KR102510212B1 - Template for supporting mask and producing method of mask integrated frame - Google Patents

Abstract

The present invention relates to a mask support template and a method of manufacturing a frame-integrated mask. A mask support template according to the present invention is a template supporting a mask for forming an OLED pixel to correspond to a frame, comprising: a template; Temporary adhesive formed on the template; and a mask having a mask pattern formed on the template while being adhered to the template via the temporary adhesive portion, wherein the temporary adhesive portion is formed on the entire surface of the template and the entire surface of the mask corresponding to the temporary adhesive portion is adhered.

Description

Method for manufacturing mask support template and frame integrated mask {TEMPLATE FOR SUPPORTING MASK AND PRODUCING METHOD OF MASK INTEGRATED FRAME}

The present invention relates to a mask support template and a method of manufacturing a frame-integrated mask. More specifically, it is possible to stably support and move the mask without deformation, and when the mask is integrated with the frame, the adhesion between the mask and the frame can be improved, and the alignment between each mask can be made clear. It relates to a mask support template and a method for manufacturing a frame-integrated mask.

As a technology for forming pixels in the OLED manufacturing process, the FMM (Fine Metal Mask) method, which deposits organic materials on a desired location by attaching a thin metal shadow mask to the substrate, is mainly used.

In the existing OLED manufacturing process, a mask is manufactured in a stick shape, plate shape, etc., and then the mask is welded and fixed to the OLED pixel deposition frame. A plurality of cells corresponding to one display may be provided in one mask. In addition, several masks can be fixed to the OLED pixel deposition frame for manufacturing large-area OLEDs. In the process of fixing to the frame, each mask is tensioned so that it is flat. It is a very difficult task to adjust the tension so that the entire part of the mask is flat. In particular, in order to flatten each cell and align a mask pattern that is only a few to several tens of μm in size, a high level of work is required to check the alignment in real time while finely adjusting the tensile force applied to each side of the mask. do.

Nevertheless, in the process of fixing a plurality of masks to one frame, there is a problem in that alignment between masks and between mask cells is not good. In addition, in the process of fixing the mask to the frame by welding, the thickness of the mask film is too thin and has a large area, so the mask is sagging or distorted by the load, and wrinkles and burrs generated at the welded part during the welding process cause the mask cell to deteriorate. There was a problem with the alignment being staggered.

In the case of ultra-high-definition OLED, the current QHD picture quality is 500 to 600 PPI (pixel per inch), with a pixel size of about 30 to 50 μm, and 4K UHD and 8K UHD high-definition are higher than this, such as ~860 PPI and ~1600 PPI. has a resolution of In this way, considering the pixel size of ultra-high-definition OLED, the alignment error between each cell must be reduced to about several micrometers, and an error that deviate from this can lead to failure of the product, so the yield can be very low. Therefore, there is a need to develop a technology capable of preventing deformation such as drooping or twisting of the mask and clarifying the alignment, a technology of fixing the mask to the frame, and the like.

Accordingly, an object of the present invention is to provide a mask support temple capable of stably supporting and moving a mask without deformation.

Another object of the present invention is to provide a mask support template capable of improving adhesion between a mask and a frame when attaching a mask to a frame.

Another object of the present invention is to provide a mask support template that can be repeatedly used after attaching a mask to a frame.

In addition, an object of the present invention is to provide a method of manufacturing a frame-integrated mask in which a mask and a frame can form an integral structure.

In addition, an object of the present invention is to provide a method of manufacturing a frame-integrated mask capable of preventing deformation such as drooping or twisting of the mask and clarifying alignment.

In addition, an object of the present invention is to provide a method for manufacturing a frame-integrated mask that significantly reduces manufacturing time and significantly increases yield.

The above object of the present invention is a method of manufacturing a template for supporting a mask for forming an OLED pixel and corresponding to a frame, comprising: (a) providing a mask metal film; (b) bonding a mask metal film onto a template having a temporary bonding portion formed on one surface thereof; and (c) manufacturing a mask by forming a mask pattern on the mask metal film.

Between steps (b) and (c), a step of reducing the thickness of the mask metal film adhered to the template may be further included.

The temporary adhesive portion may be an adhesive or adhesive sheet that can be separated by application of heat, or an adhesive or adhesive sheet that can be separated by UV irradiation.

The temporary adhesive portion may be formed on the entire surface of the template, and a mask metal film may be adhered to the entire surface of the temporary adhesive portion.

And, the above object of the present invention, as a template for supporting a mask for forming an OLED pixel to correspond to a frame, the template; Temporary adhesive formed on the template; and a mask attached to the template via the temporary adhesive portion and having a mask pattern formed thereon.

The temporary adhesive portion may be formed on the entire surface of the template, and a mask metal film may be adhered to the entire surface of the temporary adhesive portion.

And, the above object of the present invention is a method of manufacturing a frame-integrated mask in which at least one mask and a frame supporting the mask are integrally formed, (a) on a frame having at least one mask cell region, the template loading a mask to correspond to the mask cell region of the frame; and (b) attaching the mask to the frame.

According to the present invention configured as described above, there is an effect of stably supporting and moving the mask without deformation.

In addition, according to the present invention, when attaching the mask to the frame, there is an effect of improving the adhesion between the mask and the frame.

In addition, according to the present invention, there is an effect that can be used repeatedly after attaching the mask to the frame.

In addition, according to the present invention, there is an effect that the mask and the frame can form an integral structure.

In addition, according to the present invention, there is an effect of preventing deformation such as drooping or twisting of the mask and clarifying the alignment.

In addition, according to the present invention, there is an effect of significantly reducing the manufacturing time and significantly increasing the yield.

