KR20220114029A - A method for manufacturing a thin film pattern for a display - Google Patents

Abstract

A method of manufacturing a thin film pattern of a display according to the present embodiment includes a drop inspection step of inspecting each drop falling from each nozzle to each pixel; a drop count calculation step of calculating a minimum number of drops required to reach a target volume for each pixel according to a result of the drop checking step; a drop sorting step of assigning a weight to each drop according to a result of the check in the drop checking step, and arranging each drop in an order of increasing weight; and a print control step of basically selecting drops having a weight as high as the minimum number of drops, and generating print data according to a result of comparing the target volume with the sum of the volumes of the basically selected drops.

Description

A method for manufacturing a thin film pattern for a display

The present invention relates to a method for manufacturing a thin film pattern of a display capable of controlling staining during an inkjet process.

With the recent development of advanced imaging devices, the demand for display devices is increasing, and LCD (Liquid Crystal Display), OLED (Organic Light Emitting Diodes), and the like are widely used.

LCD is a process of manufacturing a lower array substrate in which thin film transistors and pixel electrodes are arranged; and a liquid crystal cell process consisting of encapsulation and attaching a polarizing plate.

OLED is a solid thin film (light emitting layer) containing fluorescent organic molecules sandwiched by two electrodes (cathode and anode). When a voltage is applied to the electrodes, holes from the anode and electrons from the cathode are injected into the light emitting layer, Fluorescence is emitted.

In order to manufacture a color filter or a solid thin film in the display device as described above, vacuum deposition or an inkjet technique is used. The inkjet technique is simple and can increase production efficiency at low cost in a short time.

1A to 1B are diagrams illustrating a process of manufacturing a display device by an inkjet technique.

As shown in FIG. 1A , when an electronic material 1 forming a pixel is printed in each space partitioned by a plurality of barrier ribs 2 by an inkjet technique, the electronic material 1 is formed between the barrier ribs 2 . When dried and cured in each space, each pixel P may be completed.

However, the same amount of the electronic material 1 may not be supplied in each space, and the characteristics may be different due to a slight difference in the amount of the electronic material 1 .

As shown in FIG. 1B , when the electronic material 1 is cured to have different thicknesses in each space, differences in luminance and color may occur due to the difference in thickness of each pixel P, and may appear as spots.

Japanese Patent No. 4311084 (applied on June 2, 2003) discloses a liquid application process for applying a liquid material to a pixel region having a long axis and a short axis in a droplet ejection method, and a droplet ejection device in the liquid application process. Disclosed is a method for manufacturing a thin film pattern having a short axis discharge process in which a nozzle head is scanned in a short axis direction of a pixel area, and a droplet is discharged to a pixel area from an inkjet nozzle provided in the nozzle head in the scanning process.

Staining occurs due to the volume deviation of the droplet within each pixel. By mixing nozzles using a plurality of nozzles, the volume variance of the droplet can be dispersed within each pixel, and unidirectional or periodic staining can be reduced. can do it

However, although the above technique can disperse the volume variation of the droplet within each pixel, it cannot reduce the volume variation of the droplet within each pixel, so there is a limit to reducing the speckle.

Korean Patent Registration No. 1250785 (applied on June 29, 2006) includes the steps of inspecting stains after inputting the liquid crystal panel; measuring spot coordinates and luminance of the liquid crystal panel; storing the coordinates and luminance data in a printer; printing at least one ink on the film according to the data; measuring the degree of compensation after loading the film on the liquid crystal panel; feedback to the initial stage when the compensation level is abnormal; And when the degree of compensation is good, the step of assembling the liquid crystal panel is disclosed.

However, in the above technique, since an additional printing process of attaching a film for compensating for stains generated after ink printing is performed, productivity is lowered, and abnormal occurrence of the printing apparatus during the printing process cannot be confirmed.

The present invention has been devised to solve the problems of the prior art, and an object of the present invention is to provide a method for manufacturing a thin film pattern of a display capable of constantly supplying a volume of a droplet in each pixel during an inkjet process.

