JP2006021146A - Ink applying apparatus and display manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ink applying apparatus in which the discharge amount of ink can easily be adjusted accurately and to provide a display manufacturing method. <P>SOLUTION: A discharge signal generating part 27 for selecting at least one nozzle from a plurality of nozzles arranged in a coating head 15 when a predetermined adequate ink amount is not equal to the total amount of the ink to be discharged from the plurality of nozzles and for adjusting the amount of the ink to be discharged from the selected nozzles so that the adequate ink amount is equal to the total amount of the ink to be discharged from the selected nozzles is arranged in a control part 20 of this ink applying apparatus together with a switching circuit 34 and a resistance dividing circuit 35. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an ink application device that ejects ink toward an object, and a display device manufacturing method that forms pixels using the ink, thereby manufacturing a display device such as a display.

  In manufacturing a display device such as an organic EL (Electro Luminescence) display, ink that is a light emitting layer material is ejected, and pixels are formed using this ink.

  As an example of such an ink application method, there is a method (hereinafter referred to as “I / J method” as appropriate) in which ink is made into fine droplets and ejected toward an object such as a substrate (hereinafter referred to as “I / J method” as appropriate). For example, see Patent Document 1).

  The above organic EL display is required to have uniform brightness without causing luminance unevenness in the entire display area.

  When the ink is applied by the I / J method, the light emitting layer needs to have a uniform film thickness in order to make the brightness uniform. For this reason, the plurality of nozzles provided in the I / J head need to be uniform. The total amount of ink ejected from each needs to be uniform.

  Conventionally, when the total amount of ink is made uniform, the amount of ink discharged (application amount) from each of the plurality of nozzles is made uniform. The details will be described below.

  First, a discharge amount range that can be reduced to a level where the luminance unevenness cannot be recognized, and a correspondence relationship between the voltage applied to the actuator for discharging ink from the nozzles and the ink discharge amount are obtained in advance.

  Next, ink is applied to glossy paper by applying a voltage to the actuator, the droplet diameter is determined by total image recognition, and the average discharge amount for each nozzle is determined by converting the droplet diameter to the discharge amount. .

  Next, the correction value of the voltage applied to each actuator is obtained so that the discharge amount falls within the discharge amount range. The voltage correction value is obtained based on the correspondence relationship between the applied voltage and the ink ejection amount.

Next, the corrected voltage is applied to the actuator, and the average discharge amount of each nozzle is made uniform.
JP 2002-221617 A

  However, in order to reduce the luminance unevenness to an extent where it cannot be recognized, it is necessary to set the difference in the average discharge amount between the nozzles to a very low value of ± 2.5% or less.

  In addition, it is difficult to make the difference in the average discharge amount equal to or less than the above value due to the processing accuracy and deterioration state of the nozzle, the variation in actuator characteristics, the presence of foreign matter, and the like.

  Furthermore, in some cases, replacement of parts, cleaning of parts, and adjustment of parts need to be executed again, resulting in an increase in human costs and time costs.

  For example, although the actual application time is only a few minutes, the adjustment time is several hours when inks of three colors of red, green and blue are used.

  In view of such circumstances, it is an object of the present invention to provide an ink application device and a display device manufacturing method capable of easily and accurately adjusting an ink discharge amount.

  The present invention according to claim 1 is an ink coating apparatus that ejects ink droplets from a plurality of nozzles, and includes an appropriate ink amount that is a predetermined appropriate amount of ink, and a plurality of nozzles. When the total amount of ink discharged, which is the total amount of ink discharged, is not the same, the nozzle selection means for selecting at least one nozzle from the plurality of nozzles, the appropriate ink amount, and the total ink discharge amount are the same Thus, the gist of the present invention is to have a discharge amount adjusting means for adjusting the discharge amount of ink at the selected nozzle.

