the input means 152, for example, a touch panel, a keyboard, or the like can be used. If there is an instruction to specify the model (step S101: Yes), the control device 15 refers to the table stored in the storage unit 151 and selects the waveform data corresponding to the specified model (step S102).

  Next, the control device 15 is in a standby state until an application start instruction or a reset instruction is issued (step S103: No, step S104: No). If there is a reset instruction (step S104: Yes), the operation of the control device ends. If there is an instruction to start application (step S103: Yes), the control device 15 instructs the scanning control unit 213 to start scanning of the head unit 30 (step S105). The scanning control unit 213 drives the linear motors 204 and 205 according to instructions. In synchronization with this, the control device 15 initializes a variable i indicating the number of repetitions (step S106), and generates a unit drive signal based on the selected unit waveform data (step S107). The control device 15 repeats the generation of the unit drive signal until the number of times N indicated in the selected repetition number data is reached (No at Step S108, Step S109). Thereby, a drive signal is generated. When the number N has been reached (step S108: Yes), the control device 15 instructs the scanning control unit 213 to stop scanning the head unit 30 (step S110) and move the head unit 30 to the home position. (Step S111). Thus, the operation of the control device 15 ends.

<2-7> Summary As described above, the storage unit 151 stores waveform data that is the basis of a plurality of drive signals. Further, the length of the standby period of each drive signal is adjusted as appropriate. As a result, in this example, the length of the standby period of each drive signal is different from each other. Therefore, the control device 15 can execute a plurality of discharge operations with different standby periods. Further, the control device 15 selects one of a plurality of waveform data stored in the storage unit 151 and generates a drive signal based on the selected waveform data. Therefore, the control device 15 selects one of a plurality of executable discharge operations as a discharge operation that causes the piezoelectric element 3010 to execute. As described above, since a plurality of ejection operations having different lengths of the standby period can be executed, the ink application amount can be adjusted more finely.

<3> Embodiment 2
The ink jet apparatus according to Embodiment 1 can be used for manufacturing electronic devices such as organic EL elements and TFTs. In Embodiment 2, a case where an inkjet apparatus is used for manufacturing an organic EL display panel which is an example of an electronic device will be described.
<3-1> Structure of Organic EL Display Panel FIG. 12 is a partial cross-sectional view of the organic EL display panel according to the embodiment of the present invention. The organic EL display panel 100 includes a substrate 101, a TFT layer 102, a feeding electrode 103, an insulating film 104, an anode 106, a partition layer 107, a hole injection layer 109, a hole transport layer 110, an organic light emitting layer 111, and an electron transport layer 112. The electron injection layer 113 and the cathode 114 are provided.

A stacked structure of the anode 106, the hole injection layer 109, the hole transport layer 110, the organic light emitting layer 111, the electron transport layer 112, the electron injection layer 113, and the cathode 114 corresponds to the organic EL element 115. In addition, the hole injection layer 109, the hole transport layer 110, the organic light emitting layer 111, the electron transport layer 112, and the electron injection layer 113 correspond to functional layers, respectively.
The substrate 101 is a back substrate in the organic EL display panel 100. The TFT layer 102 has a drive circuit for driving the organic EL element 115 by an active matrix method, and various wirings for supplying signals and power from the outside to the drive circuit. The drive circuit includes a TFT and a capacitor. The power supply electrode 103 is an electrode for supplying power from the drive circuit to the organic EL element 115. The insulating film 104 is provided in order to flatten a step generated by the TFT layer 102 and the power supply electrode 103. The insulating film 104 has a contact hole 118 for burying a part of the anode 106. A part of the anode 106 is connected to the power supply electrode 103 in the contact hole 118.