The method for manufacturing a thin film pattern of a display according to the present embodiment includes a drop inspection step of inspecting each drop (D) falling from each nozzle to each pixel; a drop number calculation step of calculating a minimum number of drops (Nm) for reaching a target volume (Vt) per pixel according to the result of the drop checking step; a drop sorting step of assigning a weight (a) to each drop (D) according to the test result in the drop checking step, and arranging each drop (D) in an order of increasing weight (a); and basically selecting the drops D1 having a weight as high as the minimum number of drops Nm, and adding the summed volume V _D1 by summing the volumes of the basically selected drops D1 and the target volume Vt. and a print control step of generating print data according to the comparison result.

The drop inspection step may include measuring the volume of each drop (D).

In the step of calculating the number of drops, the average volume of each drop D and its deviation are calculated, and the volume average of each drop D and its deviation are taken into consideration to reach the target volume Vt for each pixel. It may include a process of calculating the minimum number of drops (Nm).

The drop alignment step includes extracting an inspection result of each drop (D) corresponding to each pixel, and extracting the remaining normal drops (D) after removing defective drops according to the inspection result of each drop (D); , it may include a process of assigning a weight (a) to each normal drop (D).

In the drop sorting step, a weight (a) is given to each drop (D) according to the position of each pixel corresponding to each drop (D), the scan order of each drop (D), and the volume range of each drop (D) The process may further include.

The drop sorting step may further include a process in which a weight (a) is assigned to each drop (D) according to a random number.

The drop sorting step may further include setting different weights of criteria for giving weight a to each drop D.

The printing control step may include generating print data using the basically selected drops D1 when the summed volume V _D1 is equal to the target volume Vt.

In the printing control step, if the summed volume (V _D1 ) is smaller than the target volume (Vt), the additional volume (ΔV) that is an error value between the summed volume (V _D1 ) and the target volume (Vt) is reached. a process of calculating the number of additional drops Na for ) and generating print data using the additionally selected drops D2.

In the process of calculating the number of additional drops, the number of additional drops Na for reaching the additional volume for each pixel may be calculated in consideration of the average volume of each drop D and a deviation thereof.

In the method for manufacturing a thin film pattern of a display according to the present embodiment, the volumes of the drops are summed in the order of the highest weight among all the drops to fit the target volume required for one pixel. Since it can be effectively selected and used in the printing process, and the thickness of each pixel can be formed uniformly, it is possible to not only prevent staining of the display panel but also improve its quality.

In addition, the volume of drops with high weight among all the drops is summed up by the minimum number of drops, and the volume of drops is added up by the number of additional drops in the order of increasing weight among the remaining drops except for the default selected drops, so the calculation execution time is minimized can do it

In addition, by easily controlling the weight of each drop, it is possible to efficiently change print data suitable for each equipment.

1A to 1B are views illustrating a process of manufacturing a display device by an inkjet technique.
2 is a diagram schematically illustrating an apparatus for manufacturing a thin film pattern of a display according to the present embodiment.
3 is a block diagram illustrating a control unit included in the apparatus for manufacturing a thin film pattern of a display according to the present embodiment.
4 is a flowchart illustrating a method for manufacturing a thin film pattern of a display according to the present embodiment.

2 to 3 are diagrams respectively illustrating an apparatus for manufacturing a thin film pattern of a display and a control unit included therein according to the present embodiment.

As shown in FIG. 2 , the apparatus for manufacturing a thin film pattern of a display according to the present embodiment may include a nozzle head 110 , a head driving unit 120 , an inspection unit 130 , and a control unit 120 .

The nozzle head 110 is a device for forming a thin film pattern on the display panel P by dropping an electronic material in the form of droplets on one surface of the display panel P, and is located above the stage on which the display panel P is loaded. may be spaced apart. Of course, since the stage is rotatably installed, the long side or the short side of the display panel P loaded on the stage may be located below the nozzle head 110 .