  According to a second aspect of the present invention, in the first aspect of the present invention, the ink droplets are ejected by an actuator, and the nozzle selection means determines the magnitude relationship of the ejection amount of the ink in each of the plurality of nozzles. The gist is to select a nozzle based on at least one of data shown, processing data at the time of manufacturing a plurality of nozzles, and data on actuator characteristics.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, the ink droplets are ejected by an actuator, and the ejection amount adjusting means is based on the ink ejection amount from each of the plurality of nozzles. The total amount of ink discharged is calculated, and the amount of power supplied to the actuator is corrected based on the total amount of ink discharged and data indicating the correspondence between the power supplied to the actuator and the amount of ink discharged in advance. The gist is to adjust the amount of ink discharged from the selected nozzle by supplying an amount of power to the actuator.

  According to a fourth aspect of the present invention, there is provided a method of manufacturing a display device in which ink droplets are ejected from a plurality of nozzles and pixels are formed by the ejected ink. Nozzle selection that selects at least one nozzle from a plurality of nozzles when the total amount of ink discharged, which is the total amount, is not the same as the required amount of ink, which is the amount of ink necessary to properly form pixels The gist of the invention is to include a step, and a discharge amount adjustment step of adjusting the ink discharge amount at the selected nozzle so that the total ink discharge amount and the required ink amount are the same.

  According to a fifth aspect of the present invention, in the fourth aspect of the present invention, the ink droplets are ejected by an actuator, and in the nozzle selection step, the magnitude relationship of the amount of ink ejected from each of the plurality of nozzles. The gist is to select a nozzle based on at least one of data indicating the above, processing data at the time of manufacturing a plurality of nozzles, and data relating to actuator characteristics.

  According to a sixth aspect of the present invention, in the invention according to the fourth or fifth aspect, the ink droplets are ejected by an actuator, and in the ejection amount adjusting step, the ejection amount of the ink at each of the plurality of nozzles. The total amount of ink discharged from the ink is calculated, and the amount of power supplied to the actuator is corrected based on the total amount of ink discharged and the data indicating the correspondence between the power supplied to the actuator and the amount of ink discharged in advance. The gist is to adjust the amount of ink discharged from the selected nozzle by supplying a predetermined amount of electric power to the actuator.

  According to the present invention, it is possible to provide an ink application device and a display device manufacturing method capable of easily and accurately adjusting an ink discharge amount even when there is a variation in nozzle processing accuracy.

Hereinafter, the ink coating device and the display device manufacturing method of the present invention will be described with reference to the drawings.
It should be noted that the following examples are merely illustrative of the present invention and do not limit the scope of the present invention. Accordingly, those skilled in the art can employ various embodiments including each or all of these elements, and these embodiments are also included in the scope of the present invention.
Further, in all drawings for explaining the following embodiments, the same reference numerals are given to the same elements, and repeated explanation thereof is omitted.

FIG. 1 is a perspective view of an ink coating apparatus 1 according to an embodiment of the present invention.
The ink application device 1 is for manufacturing a display device such as an organic EL display, and includes an ink application box 2 and an ink supply box 3. The ink application box 2 and the ink supply box 3 are adjacent to each other. Are both fixed to the upper surface of the gantry 4.

  Inside the ink application box 2, a Y-axis direction slide plate 5, a Y-axis direction moving table 6, an X-axis direction moving table 7, and a substrate holding table 8 are stacked.

  The Y-axis direction slide plate 5 is fixed to the gantry 4, and at least one groove is provided on the surface in the Y-axis direction.

  On the other hand, the Y-axis direction moving table 6 includes a protruding mechanism (not shown) for moving along a groove formed in the Y-axis direction slide plate 5, and the Y-axis direction moving table 6 is fitted into the groove to fit the Y-axis. The direction can be moved.

  Also, at least one groove is provided in the X-axis direction on the surface of the Y-axis direction moving table 6. Accordingly, the X-axis direction moving table 7 can also move in the X-axis direction by fitting the protrusion mechanism into the groove. Therefore, the Y-axis direction moving table 6 slides in the ± Y direction, and the X-axis direction moving table 7 slides in the ± X direction.