1 is a schematic diagram showing a conventional OLED pixel deposition mask.
2 is a schematic diagram showing a process of attaching a conventional mask to a frame.
3 is a schematic diagram illustrating alignment errors between cells in the process of stretching a conventional mask.
4 is a front view and a side cross-sectional view illustrating a frame-integrated mask according to an embodiment of the present invention.
5 is a front view and a side cross-sectional view showing a frame according to an embodiment of the present invention.
6 is a schematic diagram showing a manufacturing process of a frame according to an embodiment of the present invention.
7 is a schematic diagram showing a manufacturing process of a frame according to another embodiment of the present invention.
8 is a schematic diagram showing a mask for forming a conventional high-resolution OLED.
9 is a schematic diagram showing a mask according to an embodiment of the present invention.
10 is a schematic diagram illustrating a process of manufacturing a mask metal film by a rolling method according to an embodiment of the present invention.
11 is a schematic diagram illustrating a process of manufacturing a mask metal film according to another embodiment of the present invention using an electroforming method.
12 to 13 are schematic diagrams illustrating a process of manufacturing a mask support template by attaching a mask metal film to a template and forming a mask according to an embodiment of the present invention.
14 is an enlarged cross-sectional schematic view showing a temporary adhesive part according to an embodiment of the present invention.
15 is a schematic diagram illustrating a process of loading a mask support template onto a frame according to an embodiment of the present invention.
16 is a schematic diagram illustrating a state in which a mask corresponds to a cell region of a frame by loading a template onto a frame according to an embodiment of the present invention.
17 is a schematic diagram illustrating a process of separating a mask and a template after attaching a mask to a frame according to an embodiment of the present invention.
18 is a schematic diagram showing a state in which a mask is attached to a frame according to an embodiment of the present invention.
19 is a schematic diagram illustrating an OLED pixel deposition apparatus using a frame-integrated mask according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention which follows refers to the accompanying drawings which illustrate, by way of illustration, specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable one skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different from each other but are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in one embodiment in another embodiment without departing from the spirit and scope of the invention. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all equivalents as claimed by those claims. Similar reference numerals in the drawings indicate the same or similar functions in various aspects, and the length, area, thickness, and the like may be exaggerated for convenience.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily practice the present invention.

1 is a schematic diagram showing a conventional mask 10 for OLED pixel deposition.

Referring to FIG. 1 , a conventional mask 10 may be manufactured in a stick-type or plate-type. The mask 10 shown in (a) of FIG. 1 is a stick-type mask, and both sides of the stick can be welded and fixed to the OLED pixel deposition frame. The mask 100 shown in (b) of FIG. 1 is a plate-type mask and can be used in a large-area pixel formation process.

A plurality of display cells C are provided on the body of the mask 10 (or the mask layer 11 ). One cell C corresponds to one display of a smartphone or the like. A pixel pattern P is formed in the cell C to correspond to each pixel of the display. When the cell C is enlarged, a plurality of pixel patterns P corresponding to R, G, and B appear. For example, a pixel pattern P is formed in the cell C to have a resolution of 70 X 140. That is, numerous pixel patterns P are clustered to form one cell C, and a plurality of cells C may be formed on the mask 10 .

2 is a schematic diagram showing a process of attaching a conventional mask 10 to a frame 20 . FIG. 3 is a schematic diagram illustrating alignment errors between cells in the process of stretching (F1 to F2) the conventional mask 10. As shown in FIG. The stick mask 10 having six cells (C: C1 to C6) shown in FIG. 1 (a) will be described as an example.

Referring to (a) of FIG. 2, first, the stick mask 10 should be flattened. As tensile forces (F1 to F2) are applied in the direction of the long axis of the stick mask 10 and pulled, the stick mask 10 is unfolded. In that state, the stick mask 10 is loaded on the frame 20 in the form of a square frame. The cells C1 to C6 of the stick mask 10 are positioned in the blank area inside the frame 20 . The frame 20 may be of such a size that the cells C1 to C6 of one stick mask 10 are positioned in an empty area inside the frame, and the cells C1 to C6 of the plurality of stick masks 10 may be positioned in an empty area inside the frame. It may be large enough to be located in an internal empty area.

Referring to (b) of FIG. 2, after aligning while finely adjusting the tensile forces (F1 to F2) applied to each side of the stick mask 10, welding (W) a part of the side of the stick mask 10 Accordingly, the stick mask 10 and the frame 20 are interconnected. 2(c) shows a cross-sectional side view of the frame and the stick mask 10 connected to each other.

Referring to FIG. 3 , although the tensile forces F1 to F2 applied to each side of the stick mask 10 are finely adjusted, there is a problem in that the mask cells C1 to C3 are not well aligned with each other. For example, an example is that the distances D1 to D1" and D2 to D2" between the patterns P of the cells C1 to C3 are different from each other or the patterns P are distorted. Since the stick mask 10 has a large area including a plurality of (eg, six) cells C1 to C6 and has a very thin thickness of several tens of μm, it is easily hit or distorted by a load. In addition, it is very difficult to check the alignment between the cells C1 to C6 in real time through a microscope while adjusting the tensile force F1 to F2 to flatten each cell C1 to C6.

Therefore, a slight error in the tensile force (F1 to F2) may cause an error in the extent to which each cell (C1 to C3) of the stick mask 10 is stretched or unfolded, and accordingly, the distance (D1) between the mask patterns (P) ~D1", D2~D2") causes a problem that they become different. Of course, it is difficult to perfectly align the error to zero, but the alignment error should not exceed 3 μm in order to prevent the mask pattern P having a size of several to several tens of μm from adversely affecting the pixel process of the ultra-high-definition OLED. It is preferable not to This alignment error between adjacent cells is referred to as pixel position accuracy (PPA).

In addition, about 6 to 20 stick masks 10 are connected to one frame 20, and between the stick masks 10, and a plurality of cells C of the stick mask 10 It is also a very difficult task to clarify the alignment between ~ C6), and the process time due to alignment inevitably increases, which is a significant reason for reducing productivity.