The nozzle head 110 includes a plurality of nozzles 111 arranged in a line at a predetermined interval in the longitudinal direction on the lower side, and each nozzle 111 may be opened and closed by each nozzle valve 112 .

Each nozzle 111 is provided with more than the number of nozzles 111 required to form each pixel of the display panel P, and some of the nozzles 111 can be selectively used in the inkjet process. have.

Each nozzle valve 112 is controlled by a valve control unit 142 included in the control unit 140 to be described below, and it is possible to control whether each nozzle valve 112 is opened or closed.

The head driving unit 120 is a device for moving the nozzle head 110 along the long side or the short side of the display panel P from the upper side of the display panel P, and includes a motor and a power transmission member such as a belt for transmitting power. may include. Of course, the head driver 120 may move the nozzle head 110 to be horizontal with the stage on which the display panel A is seated.

The head driving unit 120 is controlled by a driving control unit 141 included in the control unit 140 to be described below. During the inkjet process, the nozzle head 110 is moved horizontally along the long side or short side of the display panel P. can be moved

The inspection unit 130 is a device for inspecting the state of each nozzle 111 by measuring each drop D falling from each nozzle 111 of the nozzle head 110 , and may be configured in various ways.

For example, configured to measure the area of each drop (D) falling on a separate film, configured to take an image of each drop (D) falling from the air by a camera and line cam, etc., or falling from the air by a laser It may be configured to measure each drop (D), but is not limited thereto.

The inspection unit 130 provides the inspection result of each nozzle 111 to the print control unit 143 included in the control unit 140 described below, and the print control unit 143 determines whether each nozzle 111 is normal or defective. Alternatively, the volume of each drop (D) can be calculated.

The control unit 140 includes a driving control unit 141 for controlling the head driving unit 120 , a valve control unit 142 for controlling each nozzle valve 112 , and a control signal to the driving control unit 141 and the valve control unit 142 . It may include a print control unit 143 that transmits the .

The print control unit 143 generates print data by using the information input from the inspection unit 130, and provides respective control signals to the drive control unit 141 and the valve control unit 142 according to the print data, so that the nozzle head ( 110) to control the inkjet process.

However, during the inkjet process, one pixel may be manufactured by at least several drops D falling from each nozzle 111 , and print data may include opening/closing information of each nozzle 111 .

The print control unit 143 may receive from the inspection unit 130 an image of measuring the drops D of each nozzle 111 as well as the volume of each drop D as information, and It is possible to determine whether each nozzle 111 is defective by comparing the measured image with the normal drop image, and calculates the average volume and volume deviation of each drop D based on the remaining nozzles 111 except for the defective nozzle. can do.

The print control unit 143 assigns a higher weight to each drop D of the remaining nozzles 111 except for the defective nozzle as it is suitable for the process, and uses the drops D with high weight in order to match the target volume. Print data can be calculated, which will be described in detail below.

The print control unit 143 may set a weight given to each drop D, and the setting criterion of the weight a may be changed by an operator.

The weight (a) of each drop (D) is the position of each pixel corresponding to each drop (D), the scan order of each drop (D), the volume range of each drop (D), and can be a variable for each pixel. It may be assigned based on a random number, etc., and the weight of the criterion for assigning a weight (a) to each drop (D) may be set differently.

For example, the closer the distance from the boundary or center of each pixel, the faster the scan order, the smaller the average volume and deviation of all drops D, the larger the weight a of each drop D will be set. may, but is not limited to.

The print data calculated by the print control unit 143 may be computerized, such as BMP, PDF, or JPEG, and may be configured in a format capable of recording the location of each drop D, and correspond to each drop D calculated as print data. The inkjet process may be performed by controlling each nozzle 111 to be used.

4 is a flowchart illustrating a method for manufacturing a thin film pattern of a display according to the present embodiment.

According to the present embodiment, when each pixel is formed on the display panel by the inkjet method, each pixel should be formed to have the same thickness in order to prevent the occurrence of stains on the display panel. Accordingly, in order to supply drops by the same target volume to each pixel, it is possible to quickly control the ejection of each drop by examining each drop.