  The substrate holding table 8 includes a substrate suction mechanism or a substrate gripping mechanism 10, and the substrate 9 is closely fixed on the substrate holding table 8 using the substrate suction mechanism or the substrate gripping mechanism 10. Here, the substrate suction mechanism is, for example, a rubber sucker, a suction pump, or the like, and the substrate gripping mechanism 10 in this embodiment is a U-shaped sandwiching bracket or the like.

  Furthermore, the Y-axis direction moving table 6 and the X-axis direction moving table 7 include a correction mechanism that keeps the ink application direction (Y direction) and the movement direction of the Y-axis direction movement table 6 parallel, an ink application direction, and an X A correction mechanism that maintains the movement direction of the axial movement table 7 at a right angle, that is, a θ direction correction mechanism is provided.

  The θ direction correction mechanism in the present embodiment is composed of a rotating disk having a flat surface. By providing this on the lower surface or interlayer of the Y axis direction moving table 6 or the X axis direction moving table 7, the rotation in the θ direction is performed. Allowing movement and keeping both parallel or orthogonal.

  Further, inside the ink application box 2, a set of columns 11 is erected on both sides of the Y-axis direction slide plate 5 in a direction perpendicular to the groove formed in the Y-axis direction slide plate 5.

  An X-axis direction slide plate 12 is horizontally mounted on the column 11. An application head unit 13 for discharging ink onto the surface of the substrate 9 is suspended from the X-axis direction slide plate 12 so as to be slidable in the X-axis direction by the application head unit gripping member 14. By providing the X-axis direction slide plate 12, the application head unit 13 can be moved in a direction orthogonal to the ink pattern application direction.

  A coating head 15 is provided at the tip of the coating head unit 13 and receives ink supplied from the ink tank 17 through a pipe. The ink tank 17 is further connected to an ink supply tank 18 so that ink can be supplied from the ink supply tank 18 at all times.

  The coating head unit 13 is provided with a vertical movement mechanism 16 that can move up and down in a direction perpendicular to the surface of the substrate 9. Thereby, the distance between the coating head 15 and the substrate 9 can be set to a desired interval.

  In addition to these mechanisms, a head maintenance unit 19 for cleaning ink clogging of the nozzles of the application head 15 is provided inside the ink application box 2. The head maintenance unit 19 is disposed on the extended line in the sliding direction of the X-axis direction slide plate 12 at a position separated from the substrate 9, and moves the coating head unit 13 to the end of the X-axis direction slide plate 12. By arranging the head maintenance unit 19 at the upper part, clogging of the nozzle holes can be automatically cleaned.

  Note that drive control and correction control of the Y-axis direction moving table 6, the X-axis direction moving table 7, the X-axis direction slide plate 12, the vertical movement mechanism 16, and the like are performed by the control unit 20. The controller 20 is provided inside the gantry 4, and the amount of ink ejected from the coating head 15 is also controlled by the controller 20.

FIG. 2 is a schematic diagram of the coating head 15 of FIG.
The coating head 15 includes an actuator (piezoelectric element) 21, a diaphragm 22, an ink chamber 23, and a nozzle 25. In the drawing, only three actuators 21, ink chambers 23 and nozzles 25 are shown for easy explanation.

  The actuator 21 is bonded to the diaphragm 22 and contracts when a voltage is applied from an electrode (not shown) to move the diaphragm 22 upward. At this time, the pressure in the ink chamber 23 becomes negative, and the ink 24 is replenished into the ink chamber 23 from a flow path (not shown).

  Thereafter, when the applied voltage returns to zero, the diaphragm 22 returns to the original state, the ink chamber 23 is compressed, and the droplet 26 is ejected from the nozzle 25.

  FIG. 3 is a block diagram showing a configuration of the control unit 20 of FIG. In this figure, for ease of explanation, the Y-axis direction moving table 6, the X-axis direction moving table 7, the X-axis direction sliding plate 12, the up-and-down moving mechanism 16 and the like are controlled. Description is omitted.