Meanwhile, after the stick mask 10 is connected and fixed to the frame 20 , tensile forces F1 to F2 applied to the stick mask 10 may act inversely to the frame 20 . That is, tension may be applied to the frame 20 after the stick mask 10 stretched tightly by the tensile forces F1 to F2 is connected to the frame 20 . Normally, this tension is not great and may not have a great effect on the frame 20 . However, when the size of the frame 20 is reduced and the rigidity is lowered, this tension may slightly deform the frame 20 . In this case, a problem in which an alignment state is distorted between the plurality of cells C to C6 may occur.

Accordingly, the present invention proposes a frame 200 and a frame-integrated mask enabling the mask 100 to form an integral structure with the frame 200 . The mask 100 integrally formed with the frame 200 can be prevented from deformation such as sagging or twisting, and can be clearly aligned with the frame 200 . When the mask 100 is connected to the frame 200, no tensile force is applied to the mask 100, so after the mask 100 is connected to the frame 200, tension to the extent that the frame 200 is deformed may not be applied. . In addition, the manufacturing time for integrally connecting the mask 100 to the frame 200 can be remarkably reduced, and the yield can be remarkably increased.

Figure 4 is a front view (Fig. 4 (a)) and a side cross-sectional view (Fig. 4 (b)) showing a frame-integrated mask according to an embodiment of the present invention, Figure 5 is according to an embodiment of the present invention It is a front view (FIG. 5 (a)) and a side sectional view (FIG. 5 (b)) showing the frame.

Referring to FIGS. 4 and 5 , the frame-integrated mask may include a plurality of masks 100 and one frame 200 . In other words, it is a form in which a plurality of masks 100 are attached to the frame 200 one by one. Hereinafter, for convenience of description, a square mask 100 will be described as an example, but the masks 100 may be in the form of a stick mask having protrusions clamped on both sides before being attached to the frame 200, and the frame 200 ), then the protrusion can be removed.

A plurality of mask patterns P may be formed on each mask 100 , and one cell C may be formed on one mask 100 . One mask cell C may correspond to one display of a smartphone or the like.

The mask 100 may be made of invar having a thermal expansion coefficient of about 1.0 X 10 ^-6 /°C or super invar having about 1.0 X 10 ^-7 /°C. Since the mask 100 made of this material has a very low coefficient of thermal expansion, there is little risk of deformation of the pattern shape of the mask by thermal energy, so it can be used as a fine metal mask (FMM) or shadow mask in high-resolution OLED manufacturing. In addition, considering that technologies for performing pixel deposition processes in a range where the temperature change value is not large are recently developed, the mask 100 is made of nickel (Ni) or nickel-cobalt (Ni-Co) having a slightly higher thermal expansion coefficient. ) and the like. The mask 100 may use a metal sheet produced by a rolling process or electroforming. It will be described later in detail with reference to FIGS. 9 and 10 .

The frame 200 is formed to attach a plurality of masks 100 thereto. The frame 200 may include several corners formed in a first direction (eg, a horizontal direction) and a second direction (eg, a vertical direction) including an outermost edge. These various corners may partition an area where the mask 100 is to be attached on the frame 200 .

The frame 200 may include an edge frame portion 210 having a substantially rectangular shape or a rectangular frame shape. The inside of the edge frame unit 210 may be hollow. That is, the edge frame unit 210 may include the hollow region R. The frame 200 may be made of a metal material such as invar, superinvar, aluminum, or titanium, and may be made of a material such as invar, superinvar, nickel, or nickel-cobalt having the same coefficient of thermal expansion as that of the mask in consideration of thermal deformation. Preferably, these materials may be applied to both the frame 210 and the mask cell sheet 220, which are components of the frame 200.

In addition, the frame 200 may include a plurality of mask cell regions CR, and may include a mask cell sheet portion 220 connected to the edge frame portion 210 . Like the mask 100, the mask cell sheet portion 220 may be formed by rolling, or may be formed using another film forming process such as electroplating. In addition, the mask cell sheet portion 220 may be connected to the edge frame portion 210 after forming a plurality of mask cell regions CR on a flat sheet through laser scribing, etching, or the like. Alternatively, in the mask cell sheet portion 220 , a plurality of mask cell regions CR may be formed through laser scribing or etching after connecting a flat sheet to the edge frame portion 210 . In this specification, it is mainly assumed that a plurality of mask cell regions CR are first formed on the mask cell sheet portion 220 and then connected to the frame frame portion 210 .

The mask cell sheet portion 220 may include at least one of the edge sheet portion 221 and the first and second grid sheet portions 223 and 225 . The edge sheet portion 221 and the first and second grid sheet portions 223 and 225 refer to portions partitioned from the same sheet, and are integrally formed with each other.

The rim sheet portion 221 may be substantially connected to the rim frame portion 210 . Accordingly, the rim sheet portion 221 may have a substantially rectangular shape or a rectangular frame shape corresponding to the rim frame portion 210 .

In addition, the first grid sheet portion 223 may extend in a first direction (horizontal direction). The first grid sheet portion 223 is formed in a straight line shape, and both ends may be connected to the edge sheet portion 221 . When the mask cell sheet portion 220 includes a plurality of first grid sheet portions 223, each first grid sheet portion 223 is preferably equally spaced apart.

In addition, the second grid sheet portion 225 may extend in the second direction (vertical direction). The second grid sheet portion 225 is formed in a straight line shape, and both ends may be connected to the edge sheet portion 221 . The first grid sheet portion 223 and the second grid sheet portion 225 may perpendicularly cross each other. When the mask cell sheet part 220 includes a plurality of second grid sheet parts 225, it is preferable that each second grid sheet part 225 form an equal interval.

