KR20210136630A - Inkjet nozzle module with swivel motion and apparatus for repairing substrate comprising the same - Google Patents

Abstract

Provided is an inkjet nozzle module with swivel motion. According to the present invention, the inkjet nozzle module with swivel motion for discharging ink from a nozzle toward a substrate comprises: an XYZ stage moving through a three-axis motion to an upper spatial position of the substrate; a swivel stage coupled to the XYZ stage and changing the Z-axis position with respect to the nozzle tip; and a nozzle holder coupled to the swivel stage and allowing the nozzle to be attached and detached.

Description

Inkjet nozzle module with swivel motion and repair device for substrate including same

The present invention relates to an inkjet nozzle module for repairing defects generated on a substrate using ink, and a substrate repair apparatus including the same.

A display panel is a device for displaying visual information such as an image or video. Such a display panel tends to include more pixels and data lines in the same area according to the development of technology and changes in IT trends. As a result, the metal wiring including the data line is formed with a very fine line width, and defects such as disconnection of the metal wiring occur in the manufacturing process of the display panel. As such, when a defect such as disconnection occurs in the metal wiring, it is repaired by a repair device. In addition, the repair apparatus is equipped with an inkjet nozzle module for discharging ink to the defective area.

However, in the conventional inkjet nozzle module, two nozzles for discharging ink, for example, conductive ink and passivation ink, respectively, are arranged in a double-arm structure at positions symmetrical to each other. That is, the existing inkjet nozzle module consists of an inkjet nozzle module 1 for discharging conductive ink and an inkjet nozzle module 2 for discharging insulating ink. At this time, the inkjet nozzle module 1 and the inkjet nozzle module 2 each include an X stage, a Y stage, and a Z stage, and a total of six axial stages were used in the inkjet nozzle module. In addition, a separate VMU optical system was installed in the repair device to visually check the work process through the inkjet nozzle module.

However, the structure of the inkjet nozzle module lowered the precision for positioning, and resulted in an increase in the time required for operation through each nozzle. In addition, the laser process performed after the inkjet process involves positioning of the main optical system, which also takes a certain amount of time, so the conventional repair process is disadvantageous in terms of tact time.

Republic of Korea Patent No. 10-1735820 (Registered on May 08, 2017) Republic of Korea Patent Publication No. 10-2018-0121470 (published on November 07, 2018) Republic of Korea Patent Publication No. 10-2019-0102864 (published on September 4. 2019)

The embodiment of the present invention has been devised to solve the above problems, and a plurality of nozzles can be attached to a single module, thereby reducing the number of parts and time required for positioning each nozzle. We would like to provide an inkjet nozzle module that can In addition, an object of the present invention is to provide an inkjet nozzle module that can be used not only in a repair process but also in a color filter manufacturing process. Another object of the present invention is to provide an inkjet nozzle module capable of further improving positioning accuracy. Another object of the present invention is to provide an inkjet nozzle module capable of changing a nozzle used by a simple operation among a plurality of nozzles.

An object of the present invention is to provide a substrate repair apparatus that can reduce the number and time required to check the work process by using an existing optical unit instead of an optical system for an inkjet nozzle module. Another object of the present invention is to provide an apparatus for repairing a substrate having a more simplified structure.

An embodiment of the present invention provides an inkjet nozzle module for discharging ink from a nozzle toward a substrate in order to solve the above problems, an XYZ stage moving through a three-axis motion to a spatial position above the substrate; a swivel stage coupled to the XYZ stage and changing the Z-axis position with respect to the nozzle tip; It provides an inkjet nozzle module with a swivel motion that includes; a nozzle holder coupled to the swivel stage and allowing the nozzle to be attached and detached.

The swivel stage may provide a swivel motion so that the nozzle tip is moved from a ready position to a jetting position where ink is discharged.

The Z-axis distance between the ready position and the jetting position is preferably within 10 mm.