  The control unit 20 includes a discharge signal generation unit 27, a stage position signal storage unit 28, a discharge permission signal generation unit 29, a coating pattern signal storage unit 30, a nozzle processing data storage unit 31, an actuator characteristic data storage unit 32, and correspondence data. A storage unit 33, a switching circuit 34, and a resistance voltage dividing circuit 35 are included.

  The stage position signal storage unit 28 collects and stores a stage position signal indicating the position of the substrate 9 and the like.

  Upon receiving an instruction signal from the outside, the discharge permission signal generation unit 29 generates a signal for causing the coating head 15 to discharge ink.

  The application pattern signal storage unit 30 stores a signal indicating the arrangement of pixels of the light emitting layer formed on the substrate 9.

  The nozzle processing data storage unit 31, the actuator characteristic data storage unit 32, and the correspondence data storage unit 33 will be described later.

  The discharge signal generation unit 27 receives the stage position signal, the discharge permission signal, and the coating pattern signal, and generates a discharge signal.

  As shown in FIG. 4, this ejection signal is composed of On sig and Off sig, and is supplied to the actuator 21 of the coating head 15 at the timing shown in the figure, whereby the pulse width of the command waveform is determined.

  In other words, by controlling the ON timing of an FET (Field Effect Transistor) bridge (not shown) in the switching circuit of FIG. 3 by controlling the above-mentioned On sig, the timing of charging the actuator 21 is controlled, and the charge is charged by the Off Sig. Control the timing of discharging.

  The voltage value Vref of the command waveform shown in FIG. 4 is obtained by dividing the power supply voltage Vcc in FIG. 3 by the resistance voltage dividing circuit 35 including the variable resistor VR1 and the fixed resistor R1, and adjusting the above-described variable resistor R1. Is obtained.

Next, a conventional method for adjusting the ink discharge amount will be described.
FIG. 5 is a diagram illustrating an example of the amount of ink ejected from the nozzle when a voltage having the same value is applied to all actuators.
As shown in the figure, the amount of ink ejected from the nozzles is not uniform even when the same voltage is applied. This may be due to variations in the characteristics of the actuator, variations in the shape of the nozzles, bubbles or foreign matter in the vicinity of the ink chamber or nozzle, and the presence of bubbles or foreign matter.

  Therefore, conventionally, in order to suppress the difference in discharge amount (ΔΔQ in FIG. 5) to a certain value or less, the command voltage to the actuator is adjusted by adjusting VR1 in FIG.

  As shown in FIG. 6, the relationship between the voltage and the ink discharge amount is generally proportional, and can be linearly approximated as shown in the figure. As described above, since the discharge characteristics differ depending on the nozzle, each nozzle has a different approximate line.

FIG. 7 is a diagram illustrating a sequence of a conventional ink discharge amount adjustment method.
First, information about the ink discharge amount for each nozzle as shown in FIG. 5 is acquired (S71), and then the nozzle discharge amount is adjusted so that the discharge amount falls within the specified range (ΔQ lim) ( Application is performed (S73).

  The process in S72 will be described more specifically. As shown in FIG. 6, when the total ink discharge amount is desired to be equal to Q, the command voltage to the nozzle a is set to Va and the command voltage to the nozzle b is set to Vb. The command voltage to the nozzle c is adjusted to Vc.

  Next, the ink ejection amount method of the present invention will be described with reference to FIG. 9. In the following description, for ease of explanation, the number of nozzles is 10 and one pixel is formed by two drops of ink. It is assumed that the coating head 15 moves by 5 nozzles in a direction orthogonal to the scanning direction every time scanning is performed. Further, the ink discharge amount and the brightness at the time of panel light emission have a correlation.

  As described above, in the conventional discharge amount adjustment method, the discharge amount for each nozzle is adjusted so as to fall within a certain range (ΔQ in FIG. 5). For example, as shown in FIG. 8, only the discharge amount of the nozzle group (a combination of nozzles that supplies ink to the same pixel) B may become small. That is, an appropriate amount of ink, in other words, a necessary amount of ink that is necessary for properly forming the pixel, and a total amount of ink that is ejected from a plurality of nozzles. May not be the same.