Meanwhile, the distance between the first grid sheet parts 223 and the distance between the second grid sheet parts 225 may be the same or different depending on the size of the mask cell C.

The first grid sheet portion 223 and the second grid sheet portion 225 have a thin film-like thickness, but the shape of a cross section perpendicular to the longitudinal direction may be a rectangle, a quadrangular shape such as a trapezoid, or a triangular shape. The sides and corners may be partially rounded. The cross-sectional shape can be adjusted in the process of laser scribing, etching, etc.

The thickness of the edge frame portion 210 may be greater than that of the mask cell sheet portion 220 . Since the frame 210 is responsible for the overall rigidity of the frame 200, it may be formed to a thickness of several mm to several cm.

In the case of the mask cell sheet portion 220, it is difficult to manufacture a substantially thick sheet, and if the sheet is too thick, the organic material source 600 (see FIG. 19) passes through the mask 100 in the OLED pixel deposition process. It can cause blocking problems. Conversely, if the thickness is too thin, it may be difficult to secure enough rigidity to support the mask 100 . Accordingly, the mask cell sheet portion 220 is preferably thinner than the thickness of the edge frame portion 210 but thicker than the mask 100 . The mask cell sheet portion 220 may have a thickness of about 0.1 mm to about 1 mm. Also, the first and second grid sheet portions 223 and 225 may have a width of about 1 to 5 mm.

In the flat sheet, a plurality of mask cell regions CR (CR11 to CR56) may be provided except for regions occupied by the edge sheet portion 221 and the first and second grid sheet portions 223 and 225 . From another point of view, the mask cell region CR is the region occupied by the edge sheet portion 221 and the first and second grid sheet portions 223 and 225 in the hollow region R of the edge frame portion 210. Except for , it may mean an empty area.

As the cell C of the mask 100 corresponds to the mask cell region CR, it can be substantially used as a passage through which the pixels of the OLED are deposited through the mask pattern P. As described above, one mask cell C corresponds to one display of a smartphone or the like. Mask patterns P constituting one cell C may be formed on one mask 100 . Alternatively, one mask 100 may include a plurality of cells C, and each cell C may correspond to each cell region CR of the frame 200, but clear alignment of the mask 100 is required. For this purpose, it is necessary to avoid the large-area mask 100, and the small-area mask 100 having one cell (C) is preferable. Alternatively, one mask 100 having a plurality of cells C may correspond to one cell region CR of the frame 200 . In this case, for clear alignment, it may be considered to correspond to the mask 100 having a small number of cells (C) of about 2-3.

The frame 200 includes a plurality of mask cell regions CR, and each mask 100 may be attached such that one mask cell C corresponds to the mask cell region CR. Each mask 100 may include a mask cell C on which a plurality of mask patterns P are formed and a dummy around the mask cell C (corresponding to a portion of the mask film 110 excluding the cell C). there is. The dummy may include only the mask layer 110 or may include the mask layer 110 on which a predetermined dummy pattern similar to the mask pattern P is formed. The mask cell C corresponds to the mask cell region CR of the frame 200, and part or all of the dummy may be attached to the frame 200 (mask cell sheet portion 220). Accordingly, the mask 100 and the frame 200 can form an integral structure.

Meanwhile, according to another embodiment, the frame is not manufactured by attaching the mask cell sheet part 220 to the frame frame part 210, but the frame part 210 is attached to the hollow region R of the frame frame part 210. ) and integral grid frames (corresponding to the grid sheet portions 223 and 225) may be used. A frame of this type also includes at least one mask cell region CR, and a frame integrated mask can be manufactured by making the mask 100 correspond to the mask cell region CR.

Hereinafter, a process of manufacturing a frame-integrated mask will be described.

First, the frame 200 described above in FIGS. 4 and 5 may be provided. Figure 6 is a schematic diagram showing a manufacturing process of the frame 200 according to an embodiment of the present invention.

Referring to (a) of FIG. 6 , an edge frame unit 210 is provided. The edge frame unit 210 may have a rectangular frame shape including a hollow region R.

Next, referring to (b) of FIG. 6 , a mask cell sheet portion 220 is manufactured. The mask cell sheet portion 220 is manufactured by manufacturing a flat sheet using rolling, electroplating, or other film forming processes, and then removing portions of the mask cell region (CR) through laser scribing, etching, or the like. can do. In this specification, an example in which a 6 X 5 mask cell region (CR: CR11 to CR56) is formed will be described. Five first grid sheet parts 223 and four second grid sheet parts 225 may exist.

Next, the mask cell sheet portion 220 may correspond to the edge frame portion 210 . In the process of matching, all sides of the mask cell sheet portion 220 are stretched (F1 to F4) to flatten the mask cell sheet portion 220, and the edge sheet portion 221 is attached to the frame frame portion 210. can respond Even on one side, the mask cell sheet portion 220 may be held and stretched at several points (eg, 1 to 3 points in the example of FIG. 6(b) ). Meanwhile, the mask cell sheet portion 220 may be stretched (F1, F2) along some lateral directions instead of all sides.

Next, when the mask cell sheet portion 220 corresponds to the edge frame portion 210, the edge sheet portion 221 of the mask cell sheet portion 220 may be attached by welding (W). It is preferable to weld (W) all sides so that the mask cell sheet part 220 can be firmly attached to the edge frame part 220 . The welding (W) should be performed as close as possible to the edge of the edge frame unit 210 so that the lifted space between the edge frame unit 210 and the mask cell sheet unit 220 can be reduced as much as possible and adhesion can be increased. The welding (W) part may be formed in a line or spot shape, and has the same material as the mask cell sheet part 220, and the edge frame part 210 and the mask cell sheet part 220 are integrally formed. It can be a medium to connect with.