At least one nozzle is coupled to the nozzle holder, and it is preferable that the Z-axis position with respect to the nozzle tip in the coupled state gradually increases from the middle point of the nozzle holder to both ends.

When a plurality of the nozzles are combined, the nozzles used may be changed between the nozzles by driving by the swivel stage.

inkjet nozzle module; a gantry unit to which the inkjet nozzle module is mounted; and an optical unit installed in the gantry unit and formed to have an optical path coaxial with the optical path of the laser beam generated from the laser unit, wherein the inkjet process through the inkjet nozzle module captures the image by the optical unit. It provides a repair apparatus of the substrate, characterized in that confirmed through.

An optical Z stage for changing the Z-axis position of the optical unit may be further formed between the gantry and the optical unit.

Preferably, the nozzle tip is located within the photographing area of the optical unit at the jetting position.

When the inkjet process is finished, the nozzle tip is moved from the jetting position to the ready position by a swivel motion, and then it is preferably moved to depart within the shooting area by the X-axis or Y-axis motion by the XYZ stage. .

According to the problem solving means of the present invention as described above, various effects including the following items can be expected. However, the present invention is not established only when exhibiting all of the following effects.

In the inkjet nozzle module according to an embodiment of the present invention, a plurality of nozzles may be attached to a single module, thereby reducing the number of parts and time required for positioning each nozzle. In addition, it may be used in a color filter manufacturing process as well as a repair process. In addition, the operation of changing the Z-axis position of the nozzle tip through the swivel stage can improve the positioning accuracy. In addition, it is possible to simply change the nozzle used between the nozzles through the swivel motion.

The apparatus for repairing a substrate according to an embodiment of the present invention can reduce the number of parts and time required to check a work process by using an existing optical unit instead of an optical system for an inkjet nozzle module. In addition, the structure of the substrate repair apparatus can be further simplified thereby.

1 is a block diagram of an inkjet nozzle module according to an embodiment of the present invention;
Figure 2 is a view showing a change in the position of the nozzle according to the swivel motion process.
Figure 3 is a relationship diagram when the nozzle tip is changed from the ready position to the jetting position according to the swivel motion.
Figure 4 is a schematic view showing a state in which a plurality of nozzles are attached to the nozzle holder.
FIG. 5 is a view showing the operation of the inkjet nozzle module after the inkjet process is finished in the apparatus for repairing the substrate including the inkjet nozzle module of FIG. 1 ;

Hereinafter, in the description of the present invention, when it is determined that the subject matter of the present invention may be unnecessarily obscured as it is obvious to those skilled in the art with respect to related known functions, the detailed description thereof will be omitted. The terminology used in the present application is only used to describe specific embodiments and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

1 is a block diagram of an inkjet nozzle module according to an embodiment of the present invention, FIG. 2 is a view showing a change in position of a nozzle during a swivel motion process, and FIG. It is a relationship diagram when the position is changed, and FIG. 4 is a schematic diagram showing a state in which a plurality of nozzles are attached to the nozzle holder.

1 to 4 , the inkjet nozzle module according to an embodiment of the present invention includes an XYZ stage 10 , a swivel stage 20 , a nozzle holder 30 , a nozzle 40 , and the like. Here, the inkjet nozzle module 100 may be used as a part of various inkjet apparatuses, for example, an E.H.D (Electro Hydro Dynamics) inkjet apparatus, a pneumatic ejection type inkjet apparatus, a laser chemical vapor deposition apparatus (LCVD), and the like. The inkjet nozzle module 100 may perform a process of discharging or applying ink to various types of substrates 400 including semiconductor substrates, display panels, PCB substrates, and the like. More specifically, the inkjet process may be utilized, for example, in a repair process, a color filter manufacturing process, and various circuit manufacturing processes depending on the ink used.

The inkjet nozzle module 100 functions to discharge ink toward the substrate 400 using the nozzle 40 . The inkjet nozzle module 100 according to an embodiment may have a purpose for repairing defects such as open defects and short defects generated in the display panel. The defect may be, for example, an open defect in which a part of a data line formed in the panel is disconnected. And, the inkjet nozzle module 100 may repair such a metal wiring layer.