  As a result, as shown in FIG. 9, when the substrate 9 coated with ink is caused to emit light, streak unevenness (luminance unevenness) 36 occurs in the portion corresponding to the nozzle group B.

  The nozzle processing data storage unit 31, the actuator characteristic data storage unit 32, and the correspondence data storage unit 33 shown in FIG. 3 are for preventing the above-described streak unevenness 36 from occurring.

  The nozzle processing data storage unit 31 stores processing data such as the thickness of the diaphragm 22, the dimensions of the ink chamber 23, and the outer diameter of the nozzle 25.

  The actuator characteristic data storage unit 32 stores displacement data when the same voltage is applied to each actuator 21, data related to impedance characteristics, and the like.

  The correspondence relationship data storage unit 33 stores data indicating the correspondence relationship between the value of the voltage applied to the actuator 21 and the ink ejection amount. This data is collected in advance.

  The discharge signal generation unit 27 shown in FIG. 3 performs discharge based on at least one of nozzle processing data, actuator characteristic data, and correspondence data in addition to the above-described stage position signal, discharge permission signal, and application pattern signal. A signal is generated, thereby adjusting the ink discharge amount.

  That is, when the required ink amount, which is the amount of ink necessary for properly forming the pixels, and the total ink discharge amount, which is the total amount of ink discharged from the plurality of nozzles 25, are not the same, the plurality of nozzles 25. At least one nozzle is selected.

  Next, the ink discharge amount at the selected nozzle is adjusted so that the total ink discharge amount is equal to the required ink amount.

  Further, the selection of the adjustment target nozzle is performed by selecting at least one of the data indicating the magnitude relationship of the ink discharge amount in each of the plurality of nozzles 25 as shown in FIG. 5, nozzle processing data, and actuator characteristic data. Done based on either.

  In addition, the adjustment of the ink discharge amount calculates the total ink discharge amount from the ink discharge amount of each of the plurality of nozzles, corrects the voltage based on the total ink discharge amount and the corresponding relationship data, and corrects the corrected voltage. Is applied to the actuator 21.

Hereinafter, examples of selecting the adjustment target nozzle and adjusting the ink discharge amount will be described.
FIG. 10A is a diagram showing the discharge amount for each nozzle when the stripe unevenness 36 of FIG. 9 occurs. From this figure, it can be seen that the discharge amount of the No. 2 nozzle and the No. 7 nozzle is small and it is necessary to increase the discharge amount of either or both.

  Here, when determining the nozzle for increasing the discharge amount, the above-described nozzle processing data, actuator characteristic data, and the like are used.

  FIG. 10B shows data relating to the nozzle diameter in the nozzle processing data, and FIG. 10C shows data relating to the displacement amount of the actuator in the actuator characteristic data.

  In this case, it can be seen that the diameter of the second nozzle is extremely small compared to the other nozzles, and it is difficult to increase the discharge amount.

  Further, since the displacements of the actuators are the same, it is determined to increase the discharge amount of the seventh nozzle belonging to the same nozzle group B.

  In order to suppress the stripe unevenness 36, it is necessary to set the difference in the discharge amount between adjacent nozzle groups to a specified value (ΔQT lim) or less.

  FIG. 11 is a diagram showing the discharge amount difference between adjacent nozzle groups before and after the adjustment of the No. 7 nozzle. As shown in the figure, by adjusting the No. 7 nozzle, the discharge amount difference of all the nozzle groups becomes less than the specified value. , It can prevent the occurrence of muscle irregularities.

  The discharge amount difference between the nozzle group A and the adjacent nozzle group is an absolute value obtained by subtracting the discharge amount of the nozzle group A from the discharge of the nozzle group B. For the nozzle group F, the absolute value of the value obtained by subtracting the discharge amount of the nozzle group F from the discharge amount of the nozzle group A from the periodicity of application.