7 is a schematic diagram showing a manufacturing process of a frame according to another embodiment of the present invention. In the embodiment of FIG. 6, the mask cell sheet portion 220 having the mask cell region CR is first manufactured and attached to the edge frame portion 210, but in the embodiment of FIG. 7, a flat sheet is formed on the edge frame portion ( 210), a mask cell region CR portion is formed.

First, as shown in (a) of FIG. 6 , an edge frame unit 210 including a hollow region R is provided.

Next, referring to (a) of FIG. 7 , a flat sheet (a flat mask cell sheet portion 220') may correspond to the frame portion 210 . The mask cell sheet portion 220' is in a planar state in which the mask cell region CR is not yet formed. During the correspondence process, all sides of the mask cell sheet portion 220' are stretched (F1 to F4) to correspond to the edge frame portion 210 while the mask cell sheet portion 220' is flattened. Even on one side, the mask cell sheet portion 220' can be held and stretched at several points (eg, 1 to 3 points in the example of FIG. 7(a)). Meanwhile, the mask cell sheet portion 220 ′ may be stretched (F1, F2) along some lateral directions instead of all sides.

Next, if the mask cell sheet portion 220' corresponds to the edge frame portion 210, the edge portion of the mask cell sheet portion 220' may be welded (W) and attached. It is preferable to weld (W) all sides so that the mask cell sheet part 220' can be firmly attached to the edge frame part 220. Welding (W) should be performed as close as possible to the edge of the edge frame portion 210 to reduce the lifted space between the frame portion 210 and the mask cell sheet portion 220' as much as possible and increase adhesion. The welding (W) part may be formed in the form of a line or a spot, and is made of the same material as the mask cell sheet part 220', and the frame part 210 and the mask cell sheet part 220' can be a medium that connects them integrally.

Next, referring to (b) of FIG. 7 , mask cell regions CR are formed on a planar sheet (planar mask cell sheet portion 220 ′). The mask cell region CR may be formed by removing the sheet in the mask cell region CR portion through laser scribing, etching, or the like. In this specification, an example in which a 6 X 5 mask cell region (CR: CR11 to CR56) is formed will be described. When the mask cell region CR is formed, the portion welded (W) to the edge frame portion 210 becomes the edge sheet portion 221, and five first grid sheet portions 223 and four second grids are formed. A mask cell sheet portion 220 having a sheet portion 225 may be configured.

8 is a schematic diagram showing a mask for forming a conventional high-resolution OLED.

In order to realize high-resolution OLED, the pattern size is being reduced, and the thickness of the mask metal film used for this needs to be thinned. As shown in (a) of FIG. 8 , in order to implement a high-resolution OLED pixel 6 , the pixel interval and pixel size in the mask 10' need to be reduced (PD -> PD'). In addition, in order to prevent non-uniform deposition of the OLED pixels 6 due to the shadow effect, it is necessary to form the pattern of the mask 10' to be inclined (14). However, in the process of forming (14) an inclined pattern on a thick mask (10') having a thickness (T1) of about 30 to 50 μm, patterning (13) suitable for a fine pixel spacing (PD') and pixel size is performed. Since it is difficult to do, it becomes a cause of poor yield in the processing process. In other words, in order to form (14) an inclined pattern with a fine pixel spacing PD', a thin mask 10' should be used.

In particular, for a high resolution of the UHD level, as shown in FIG. In addition, for ultra-high resolution of UHD or higher, the use of a thin mask 10' having a thickness T2 of about 10 μm may be considered.

9 is a schematic diagram showing a mask 100 according to an embodiment of the present invention.

The mask 100 may include mask cells C on which a plurality of mask patterns P are formed and dummy DMs around the mask cells C. It has been described above that the mask 100 may be manufactured from a metal sheet produced through a rolling process, electroforming plating, or the like, and that one cell C may be formed in the mask 100 . The dummy DM corresponds to a portion of the mask film 110 (mask metal film 110) excluding the cell C, and includes only the mask film 110 or a predetermined dummy having a shape similar to that of the mask pattern P. A patterned mask layer 110 may be included. A part or all of the dummy DM may be attached to the frame 200 (mask cell sheet portion 220) corresponding to the edge of the mask 100.

The width of the mask pattern P may be less than 40 μm, and the thickness of the mask 100 may be about 5 μm to 20 μm. Since the frame 200 includes a plurality of mask cell regions (CR: CR11 to CR56), the mask 100 has mask cells (C: C11 to C56) corresponding to each of the mask cell regions (CR: CR11 to CR56). ) may also be provided with a plurality.

One surface 101 of the mask 100 is preferably flat because it is a surface to be attached by contacting the frame 200 . One surface 101 may be flattened and mirror-finished through a planarization process to be described later. The other surface 102 of the mask 100 may face one surface of the template 50 to be described later.

Hereinafter, the mask metal film 110 ′ is manufactured, supported by the template 50 to manufacture the mask 100, and the template 50 supported by the mask 100 is loaded onto the frame 200. A series of processes for manufacturing a frame-integrated mask by attaching the mask 100 to the frame 200 will be described.

10 is a schematic diagram illustrating a process of manufacturing a mask metal film by a rolling method according to an embodiment of the present invention. 11 is a schematic diagram illustrating a process of manufacturing a mask metal film according to another embodiment of the present invention by an electroforming method.

First, the mask metal film 110 may be prepared. As an example, the mask metal film 110 may be prepared by a rolling method.

Referring to (a) of FIG. 10 , a metal sheet produced through a rolling process may be used as the mask metal film 110'. The metal sheet manufactured by the rolling process may have a thickness of several tens to hundreds of μm due to the manufacturing process. As described above in FIG. 8 , fine patterning can be performed only when a thin mask metal film 110 having a thickness of about 20 μm or less is used for high resolution of the UHD level, and a thickness of about 10 μm for ultra high resolution of UHD or higher. It is necessary to use a thin mask metal film 110 having . However, since the mask metal film 110' formed by the rolling process has a thickness of about 25 to 500 μm, it needs to be made thinner.