In the XYZ stage 10, the X stage 12, the Y stage 14 and the Z stage 16 are combined, and the object is moved to a certain space position through independent motion that is individually controlled in the three-axis direction to determine the position do That is, the XYZ stage 10 is a transport means for transporting the nozzle 40 . On the other hand, the XYZ stage 10 may be coupled to each other in various combinations such as X-Y-Z, X-Z-Y, Y-X-Z.

The XYZ stage 10 may move through a three-axis motion to a spatial position above the substrate 400 . That is, the XYZ stage 10 may be positioned in a horizontal direction and a vertical direction, respectively. The XYZ stage 10 is driven in steps, and the X stage etc. 12, 14, and 16 use, for example, a linear motor to achieve ultra-precise position control in micrometers (μm) within the maximum stroke range. possible.

The swivel stage 20 is coupled to the XYZ stage 10 , and the Z-axis position with respect to the nozzle tip 42 can be changed. The swivel stage 20 includes a fixed stage and a driving stage driven by a motor. The swivel stage 20 determines its position through a driving stage that reciprocates between the forward and reverse directions within a predetermined rotation angle range. The movement according to the operation of the driving stage is called swivel motion.

The swivel stage 20 according to an embodiment has a purpose for changing the Z-axis position, in particular, with respect to the nozzle tip 42 (nozzle tip), which is one end of the nozzle 40 . Specifically, the swivel stage 20 may provide a swivel motion so that the nozzle tip 42 is moved from a ready position to a jetting position where ink is discharged. The ready position RP refers to a point located upward in the Z-axis direction from the preset jetting position JP.

For example, it is assumed that the spatial coordinates of the ready position RP are x1, y1, and z1, and the spatial coordinates of the jetting position JP are x2, y2, and z2. Here, the Z-axis distance between the ready position (RP) and the jetting position (JP) according to an embodiment is preferably within 10mm. That is, the spatial coordinates of the nozzle tip 42 may be changed within a maximum distance of 10 mm between z1 and z2 by the swivel motion. In this case, the distance between x1 and x2 may be changed within tens to hundreds of micrometers (μm). In addition, the distance between y1 and y2 may also be changed within tens to hundreds of micrometers (μm). Meanwhile, the minimum distance between z1 and z2 may be preset by the operator. This is, when the nozzle tip 42 moves in the horizontal direction from the ready position RP, it is considered that interference with the substrate 400 does not occur.

This swivel stage 20 enables high-precision position control with respect to the nozzle tip 42 in the ready position RP, particularly in the Z-axis direction. To this end, the swivel stage 20 may be disposed so that the driving stage faces vertically upward or vertically downward in a non-rotating state. In Fig. 1, the swivel stage 20 is arranged vertically downward. Alternatively, the swivel stage 20 is coupled to the upper side of the XYZ stage 10 and may be arranged to face vertically upwards. On the other hand, according to the coupling relationship with the XYZ stage 10 or the coupling direction, the swivel stage 20 is configured so that any one of the distance between x1 and x2 and the distance between y1 and y2 becomes zero even if there is a swivel motion. can

The swivel stage 20 is combined with the XYZ stage 10 that linearly moves in the three-axis direction to improve the precision of positioning with respect to the inkjet nozzle module 100 . As a result, the Z stage is controlled not to operate in the ready position (RP).

The nozzle holder 30 is coupled to the swivel stage 20 . The nozzle holder 30 has a purpose for setting the nozzle 40 on the swivel stage 20 . To this end, the nozzle holder 30 may be formed with a jaw 32 or the like to which the other end of the nozzle 40 (a portion opposite to the nozzle tip 42) can be attached. At this time, the length of the nozzle 40 may vary according to the spatial coordinates of the nozzle tip 42 is set in advance. When the nozzle 40 is attached to the nozzle holder 30 through the jaw 32 or the like, the nozzle tip 42 is positioned at the ready position RP. On the other hand, the shape of the nozzle holder 30 is not limited to any one shape. In addition, the position of the jaws or the number thereof is also not limited.