  When a voltage is applied between the anode 106 and the cathode 114, holes are supplied from the anode 106 to the organic light emitting layer 111 through the hole injection layer 109 and the hole transport layer 110, and from the cathode 114 to the electron injection layer. Electrons are supplied to the organic light-emitting layer 111 through 113 and the electron transport layer 112. The organic light emitting layer 111 emits light with recombination of holes and electrons. The hole transport layer 110 and the organic light emitting layer 111 are disposed in the opening 117 formed in the partition layer 107. The hole injection layer 109, the electron transport layer 112, the electron injection layer 113, and the cathode 114 are connected between adjacent subpixels beyond the partition layer 107.

  FIG. 13 is a plan view showing the structure of the partition wall layer 107. The partial cross-sectional view of FIG. 12 corresponds to the A-A ′ cross-sectional view of FIG. 13. The partition layer 107 has a plurality of openings 117 arranged in the XY direction. An organic EL element 115 is disposed in each opening 117. Each of the organic EL elements 115 corresponds to a subpixel. The organic EL element 115 includes an organic EL element 115R that emits red light, an organic EL element 115G that emits green light, and an organic EL element 115B that emits blue light. Three sub-pixels of the organic EL elements 115R, 115G, and 115B constitute one pixel.

<3-2> Specific materials for each layer (TFT substrate)
As the material of the substrate 101, for example, glass or plastic can be used. Examples of the glass include alkali-free glass, soda glass, non-fluorescent glass, phosphate glass, borate glass, and quartz. The plastic includes, for example, acrylic resin, styrene resin, polycarbonate resin, epoxy resin, polyethylene, polyester, polyimide, silicone resin, and the like.

  As a material of the insulating film 104, for example, a resin material or an inorganic material can be used. As the resin material, for example, a photosensitive material can be used. Examples of such photosensitive materials include acrylic resins, polyimide resins, siloxane resins, and phenol resins. Examples of the inorganic material include SiN (silicon nitride), SiON (silicon oxynitride), SiO (silicon oxide), and AlO (aluminum oxide). The insulating film 104 may be formed only from a resin material, or may be formed from both a resin material and an inorganic material.

(anode)
In the case of a top emission type organic EL display panel, a light reflective conductive material can be used as the material of the anode 106. In the case of a bottom emission type organic EL display panel, a light-transmitting conductive material can be used as the material of the anode 106. Examples of the light reflective conductive material include Al (aluminum), aluminum alloy, AG (silver), APC (silver, palladium, copper alloy), ARA (silver, rubidium, gold alloy), and MoCR (molybdenum). And an alloy of chromium and NiCR (alloy of nickel and chromium), Mo (molybdenum), and MoW (alloy of molybdenum and tungsten). Examples of the light transmissive conductive material include indium tin oxide (ITO) and indium zinc oxide (IZO). The anode 2 may have a multilayer structure in which a layer of a conductive material having light reflectivity and a layer of a light transmissive conductive material are stacked.

(Partition layer)
As a material of the partition layer 107, for example, an electrically insulating resin material can be used. As the resin material, for example, a photosensitive material can be used. Examples of such photosensitive materials include acrylic resins, polyimide resins, siloxane resins, and phenol resins.

(Hole injection layer)
As a material of the hole injection layer 109, a known inorganic material and organic material can be used. Examples of the inorganic material include oxides of metals such as silver (Ag), molybdenum (Mo), chromium (Cr), vanadium (V), tungsten (W), nickel (Ni), and iridium (Ir). . Examples of organic materials include conductive polymer materials such as PEDOT (mixture of polythiophene and polystyrene sulfonic acid), or triazole derivatives, oxadiazole derivatives, imidazole derivatives, polyarylalkane derivatives, phenylenediamine derivatives, arylamine derivatives. , Oxazole derivatives, styrylanthracene derivatives, fluorenone derivatives, stilbene derivatives, polyphyrin compounds, aromatic tertiary amine compounds, styrylamine compounds, and other low-molecular organic compounds, polyfluorenes and derivatives thereof, polyarylamines and derivatives thereof, etc. A high molecular compound is mentioned.