FIG. 12 is a sequence diagram of the ink discharge amount adjustment described above.
First, information on the discharge amount for each discharge signal generation unit nozzle is acquired (S121), then the discharge amount for each nozzle group is calculated (S122), and it is confirmed whether the discharge amount difference ΔQt is equal to or less than a specified value ΔQt lim (S123).

  In S123, when ΔQt is equal to or less than ΔQt lim (S123: Yes), the coating is performed as it is.

  On the other hand, when ΔQt is equal to or greater than ΔQt lim (S123: No), an adjustment target nozzle is selected, the discharge amount of this nozzle is adjusted (S124), and ink is applied (S125).

Next, an example of pixel formation by the ink coating apparatus 1 will be described.
On the substrate 9 (FIG. 1), ITO (Indium Tin Oxide) as a transparent pixel electrode is patterned, and a partition wall is provided between them, thereby forming an opening.

  First, ink droplets 26 (FIG. 2), the ejection amount of which has been adjusted by the controller 20 (FIGS. 1 and 3), are applied to the openings by the application head 15 (FIGS. 1 and 2).

  This ink contains a hole injecting / transporting material such as a polythiophene derivative, and this hole injecting / transporting material injects holes from the anode side into a light emitting layer to be described later for transport. It is for making it happen.

  When the ink containing the hole injection / transport material is applied, solvent removal, heat treatment in a nitrogen atmosphere, and the like are performed to form a hole injection / transport layer.

  Next, an ink droplet 26 containing a light emitting material and whose ejection amount is adjusted by the control unit 20 is applied onto the hole injection / transport layer by the application head 15.

  When the ink containing the light emitting material is applied, solvent removal, heat treatment in a nitrogen atmosphere, and the like are performed, and a light emitting layer is formed.

  Thereafter, the cathode is formed by vapor deposition or sputtering of Ca, Mg, Ag, Al, Li, or the like by another apparatus, and further, the formation of the pixel is completed by forming the sealing layer with an epoxy resin or the like.

  In the above-described embodiments, the actuator is a piezoelectric element, and the case where the applied voltage value is corrected when adjusting the ink discharge amount is not limited to this. The ink discharge amount can be adjusted by correcting the amount of power supplied to the actuator and correcting the amount of power supplied thereto.

  Further, data indicating the relationship between the supplied power and the ink discharge amount may be stored in advance, and a correction value for the power amount may be obtained based on the data.

  In addition, a display device manufacturing method including the ink discharge amount adjusting step is also included in the scope of the present invention.

  As described above, according to the present invention, even when there is a nozzle that cannot increase the ink discharge amount due to its small diameter, the nozzle amount can be increased by increasing the discharge amount of other nozzles in the same nozzle group. The total discharge amount of the group can be made uniform.

  This greatly reduces the need to replace or re-clean the parts and greatly reduces the adjustment time. Therefore, productivity of an organic EL display or the like can be improved and further cost reduction can be realized.