On the other hand, the nozzle 40 is repeatedly replaced, which necessarily accompanies the process of being detached. In addition, at least one or more nozzles 40 may be coupled to the nozzle holder 30 according to an embodiment. At this time, the nozzle 40 serves to discharge different types of ink. Specifically, the ink includes a conductive ink for repair, an insulating ink, and the like. In addition, the ink may further include a color ink for manufacturing a color filter. Meanwhile, the number of nozzles 40 set in the nozzle holder 30 may be limited according to the size of the swivel stage 20 , the shape of the nozzle holder 30 , the number of jaws, and the like.

When a plurality of nozzles 40 are coupled to the nozzle holder 30 , the Z-axis position with respect to the nozzle tip 42 in the coupled state gradually increases from the middle point of the nozzle holder 30 to both ends. This is in consideration of the driving angle of the swivel stage 20 according to the swivel motion. On the other hand, when a plurality of nozzles 40 are combined, any one nozzle 40 corresponding to each process is selected and in order for the nozzle to be used, it is necessary to first change the use state. The swivel stage 20 may change the nozzle used among the plurality of nozzles 40 through the driving of the driving stage. For example, to change the nozzle used from nozzle 1 to nozzle 2, the swivel stage 20 is driven in the forward or reverse direction to move the tip position of the nozzle 2 to the ready position RP.

As such, the inkjet nozzle module 100 according to an embodiment uses one XYZ stage 10 and one swivel stage 20 for positioning for a plurality of nozzle tips 42, in a single module. The total number of motor stages used can be minimized. Therefore, the inkjet nozzle module 100 may provide a positional accuracy within 1 μm in positioning the nozzle tip 42 . In addition, since a plurality of nozzles 40 may be attached to a single module, different types of ink may be used, and thus may be used in various processes.

FIG. 5 is a diagram illustrating an operation of the inkjet nozzle module after the inkjet process is completed in the repair apparatus of the substrate 400 including the inkjet nozzle module of FIG. 1 . Referring to FIG. 5 , an apparatus for repairing a substrate 400 according to an embodiment may include an inkjet nozzle module 100 , a gantry unit (not shown), an optical unit 200 , a controller (not shown), and the like. . Since the inkjet nozzle module 100 has been described above, a detailed description thereof will be omitted below. The gantry unit (not shown) is a member on which the inkjet nozzle module 100 is mounted, and may move in the horizontal direction in the space above the substrate 400 by a separate XY stage. Such a gantry part can be quickly moved to a work area for repair, etc. through its macroscopic behavior.

The optical unit 200 is installed in the gantry unit, and is formed to have an optical path coaxial with the optical path of the laser beam generated from the laser unit. The optical unit 200 may include, for example, a vision camera, a plurality of lenses, and a mirror. On the other hand, the inkjet process through the inkjet nozzle module 100 is confirmed through the image by the optical unit (200). That is, the apparatus for repairing the substrate 400 according to an embodiment may also check the operation process of the inkjet process in real time through the optical unit 200 for the laser unit. Here, the inkjet process may vary depending on the type of ink. This includes a repair process and the like, as described above.

To this end, the nozzle tip 42 is located in the photographing area D of the optical unit 200 at the jetting position JP. Meanwhile, when the inkjet process is finished, the nozzle tip 42 is moved from the jetting position JP to the ready position RP by a swivel motion. After that, the nozzle tip 42 is moved so as to depart within the imaging area D by the X-axis or Y-axis motion by the XYZ stage 10 . That is, the nozzle 40 according to an embodiment may move in the X-axis or Y-axis direction when the nozzle tip 42 is in the ready position RP.