First, before starting the inkjet process, each drop (D) may be inspected (see S1).

Each nozzle arranged in a row on the nozzle head jets the electronic material in the form of droplets to form each pixel on the display panel, and each drop D falling from each nozzle can be inspected before the nozzle head is put into the process. .

The inspection of each drop D may be performed in the form of photographing an image of each drop D falling from each nozzle or measuring the volume of each drop D falling from each nozzle, but is not limited thereto.

Next, the minimum number of drops (Nm) corresponding to the target volume (Vt) of each pixel may be calculated according to the drop inspection result (refer to S2).

Calculate the volume average of each drop D and its deviation by applying the volume of each drop D, and reach the target volume Vt per pixel by considering the volume average of each drop D and its deviation It is possible to calculate the minimum number of drops (Nm) for

The minimum number of drops Nm may be set as a quotient obtained by dividing the target volume Vt of one pixel by the largest volume among the drops D or the average volume of the drops D, but is not limited thereto.

Of course, even if the largest volume among the drops D or the average volume of the drops D is summed up by the minimum number of drops Nm, it is inevitably equal to or smaller than the target volume Vt.

Next, a weight (a) may be given to each drop (D) according to the drop check result, and each drop (D) may be sorted in the order of the weight (a) being higher (refer to S3 and S4).

If the image of each drop D does not match the normal image, the nozzle corresponding to the corresponding drop D may be determined to be defective, but the process for determining the defective nozzle may be variously configured and is not limited thereto.

A weight a may be given only to each drop D corresponding to the remaining normal nozzles except for the defective nozzles, and the operator may select or change a criterion for applying the weight of each drop D.

The weight (a) of each drop (D) may be assigned according to criteria such as the position of each pixel corresponding to each drop (D), the scan order of each drop, the volume range of each drop, and a random number. The weight of the criterion for assigning the weight (a) to (D) may also be set differently, but is not limited thereto.

Since the operator can appropriately control or change the weight a of each drop D, it is possible to efficiently change print data suitable for each equipment to be described below.

If a weight a is assigned to each drop D, the drops D may be arranged in an order of increasing the weight a.

Next, from among all the drops D, the drops D1 may be basically selected in the order in which the weight a is high by the minimum number of drops Nm, and the volumes of the basically selected drops D1 may be summed. (See S5, S6)

Even if the volumes of the basically selected drops D1 are summed up by the minimum number of drops Nm, it is inevitably equal to or smaller than the target volume Vt.

Next, if the summed volume V _D1 is equal to the target volume Vt of each pixel, print data may be generated by the default selected drops D1 (refer to S7 and S8).

If the volume of the drops D1 is summed up as much as the minimum number of drops Nm in the order of the highest weight a among all the drops D to match the target volume Vt required for one pixel, the print data is It may be generated by default selected drops D1.

The print data may be computerized, such as BMP, PDF, or JPEG, and may be configured in a format capable of recording the positions of the basically selected drops D1, but is not limited thereto.

On the other hand, if the summed volume (V _D1 ) is smaller than the target volume (Vt) of each pixel, the number of additional drops (Na) corresponding to the error (ΔV) between the summed volume (V _D1 ) and the target volume (Vt) is calculated. (Refer to S7 and S9)

The number of additional drops Na may be set as a quotient obtained by dividing the error volume ΔV by the average volume of the remaining drops D, but is not limited thereto.

Next, the drops D2 are additionally selected from among the unselected drops D in the order in which the weight a is higher by the number Na of the additional drops, and the default selected drops D1 and the additionally selected drops D2 are selected. ) to create print data (see S10 and S11).

The volumes of the drops D1 are summed up by the minimum number of drops (Nm) in the order of the highest weight (a) among all the drops (D), and the remaining drops (D-D1) except for the default-selected drops (D1) When the volume of the drops D2 is added up by the number of additional drops Na in the order of the weight (a) from the highest to the target volume (Vt) required for one pixel, the print data is basically selected from the drops D1 ) and additionally selected drops D2.