(Hole transport layer)
As a material for the hole transport layer 110, a known organic material can be used. Known organic materials include, for example, triazole derivatives, oxadiazole derivatives, imidazole derivatives, polyarylalkane derivatives, pyrazoline derivatives and pyrazolone derivatives, phenylenediamine derivatives, arylamine derivatives, amino-substituted chalcone derivatives, oxazole derivatives, styrylanthracene derivatives. Fluorenone derivatives, hydrazone derivatives, stilbene derivatives, porphyrin compounds, aromatic tertiary amine compounds and styrylamine compounds, butadiene compounds, polystyrene derivatives, hydrazone derivatives, triphenylmethane derivatives, and tetraphenylbenzine derivatives.

(Organic light emitting layer)
A known organic material can be used as the material of the organic light emitting layer 111. Known organic materials include, for example, oxinoid compounds, perylene compounds, coumarin compounds, azacoumarin compounds, oxazole compounds, oxadiazole compounds, perinone compounds, pyrrolopyrrole compounds, naphthalene compounds, anthracene compounds, fluorene compounds, fluoranthene compounds, tetracene compounds. , Pyrene compounds, coronene compounds, quinolone compounds and azaquinolone compounds, pyrazoline derivatives and pyrazolone derivatives, rhodamine compounds, chrysene compounds, phenanthrene compounds, cyclopentadiene compounds, stilbene compounds, diphenylquinone compounds, styryl compounds, butadiene compounds, dicyanomethylenepyran compounds, Dicyanomethylenethiopyran compound, fluorescein compound, pyrylium compound, thiapyrylium Products, serenapyrylium compounds, telluropyrylium compounds, aromatic aldadiene compounds, oligophenylene compounds, thioxanthene compounds, anthracene compounds, cyanine compounds, acridine compounds, metal complexes of 8-hydroxyquinoline compounds, metal complexes of 2-bipyridine compounds, Schiff Examples thereof include fluorescent substances such as a complex of a salt and a group III metal, an oxine metal complex, and a rare earth complex.

(Electron transport layer)
As a material of the electron transport layer 112, a known organic material or inorganic material can be used. For example, barium, phthalocyanine, or lithium fluoride can be used.
(Electron injection layer)
As a material of the electron injection layer 113, a known organic material or inorganic material can be used. For example, use nitro-substituted fluorenone derivatives, thiopyrandioxide derivatives, diphequinone derivatives, perylene tetracarboxyl derivatives, anthraquinodimethane derivatives, fluorenylidenemethane derivatives, anthrone derivatives, oxadiazole derivatives, perinone derivatives, quinoline complex derivatives be able to.

(cathode)
In the case of a top emission type organic EL display panel, a light-transmitting conductive material can be used as the material of the cathode 114. In the case of a bottom emission type organic EL display panel, a light-reflective conductive material can be used as the material of the cathode 114. As the conductive material having light reflectivity and the conductive material having light transmittance, the materials listed in the column of the material of the anode 106 can be used.

<3-3> Manufacturing Method of Organic EL Display Panel Next, an outline of a manufacturing method of the organic EL display panel will be described with reference to FIGS. 14 and 15, and subsequently, the function of the organic EL display panel will be described with reference to FIG. The coating process when the layer is formed by a coating method will be described.
(Outline)
A TFT layer 102 and a power supply electrode 103 are formed on the substrate 101 (FIG. 14A).

Next, an insulating film 104 is formed on the TFT layer 102 and the power supply electrode 103 (FIG. 14B). The insulating film 104 has a contact hole 118 for partially exposing the power supply electrode 103. Thereby, the TFT substrate 105 is formed.
Next, the anode 106 is formed on the TFT substrate 105, and the hole injection layer 109 is formed on the anode 106 (FIG. 14C). The anode 106 is formed, for example, by depositing a conductive material on the TFT substrate 105 using a vacuum vapor deposition method or a sputtering method and patterning the conductive material using an etching method. The hole injection layer 109 is formed, for example, by depositing a hole injection material on the anode 106 using a vacuum evaporation method or a sputtering method.