Meanwhile, an optical Z stage 300 for changing the Z-axis position of the optical unit 200 may be further formed between the gantry and the optical unit 200 . This optical Z stage 300 may raise or lower the optical unit 200 in the vertical direction. The controller (not shown) may control each motor used for the XYZ stage 10 , the swivel stage 20 , the optical Z stage 300 , and the movement of the gantry constituting the inkjet nozzle module 100 . The controller may control each nozzle 40 for discharging ink.

Among the inkjet processes using the repair apparatus of the substrate 400 , for example, when the repair process is finished, a sintering process of curing the ejected ink using a laser beam is followed. In this sintering process, the optical unit 200 is used and is limited to the repaired part. And at this time, if the optical unit 200 is used, the time required to determine the position of the optical unit 200 can be saved, thereby reducing the tact time.

In addition, the apparatus for repairing the substrate 400 according to another embodiment may use the inkjet nozzle module 100 in the process of forming the color filter layer again after the sintering process. This may be possible by changing the nozzle used by the swivel motion by the swivel stage 20 . That is, it depends on a process in which a certain color is ejected, for example, nozzle 3 is selected. As a result, the tip of the nozzle 3 can be moved and changed to the ready position RP.

In this way, the repair apparatus of the substrate 400 is changed from a method in which the positions were determined for each nozzle to a single positioning method for a nozzle group consisting of a plurality of nozzles 40, thereby reducing the overall number of axial stages. . As a result, the accuracy of positioning can be further improved.

In the above, preferred embodiments of the present invention have been exemplarily described, but the scope of the present invention is not limited only to such specific embodiments, and can be appropriately changed within the scope described in the claims.

100: inkjet nozzle module 10: XYZ stage
20: swivel stage 30: nozzle holder
40: nozzle 42: nozzle tip
RP : Ready Witch JP : Jet Witch
200: optical unit 300: optical Z stage
400: substrate D: imaging area

Claims (9)

In the inkjet nozzle module for discharging ink from the nozzle toward the substrate,
an XYZ stage moving through a three-axis motion to an upper spatial position of the substrate;
a swivel stage coupled to the XYZ stage and changing the Z-axis position with respect to the nozzle tip;
The swivel motion is added to the inkjet nozzle module including; a nozzle holder coupled to the swivel stage and allowing the nozzle to be attached and detached. According to claim 1, wherein the swivel stage
An inkjet nozzle module with a swivel motion that provides a swivel motion so that the nozzle tip is moved from a ready position to a jetting position where ink is ejected. 3. The method of claim 2,
The Z-axis distance between the ready position and the jetting position is an inkjet nozzle module with a swivel motion of less than 10mm. According to claim 1,
At least one nozzle is coupled to the nozzle holder,
In the coupled state, the Z-axis position with respect to the nozzle tip is an inkjet nozzle module with a swivel motion that gradually increases from the middle point of the nozzle holder to the both ends. According to claim 1,
When a plurality of nozzles are combined, an inkjet nozzle module with a swivel motion in which a used nozzle is changed between the nozzles by driving by the swivel stage. According to claim 1,
The inkjet nozzle module according to any one of claims 1 to 5;
a gantry unit to which the inkjet nozzle module is mounted; and
It is installed in the gantry unit, the optical unit is formed to have an optical path coaxial with the optical path of the laser beam generated from the laser unit; includes;
The substrate repair apparatus, characterized in that the inkjet process through the inkjet nozzle module is confirmed through the image by the optical unit. 7. The method of claim 6,
An optical Z stage for changing a Z-axis position of the optical unit is further formed between the gantry and the optical unit. 7. The method of claim 6,
The nozzle tip is a substrate repair device located in the photographing area of the optical unit in the jetting position. 9. The method of claim 8,
When the inkjet process is finished,
After the nozzle tip is moved from the jetting position to the ready position by the swivel motion, the repair apparatus of the substrate is moved so as to be separated from the photographing area by the X-axis or Y-axis motion by the XYZ stage.

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