Accordingly, a process of planarizing (PS) one surface of the mask metal film 110' may be further performed. Here, the planarization (PS) means to reduce the thickness of the mask metal film 110' by removing a part of the upper part of the mask metal film 110' while mirror-finishing one surface (upper surface) of the mask metal film 110'. The planarization (PS) may be performed by a chemical mechanical polishing (CMP) method, and a known CMP method may be used without limitation. In addition, the thickness of the mask metal layer 110' may be reduced by chemical wet etching or dry etching. In addition to this, a planarization process capable of thinning the thickness of the mask metal film 110' may be used without limitation.

In the process of performing the planarization (PS), for example, in the CMP process, the surface roughness (R _a ) of the upper surface of the mask metal layer 110' may be controlled. Preferably, mirror polishing in which the surface roughness is further reduced may be performed. Alternatively, as another example, after planarization (PS) is performed by performing a chemical wet etching or dry etching process, the surface roughness (R _a ) may be reduced by adding a polishing process such as a separate CMP process thereafter.

In this way, the thickness of the mask metal layer 110' can be made as thin as about 50 μm or less. Accordingly, the mask metal film 110 preferably has a thickness of about 2 μm to about 50 μm, more preferably about 5 μm to about 20 μm. However, it is not necessarily limited thereto.

Referring to (b) of FIG. 10 , similarly to (a) of FIG. 10 , the mask metal film 110 may be manufactured by reducing the thickness of the mask metal film 110 ′ manufactured through a rolling process. However, the thickness of the mask metal film 110' may be reduced by performing a planarization (PS) process while being adhered to the template 50 to be described later via a temporary bonding portion 55.

As another embodiment, the mask metal film 110 may be prepared by an electroforming method.

Referring to (a) of FIG. 11 , a conductive substrate 21 is prepared. To perform electroforming, the substrate 21 of the mother plate may be a conductive material. The mother plate can be used as a cathode electrode in electroplating.

As a conductive material, in the case of metal, metal oxides may be generated on the surface, impurities may flow in during the metal manufacturing process, in the case of a polycrystalline silicon substrate, inclusions or grain boundaries may exist, and conductive polymers In the case of a base material, there is a high possibility of containing impurities, and strength. Acid resistance may be weak. Elements that hinder the uniform formation of an electric field on the surface of the mother plate (or cathode body), such as metal oxides, impurities, inclusions, and grain boundaries, are referred to as “defects”. Due to a defect, a uniform electric field cannot be applied to the cathode body made of the above-described material, and thus a portion of the plating film 110 (or the mask metal film 110) may be non-uniformly formed.

In implementing ultra-high-definition pixels of UHD level or higher, non-uniformity of a plating film and a plating film pattern (mask pattern P) may adversely affect pixel formation. For example, in the case of the current QHD picture quality, the pixel size reaches about 30 ~ 50㎛ with 500 ~ 600 PPI (pixel per inch), and in the case of 4K UHD and 8K UHD high-definition, ~860 PPI and ~1600 PPI are higher than this. resolution, etc. A micro-display applied directly to a VR device or a micro-display used by being inserted into a VR device aims for ultra-high resolution of about 2,000 PPI or higher, and the pixel size reaches about 5 to 10 μm. Since the pattern width of the FMM and shadow mask applied to this can be formed in a size of several to several tens of μm, preferably smaller than 30 μm, even a defect of several μm in size is large enough to occupy a large portion in the pattern size of the mask. am. In addition, in order to remove defects in the cathode body of the above-described material, an additional process for removing metal oxide, impurities, etc. may be performed, and in this process, another defect such as etching of the anode body material may be induced. there is.

Therefore, in the present invention, a mother plate (or a cathode body) made of a single crystal material may be used. In particular, it is preferably a single crystal silicon material. In order to have conductivity, high-concentration doping of 10 ¹⁹ /cm ³ or more may be performed on the mother plate made of single crystal silicon. Doping may be performed on the entire mother plate or only on the surface portion of the mother plate.

On the other hand, single crystal materials include metals such as Ti, Cu, and Ag, semiconductors such as GaN, SiC, GaAs, GaP, AlN, InN, InP, and Ge, and carbon-based materials such as graphite and graphene. , CH ₃ NH ₃ PbCl ₃ , CH ₃ NH ₃ PbBr ₃ , CH ₃ NH ₃ PbI ₃ , single crystal ceramics for superconductors such as perovskite structures including SrTiO ₃ , single crystal superheat-resistant alloys for aircraft parts etc. can be used. In the case of metal and carbon-based materials, they are basically conductive materials. In the case of a semiconductor material, high-concentration doping of 10 ¹⁹ /cm ^{3 or} more may be performed to have conductivity. In the case of other materials, conductivity may be formed by performing doping or forming oxygen vacancies. Doping may be performed on the entire mother plate or only on the surface portion of the mother plate.

Since there is no defect in the case of a single crystal material, there is an advantage in that a uniform plating film 110 can be generated due to the formation of a uniform electric field on the entire surface during electroplating. The frame-integrated masks 100 and 200 manufactured through a uniform plating film can further improve the quality level of OLED pixels. In addition, since there is no need to perform an additional process for removing or resolving defects, there is an advantage in that process costs are reduced and productivity is improved.

Referring again to (a) of FIG. 10, next, the conductive substrate 21 is used as a mother plate (cathode body), and the anode body (not shown) is spaced apart from the conductive substrate 21. Then, the plating film 110 (or the mask metal film 110) may be formed by electroplating. The plating layer 110 may be formed on the exposed upper and side surfaces of the conductive substrate 21 that faces the anode body and may have an electric field. In addition to the side surface of the conductive substrate 21 , the plating layer 110 may be formed even on a part of the lower surface of the conductive substrate 21 .