Subsequently, a partition layer 107 is formed on the hole injection layer 109 (FIG. 14D). The partition layer 107 is formed by, for example, applying a photosensitive material on the hole injection layer 109, pattern-exposing the photosensitive material using a photolithography method, and then developing the photosensitive material. Thus, the partition layer 107 having the opening 117 can be formed.
Next, ink for forming a hole transport layer is applied into the opening 117 of the partition wall layer 107 using the inkjet head 301 (FIG. 14E). This ink contains a hole transport material for constituting the hole transport layer 110 and a solvent for dissolving or dispersing the hole transport material.

Subsequently, the hole transport layer 110 is formed by evaporating the solvent in the ink in the opening 117 (FIG. 15A).
Next, ink for forming the organic light emitting layer is applied to the opening 117 of the partition wall layer 107 using the inkjet head 301 (FIG. 15B). This ink includes an organic light emitting material for constituting the organic light emitting layer 111 and a solvent for dissolving or dispersing the organic light emitting material.

Subsequently, the organic light emitting layer 111 is formed by evaporating the solvent in the ink in the opening 117 (FIG. 15C).
Further, an electron transport layer 112 is formed on the organic light emitting layer 111 and the partition wall layer 107, an electron injection layer 113 is formed on the electron transport layer 112, and a cathode 114 is formed on the electron injection layer 113 (FIG. 15D). )). The electron transport layer 112, the electron injection layer 113, and the cathode 114 are formed using, for example, a vacuum evaporation method or a sputtering method.

(Coating process)
In the above manufacturing method, the hole transport layer 110 and the organic light emitting layer 111 which are examples of the functional layer are formed by a coating method in which ink is applied. Hereinafter, a coating process when forming the organic light emitting layer 111 will be described. In the coating process, the ink jet apparatus described in the first embodiment is used.

FIG. 16 is a diagram showing the positional relationship between the opening of the partition wall layer and the head portion.
The inkjet head 301 has a plurality of nozzles 3031 for ejecting ink at a constant pitch. In the present embodiment, the inkjet head 301 has six nozzles 3031. Of these, five nozzles 3031 pass over the opening 117 of one row arranged in the Y direction. In the figure, the opening 117 includes an opening 117R for forming a red organic light emitting layer, an opening 117G for forming a green organic light emitting layer, and an opening 117B for forming a blue organic light emitting layer. including.

  First, ink for forming a red organic light emitting layer is applied to the opening 117R. In this coating process, while the inkjet head 301 is scanned in the Y direction, ink for forming a red organic light emitting layer is ejected when the inkjet head 301 is positioned above the opening 117R. The drive signal for ejecting ink is as described in the first embodiment. Next, ink for forming a green organic light emitting layer is applied to the opening 117G. Finally, ink for forming a blue organic light emitting layer is applied to the opening 117B. In addition, the order of application | coating of each ink for forming a red, green, and red organic light emitting layer is not limited to this.

<4> Modifications As described above, the embodiment of the present invention has been specifically described, but the present invention is not limited to the above embodiment. For example, the following modifications may be adopted.
FIG. 17 is a diagram for explaining a modified example of the preliminary vibration operation. In this modification, the preliminary vibration operation is configured only by the pressing operation. Thus, if the preliminary vibration operation includes the pressing operation, the vibration of the ink can be started. There is also a waiting period from the pressing operation of the preliminary vibration operation to the suction operation of the main vibration operation.