Rather than additionally selecting the drops D2 as much as the number of additional drops Na from among all the drops D, the remaining drops D-D1 from the total drops D except for the default-selected drops D1 Since the drops D2 are additionally selected as much as the number of additional drops Na among them, the calculation execution time can be minimized.

Similarly, the print data may be computerized, such as BMP, PDF, JPEG, etc., and may be configured in a format capable of recording the positions of the basically selected drops D1 and the additionally selected drops D2, but is not limited thereto.

In this way, when the print data is generated, a printing process of forming each pixel on the display panel may be performed using an inkjet method according to the print data (see S12).

By selecting the drops in the order of the highest weight (a) among all the drops (D), one pixel can accurately fit the required target volume (Vt), so that the drops (D) in an advantageous position for the printing process can be effectively selected. It can be selected and used in the printing process, and by forming the thickness of each pixel uniformly, it is possible not only to prevent staining of the display panel, but also to improve its quality.

This embodiment may be applied to a display device such as an LCD or OLED including a thin film pattern manufactured by an inkjet process.

Claims (10)

a drop inspection step of inspecting each drop (D) falling from each nozzle to each pixel;
a drop number calculation step of calculating a minimum number of drops (Nm) for reaching a target volume (Vt) per pixel according to the result of the drop checking step;
a drop sorting step of assigning a weight (a) to each drop (D) according to the test result in the drop checking step, and arranging each drop (D) in an order of increasing weight (a); and
Drops D1 having a weight as high as the minimum number of drops Nm are basically selected, and the total volume V _D1 obtained by summing the volumes of the basically selected drops D1 is compared with the target volume Vt. A method of manufacturing a thin film pattern of a display comprising a; a print control step of generating print data according to a result. According to claim 1,
The drop inspection step is
A method for manufacturing a thin film pattern of a display, comprising measuring the volume of each drop (D). According to claim 1,
The step of calculating the number of drops is
The process of calculating the volume average of each drop (D) and its deviation;
A method of manufacturing a thin film pattern for a display, comprising calculating a minimum number of drops (Nm) to reach a target volume (Vt) for each pixel in consideration of an average volume of each drop (D) and a deviation thereof. According to claim 1,
The drop sorting step is
The process of extracting the inspection result of each drop (D) corresponding to each pixel;
The process of extracting the remaining normal drops (D) after removing the bad drops according to the inspection result of each drop (D);
A method of manufacturing a thin film pattern for a display, comprising the step of assigning a weight (a) to each normal drop (D). According to claim 1,
The drop sorting step is
The process of assigning a weight (a) to each drop (D) according to the position of each pixel corresponding to each drop (D), the scan order of each drop (D), and the volume range of each drop (D) A method of manufacturing a thin film pattern for a display. 6. The method of claim 5,
The drop sorting step is
The method of manufacturing a thin film pattern of a display further comprising the step of assigning a weight (a) to each drop (D) according to a random number. 7. The method of claim 6,
The drop sorting step is
The method of manufacturing a thin film pattern of a display further comprising the step of differently setting the weight of a criterion for assigning a weight (a) to each drop (D). According to claim 1,
The print control step is
and when the summed volume (V _D1 ) is equal to the target volume (Vt), generating print data by the basic selected drops ( D1 ). According to claim 1,
The print control step is
If the summed volume V _D1 is smaller than the target volume Vt, the _number of additional drops Na ) and the process of calculating
A part of the non-selected drops D-D1 among the drops D is additionally selected by the number of additional drops Na, and printed by the basic selected drops D1 and the additionally selected drops D2 A method for manufacturing a thin film pattern of a display, comprising the process of generating data. 10. The method of claim 9,
The process of calculating the number of additional drops is:
A method of manufacturing a thin film pattern for a display that calculates the number of additional drops (Na) to reach an additional volume per each pixel by considering the average volume of each drop (D) and its deviation.

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