Next, the edge portion of the plating film 110 is cut (D) with a laser, or a photoresist layer is formed on the plating film 110 and only the exposed portion of the plating film 110 is etched and removed (D). can Accordingly, as shown in (b) of FIG. 10 , the plating film 110 may be separated from the conductive substrate 21 .

Meanwhile, heat treatment (H) may be performed before separating the plating layer 110 from the conductive substrate 21 . In the present invention, in order to lower the thermal expansion coefficient of the mask 100 and prevent deformation due to heat of the mask 100 and the mask pattern P, the plating film ( 110) is characterized in that heat treatment (H) is performed before separation. Heat treatment may be performed at a temperature of 300 °C to 800 °C.

In general, compared to invar thin plates produced by rolling, invar thin plates produced by electroplating have a higher coefficient of thermal expansion. Thus, the thermal expansion coefficient can be lowered by performing heat treatment on the invar thin plate, and peeling, deformation, etc. may occur in the invar thin plate during the heat treatment process. This is a phenomenon that occurs because only the invar thin plate is heat treated or the invar thin plate temporarily attached only to the upper surface of the conductive substrate 21 is heat treated. However, since the plating film 110 is formed not only on the upper surface of the conductive substrate 21 but also on some of the side and lower surfaces of the conductive substrate 21, peeling or deformation does not occur even when heat treatment (H) is performed. In other words, since the heat treatment is performed in a state where the conductive substrate 21 and the plating film 110 are closely attached, peeling and deformation due to the heat treatment are prevented and the heat treatment can be stably performed.

The thickness of the mask metal film 110 formed through the electroforming process may be smaller than that of the rolling process. Accordingly, the planarization (PS) process for reducing the thickness may be omitted, but since the etching characteristics may vary depending on the composition and crystal structure/microstructure of the surface layer of the plating mask metal film 110', the planarization (PS) may be performed. Through this, it is necessary to control the surface properties and thickness.

12 to 13 are schematic diagrams illustrating a process of manufacturing a mask support template by attaching a mask metal film 110 to a template 50 and forming a mask 100 according to an embodiment of the present invention.

Referring to (a) of FIG. 12, a template 50 may be provided. The template 50 is a medium that allows the mask 100 to be attached to one surface and moved in a supported state. One surface of the template 50 is preferably flat so as to support and move the flat mask 100 . The central portion 50a may correspond to the mask cell C of the mask metal layer 110 , and the edge portion 50b may correspond to the dummy DM of the mask metal layer 110 . The size of the template 50 may be a flat plate shape having a larger area than the mask metal layer 110 so that the mask metal layer 110 can be supported as a whole.

The template 50 is preferably made of a transparent material so that vision can be easily observed during the process of aligning and attaching the mask 100 to the frame 200 . In addition, in the case of a transparent material, a laser may penetrate. As a transparent material, materials such as glass, silica, heat-resistant glass, quartz, alumina (Al ₂ O ₃ ), borosilicate glass, and zirconia may be used. For example, the template 50 may use BOROFLOAT ^® 33 material having excellent heat resistance, chemical durability, mechanical strength, and transparency among borosilicate glass. In addition, BOROFLOAT ^® 33 has a thermal expansion coefficient of about 3.3 and a difference in thermal expansion coefficient from that of the mask metal film 110 is small, so that the mask metal film 110 can be easily controlled.

Meanwhile, in the template 50, one surface in contact with the mask metal film 110 should be a mirror surface so that an air gap does not occur between the interface with the mask metal film 110 (or the mask 100). can In consideration of this, the surface roughness (Ra) of one surface of the template 50 may be 100 nm or less. In order to implement the template 50 having a surface roughness (Ra) of 100 nm or less, the template 50 may use a wafer. The wafer has a surface roughness (Ra) of about 10 nm, and since there are many products on the market and many surface treatment processes are known, it can be used as the template 50 . Since the surface roughness (Ra) of the template 50 is in the nm scale, there is no or almost no air gap, and it is easy to generate a welding bead WB by laser welding, which affects the alignment error of the mask pattern P. may not give

The template 50 has a laser pass-through hole 51 in the template 50 so that the laser L irradiated from the upper portion of the template 50 can reach the welding portion (region to be welded) of the mask 100. can be formed The laser pass-through hole 51 may be formed in the template 50 to correspond to the location and number of welded portions. Since a plurality of welding parts are disposed at predetermined intervals on the rim or the dummy DM portion of the mask 100, a plurality of laser pass-through holes 51 may also be formed at predetermined intervals to correspond thereto. For example, since a plurality of welding parts are disposed along a predetermined interval on the dummy DM on both sides (left/right) of the mask 100, the laser pass-through hole 51 also has the template 50 on both sides (left/right). A plurality may be formed along a predetermined interval.

The laser pass-through hole 51 does not necessarily correspond to the location and number of welded portions. For example, welding may be performed by irradiating the laser L to only some of the laser passage holes 51 . In addition, some of the laser pass-through holes 51 that do not correspond to the welded portion may be used instead of alignment marks when aligning the mask 100 and the template 50 . If the material of the template 50 is transparent to the laser L light, the laser pass-through hole 51 may not be formed.

A temporary adhesive portion 55 may be formed on one surface of the template 50 . The temporary adhesive portion 55 may be formed on the entire surface of the template 50 . The mask 100 (mask metal film 110) may be adhered to the entire surface of the temporary adhesive portion 55. The temporary adhesive portion 55 temporarily adheres the mask 100 (or the mask metal film 110 ) to one surface of the template 50 until the mask 100 is attached to the frame 200 . can be supported.

The temporary adhesive portion 55 may use an adhesive or adhesive sheet that can be separated by application of heat or an adhesive or adhesive sheet that can be separated by UV irradiation.