  FIG. 18 is a diagram for explaining a modified example of the vibration operation. In this modification, the length of the period from the suction operation of the main vibration operation to the pressing operation of the main vibration operation is three times the half cycle of the natural vibration of the ink in the nozzle. In this case, the pressing operation of the vibration operation is executed within a period in which the liquid level of the ink in the nozzle is displaced outward. As a result, it is possible to efficiently apply a pressing force to the ink in the nozzle, and to efficiently eject the ink. In addition, in this modification, although it is 3 times, it is not restricted to this, What is necessary is just to be an odd number times like 5 times and 7 times. Further, since the pressing operation of the vibration operation only needs to be performed within a period in which the liquid level of the ink in the nozzle is displaced toward the outside, it does not need to be an odd multiple. For example, when the length of the period from the suction operation to the pressing operation is P, the period during which the liquid level of the ink in the nozzle is displaced toward the outside is determined as long as the following conditions are satisfied. Can be run in. However, n is an integer greater than or equal to 1, and T is the length of the half cycle of the natural vibration of the ink in a nozzle.

(2n−1.5) T ≦ P ≦ (2n−0.5) T
FIG. 19 is a diagram for explaining a modified example of the pulse component. In the embodiment, the piezoelectric element performs a preliminary vibration operation, a main vibration operation, and a vibration damping operation. In addition to this, the piezoelectric element may execute a vibration operation for preventing sticking. For example, there is a case where the ink is not applied over a long period of time, for example, after the ink is applied to one base substrate and before the ink is applied to another base substrate. In this case, if the liquid level of the ink in the nozzle is stationary, the concentration of the functional material near the liquid level increases due to evaporation of the solvent near the liquid level, and the functional material is solidified on the inner peripheral surface of the nozzle. May stick. Therefore, the ink sticking can be prevented by vibrating the ink in the nozzle within a range where the ink in the nozzle does not discharge. Specifically, as shown in FIG. 19, the drive signal includes a vibration pulse component for preventing sticking in addition to the preliminary vibration pulse component, the main vibration pulse component, and the damping vibration pulse component. Thereby, the vibration operation for preventing sticking can be realized. Further, the amplitude of the vibration operation for preventing sticking may be the same as the amplitude of the preliminary vibration operation. As a result, it is possible to guarantee vibration within a range where ink in the nozzles is not ejected.

In the above embodiment, an example in which the head unit applies one type of ink has been described, but the present invention is not limited to this. The head unit may apply a plurality of types of ink. FIG. 20 is a functional block diagram of an inkjet apparatus according to a modification.
The head unit 2030 of the inkjet device 2000 includes ejection control units 300R, 300G, and 300B and piezoelectric elements 3010R, 3010G, and 3010B. The discharge controller 300R and the piezoelectric element 3010R are provided in an inkjet head for forming a red organic light emitting layer. The ejection control unit 300G and the piezoelectric element 3010G are provided in an inkjet head for forming a green organic light emitting layer. The ejection control unit 300B and the piezoelectric element 3010B are provided in an inkjet head for forming a blue organic light emitting layer.

The control device 2015 includes a signal generation unit 2154. The signal generation unit 2154 generates drive signals for red, green, and blue, respectively.
Appropriate amount of red, green, and blue ink applied due to differences in film thickness of red, green, and blue organic light-emitting layers and differences in density of red, green, and blue inks May be different. In such a case, it is desirable to finely adjust the amount of each ink applied, and as a result, the length of the waiting period of the drive signals for red, green, and blue may differ.

  FIG. 21 is a diagram illustrating an example of a table stored in a storage unit in the control device. The table defines the ink type (color) and the waveform of the drive signal. According to this table, the length of the standby period of the drive signals for red, green, and blue is three times, two times, and five times the half cycle of the natural vibration. As shown in FIG. 16, the openings 117R, 117G, and 117B are present at different positions in the scanning direction of the head unit. Further, the red, green, and blue inkjet heads are present at different positions in the scanning direction of the head unit. The timing of ejecting each color ink is determined by the balance of these positions. As a result, as shown in FIG. 21, the timing of the pressing operation of the main vibration operation may be different between the red, green, and blue drive signals.