It is a perspective view of the ink application apparatus which concerns on one Example of this invention. It is a schematic diagram of the coating head 15 of FIG. It is a block diagram which shows the structure of the control part of FIG. It is a figure which shows the supply timing of an ejection signal. It is a figure which shows the ink discharge amount for every nozzle. It is a figure which shows the relationship between command voltage value and ink discharge amount. It is a figure which shows the conventional ink discharge amount adjustment sequence. It is a figure which shows the ink discharge amount of a nozzle group. It is a figure which shows the stripe nonuniformity which arose on the board | substrate. (A) is a figure which shows the ink discharge amount for every nozzle at the time of a stripe | line | muscle nonuniformity having arisen. (B) It is a figure which shows the data regarding a nozzle diameter. (C) It is a figure which shows the displacement amount of the voltage in an actuator. It is a figure which shows the difference of the ink discharge amount between adjacent nozzle groups. It is a figure which shows the adjustment sequence of the ink discharge amount in this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Ink application apparatus, 2 ... Ink application box, 3 ... Ink supply box, 4 ... Mounting stand, 5 ... Y-axis direction slide plate, 6 ... Y-axis direction movement table, 7 ... X-axis direction movement table, 8 ... Substrate holding Table, 9 ... Substrate, 10 ... Substrate gripping mechanism, 11 ... Column, 12 ... X-axis direction slide plate, 13 ... Coating head unit, 14 ... Coating head unit gripping member, 15 ... Coating head, 16 ... Vertical movement mechanism, 17 Ink tank, 18 ... Ink supply tank, 19 ... Head maintenance unit, 20 ... Control unit, 21 ... Actuator, 22 ... Diaphragm, 23 ... Ink chamber, 24 ... Ink, 25 ... Nozzle, 26 ... Droplet, 27 ... Ejection Signal generation unit, 28 ... stage position signal storage unit, 29 ... discharge permission signal generation unit, 30 ... application pattern signal storage unit, 31 ... nozzle processing data storage unit, 2 ... actuator characteristic data storage unit, 33 ... correspondence data storage unit, 34 ... switching circuit, 35 ... resistor divider 36 ... streaks

Claims (6)

An ink application device that ejects ink droplets from a plurality of nozzles,
When the appropriate ink amount that is a predetermined appropriate amount of ink and the total ink discharge amount that is the total amount of ink discharged from the plurality of nozzles are not the same, at least one of the plurality of nozzles is selected. Nozzle selection means for selecting individual nozzles;
An ink application apparatus comprising: a discharge amount adjusting unit that adjusts an ink discharge amount at the selected nozzle so that the appropriate ink amount is equal to the total ink discharge amount. The ink droplets are ejected by an actuator,
The nozzle selecting means includes at least one of data indicating a magnitude relationship of ink discharge amounts at each of the plurality of nozzles, processing data at the time of manufacturing the plurality of nozzles, and data regarding the characteristics of the actuator. The ink coating apparatus according to claim 1, wherein the nozzle is selected based on whether the nozzle is selected. The ink droplets are ejected by an actuator,
The discharge amount adjusting means calculates the total ink discharge amount from the discharge amount of ink from each of the plurality of nozzles, and calculates the total ink discharge amount, the power supplied to the actuator acquired in advance, and the ink discharge amount. Correcting the amount of power supplied to the actuator based on the data indicating the correspondence, and adjusting the amount of ink discharged from the selected nozzle by supplying the corrected amount of power to the actuator. The ink coating apparatus according to claim 1 or 2, characterized in that A display device manufacturing method in which ink droplets are ejected from a plurality of nozzles, and pixels are formed by the ejected ink.
The plurality of nozzles when the total amount of ink discharged, which is the total amount of ink discharged from the plurality of nozzles, and the necessary ink amount, which is the amount of ink necessary for properly forming the pixels, are not the same. A nozzle selection step of selecting at least one nozzle from
A display device manufacturing method comprising: a discharge amount adjustment step of adjusting an ink discharge amount at the selected nozzle so that the total ink discharge amount is equal to the required ink amount. The ink droplets are ejected by an actuator,
In the nozzle selection step, at least one of data indicating the magnitude relationship of the ink discharge amount at each of the plurality of nozzles, processing data at the time of manufacturing the plurality of nozzles, and data regarding the characteristics of the actuator. The display device manufacturing method according to claim 4, wherein the nozzle is selected based on any one of them. The ink droplets are ejected by an actuator,
In the discharge amount adjustment step, the ink discharge total amount is calculated from the ink discharge amount of each of the plurality of nozzles, and the ink discharge total amount, the power supplied to the actuator and the ink discharge amount acquired in advance are calculated. The amount of power supplied to the actuator is corrected based on the data indicating the correspondence relationship between the two, and the amount of ink discharged from the selected nozzle is adjusted by supplying the corrected amount of power to the actuator. The display device manufacturing method according to claim 4, wherein:

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