  FIG. 22 is a flowchart showing the operation of the control device according to the modification. The control device 2015 is on standby until there is an application start instruction from the operator (step S201: No). If there is an instruction to start application (step S201: Yes), the control device 2015 instructs the scanning control unit 213 to start scanning of the head unit 2030 (step S202). The scanning control unit 213 drives the linear motors 204 and 205 according to instructions. In synchronization with this, the controller 2015 initializes a variable i indicating the number of repetitions (step S203), and each unit drive signal for red, green and blue is based on the unit waveform data for red, green and blue. Is generated (step S204). The control device 2015 repeats the generation of each unit drive signal until the number N of times indicated in the selected repetition count data is reached (step S205: No, step S206). Thereby, drive signals for red, green, and blue are generated. When the number N has been reached (step S205: Yes), the control device 2015 instructs the scanning control unit 213 to stop scanning the head unit 2030 (step S207) and move the head unit 2030 to the home position. (Step S208). Thus, the operation of the control device 2015 is completed. In this case, application of each ink for forming red, green, and blue organic light emitting layers is completed in one scan.

As described above, since the length of the standby period is different between the driving signals for red, green, and blue, it is possible to appropriately adjust the application amounts of the red, green, and blue inks.
In this modification, the organic light emitting layers of three colors of red, green, and blue are formed using three inkjet heads, but the present invention is not limited to this. For example, four color organic light emitting layers may be formed using four ink jet heads. Moreover, although the red, green, and blue organic light emitting layer is illustrated as a functional layer formed using a separate inkjet head in the said modification, it is not restricted to this. For example, the functional layer formed using separate inkjet heads may be an organic light emitting layer and a hole transport layer. Furthermore, in the said modification, although the model of a product is one type, it is not restricted to this. There may be multiple types of products.

  In the said embodiment, although the case where an inkjet apparatus is applied to manufacture of an organic electroluminescent display device is illustrated, this invention is not limited to this. As long as the electronic device has a functional layer that can be formed by a coating method, the inkjet apparatus of Embodiment 1 can be applied. For example, the TFT includes a gate electrode, a gate insulating film, a semiconductor layer, a source electrode, and a drain electrode. In recent years, it has been proposed to form a semiconductor layer by a coating method. When the semiconductor layer is formed by a coating method, an ink containing a semiconductor material constituting the semiconductor layer and a solvent for dissolving or dispersing the semiconductor material is prepared, and the prepared ink is applied to the base substrate and applied. It is sufficient to evaporate the ink solvent. The ink jet apparatus of the first embodiment can be applied to this ink application.

  The present invention is applicable to industrial and household inkjet devices.

15, 2015 Control device 20 Inkjet table 30, 2030 Head unit 40 Ink 100 Organic EL display panel 101 Substrate 102 TFT layer 103 Feed electrode 104 Insulating film 105 TFT substrate 106 Anode 107 Partition layer 109 Hole injection layer 110 Hole transport layer 111 Organic light emitting layer 112 Electron transport layer 113 Electron injection layer 114 Cathode 115, 115B, 115G, 115R Organic EL element 117, 117B, 117G, 117R Opening 118 Contact hole 150 CPU
151 Storage means 152 Input means 153 Display means 154, 2154 Signal generation unit 200 Base 201A, 201B, 202A, 202B Stand 203A, 203B Guide shaft 204, 205 Linear motor 210 Gantry part 211 Guide groove 213 Scanning control part 220 Moving body 221 Servo motor 300, 300B, 300G, 300R Discharge control unit 301 Inkjet head 301e Ink chamber 301i Nozzle plate 301g Reservoir 301f Channel 301c Outer peripheral wall 301h Vibration plate 301d Partition wall 302 Support unit 1000, 2000 Inkjet devices 3010, 3010B, 3010G, 3010R Piezoelectric Element 3011, 3012 Electrode 3013 Piezoelectric layer 3031 Nozzle

Claims (6)

An ink jet head including an ink chamber for containing ink, a nozzle communicating with the ink chamber, and an actuator for vibrating the ink in the nozzle;
A preliminary vibration operation for vibrating the ink in the nozzle in a range where ink is not discharged from the nozzle, and a main vibration operation for vibrating the ink in the nozzle in a range where ink is discharged from the nozzle. A controller that causes the actuator to perform a series of discharge operations,
The preliminary vibration operation includes a pressing operation of pressing the ink in the nozzle toward the outside,
The main vibration operation includes a suction operation for sucking the ink in the nozzle toward the ink chamber, and the ink sucked in the period in which the sucked ink is displaced outward due to vibration. And pressing operation to press toward
The controller is
A plurality of discharge operations having different lengths from the pressing operation of the preliminary vibration operation to the suction operation of the main vibration operation can be performed, and one of the executable discharge operations can be performed on the actuator. Select as the discharge operation to be executed,
Inkjet device. The actuator includes a piezoelectric element,
The controller is
A storage unit storing waveform data indicating a waveform of a drive signal for driving the piezoelectric element corresponding to each of the plurality of ejection operations;
A selection unit for selecting one of the waveform data stored in the storage unit;
A signal generation unit that generates a drive signal for driving the piezoelectric element based on the waveform data selected by the selection unit,
The ink jet apparatus according to claim 1. A method of manufacturing an electronic device having a functional layer,
Applying an ink containing a functional material constituting the functional layer and a solvent for dissolving or dispersing the functional material, and evaporating the solvent to form the functional layer;
The application of the ink is performed using the ink jet apparatus according to claim 1 or 2.
Electronic device manufacturing method. A first inkjet head including an ink chamber for containing ink, a nozzle communicating with the ink chamber, and an actuator for vibrating the ink in the nozzle;
A second inkjet head including an ink chamber for containing ink, a nozzle communicating with the ink chamber, and an actuator for vibrating the ink in the nozzle;
A preliminary vibration operation for vibrating the ink in the nozzle in a range where ink is not discharged from the nozzle, and a main vibration operation for vibrating the ink in the nozzle in a range where ink is discharged from the nozzle. A controller that causes the actuators of the first and second inkjet heads to perform a series of first and second ejection operations, respectively,
The preliminary vibration operation in the first and second ejection operations includes a pressing operation for pressing the ink in the nozzles toward the outside,
The main vibration operation in the first and second ejection operations includes a suction operation for sucking ink in the nozzle toward the ink chamber, and a period in which the sucked ink is displaced outward by vibration. A pressing operation for pressing the sucked ink toward the outside,
The length of the period from the pressing operation of the preliminary vibration operation in the first discharge operation to the suction operation of the main vibration operation is adjusted to a first time length, and the preliminary vibration in the second discharge operation A length of a period from the pressing operation of the operation to the suction operation of the main vibration operation is adjusted to a second time length different from the first time length;
Inkjet device. The actuators of the first and second inkjet heads include piezoelectric elements,
The controller is
Corresponding to the first ejection operation, the first waveform data indicating the waveform of the first drive signal for driving the piezoelectric element included in the first inkjet head, and the second ejection operation. A corresponding storage unit storing second waveform data indicating a waveform of a second drive signal for driving the piezoelectric element included in the second inkjet head;
The first drive signal is generated based on the first waveform data stored in the storage unit, and the second drive signal is generated based on the second waveform data stored in the storage unit A signal generation unit for generating
The ink jet apparatus according to claim 4. A method of manufacturing an electronic device having a functional layer,
Applying an ink containing a functional material constituting the functional layer and a solvent for dissolving or dispersing the functional material, and evaporating the solvent to form the functional layer;
Application of the ink is performed using the ink jet device according to claim 4 or 5.
Electronic device manufacturing method.