For example, the temporary adhesive part 55 may use liquid wax. The liquid wax may be the same as the wax used in the polishing step of a semiconductor wafer, etc., and the type is not particularly limited. The liquid wax is a resin component mainly for controlling adhesion, impact resistance, and the like for holding power, and may include substances and solvents such as acrylic, vinyl acetate, nylon, and various polymers. For example, the temporary adhesive portion 55 may use SKYLIQUID ABR-4016 containing acrylonitrile butadiene rubber (ABR) as a resin component and n-propyl alcohol as a solvent component. Liquid wax may be formed on the temporary adhesive portion 55 using spin coating.

The temporary adhesive portion 55, which is liquid wax, has lower viscosity at a temperature higher than 85°C to 100°C, increases viscosity at a temperature lower than 85°C, and may be partially hardened like a solid, so that the mask metal film 110' and the template 50 ) can be fixedly bonded.

Next, referring to (b) of FIG. 12 , a mask metal film 110 ′ may be attached to the template 50 . After heating the liquid wax to 85° C. or higher and bringing the mask metal film 110' into contact with the template 50, bonding may be performed by passing the mask metal film 110' and the template 50 between rollers. .

According to an embodiment, baking is performed on the template 50 at about 120° C. for 60 seconds to vaporize the solvent of the temporary adhesive portion 55, and a mask metal film lamination process may be performed immediately. . Lamination is carried out by loading the mask metal film 110' on the template 50 on which the temporary adhesive portion 55 is formed, and passing it between an upper roll at about 100 °C and a lower roll at about 0 °C. can As a result, the mask metal film 110 ′ may come into contact with the template 50 via the temporary bonding portion 55 .

14 is an enlarged cross-sectional schematic view showing a temporary adhesive part 55 according to an embodiment of the present invention. As another example, the temporary adhesive portion 55 may use a thermal release tape. In the thermal release tape, a core film 56 such as a PET film is disposed in the center, and thermal release adhesives 57a and 57b are disposed on both sides of the core film 56, and the adhesive layer 57a , 57b) may be in the form of disposing a release film/release film (58a, 58b) on the outside. Here, the adhesive layers 57a and 57b disposed on both sides of the core film 56 may have different peeling temperatures.

According to one embodiment, with the release films/release films 58a and 58b removed, the lower surface of the thermal release tape (second adhesive layer 57b) is adhered to the template 50, and the upper portion of the thermal release tape The surface (first adhesive layer 57a) may be adhered to the mask metal film 110'. Since the first adhesive layer 57a and the second adhesive layer 57b have different peeling temperatures, when the template 50 is separated from the mask 100 in FIG. 17 to be described later, the first adhesive layer 57a As heat for thermal separation is applied, the mask 100 can be separated from the template 50 and the temporary adhesive portion 55 .

Subsequently, further referring to FIG. 12(b) , one surface of the mask metal film 110' may be planarized (PS). As described above with reference to FIG. 10 , the thickness of the mask metal film 110' manufactured by the rolling process may be reduced (110' -> 110) by a planarization (PS) process. Also, a planarization (PS) process may be performed on the mask metal film 110 manufactured by the electroforming process to control the surface characteristics and thickness.

Accordingly, as shown in (c) of FIG. 12, as the thickness of the mask metal film 110' is reduced (110' -> 110), the mask metal film 110 will have a thickness of about 5 μm to 20 μm. can

Next, referring to (d) of FIG. 13 , a patterned insulating portion 25 may be formed on the mask metal layer 110 . The insulating portion 25 may be formed of a photoresist material using a printing method or the like.

Then, the mask metal layer 110 may be etched. Methods such as dry etching and wet etching may be used without limitation, and as a result of the etching, a portion of the mask metal layer 110 exposed to the empty space 26 between the insulating parts 25 may be etched. The etched portion of the mask metal layer 110 constitutes a mask pattern P, and a mask 100 having a plurality of mask patterns P formed thereon may be manufactured.

Next, referring to (e) of FIG. 13 , manufacturing of the template 50 supporting the mask 100 may be completed by removing the insulating portion 25 .

Since the frame 200 includes a plurality of mask cell regions (CR: CR11 to CR56), the mask 100 has mask cells (C: C11 to C56) corresponding to each of the mask cell regions (CR: CR11 to CR56). ) may also be provided with a plurality. In addition, a plurality of templates 50 supporting each of the plurality of masks 100 may be provided.

15 is a schematic diagram illustrating a process of loading a mask support template onto a frame according to an embodiment of the present invention.

Referring to FIG. 15 , the template 50 may be transferred by the vacuum chuck 90 . A surface opposite to the surface of the template 50 to which the mask 100 is attached may be suctioned and transferred by the vacuum chuck 90 . The vacuum chuck 90 may be connected to a moving means (not shown) that moves in the x, y, z, and θ axes. In addition, the vacuum chuck 90 may be connected to a flip means (not shown) capable of adsorbing and flipping the template 50 . As shown in (b) of FIG. 15, after the vacuum chuck 90 adsorbs and flips the template 50, the mask 100 is removed even in the process of transferring the template 50 onto the frame 200. Adhesion and alignment are unaffected.

16 is a schematic diagram illustrating a state in which a mask corresponds to a cell region of a frame by loading a template onto a frame according to an embodiment of the present invention. Although FIG. 16 illustrates that one mask 100 corresponds to/attached to the cell region CR, a plurality of masks 100 are simultaneously corresponded to all the cell regions CR, so that the mask 100 is applied to the frame 200. ) may be performed. In this case, a plurality of templates 50 supporting each of the plurality of masks 100 may be provided.

Next, referring to FIG. 16 , the mask 100 may correspond to one mask cell region CR of the frame 200 . By loading the template 50 onto the frame 200 (or the mask cell sheet portion 220), the mask 100 may correspond to the mask cell region CR. While controlling the positions of the template 50/vacuum chuck 90, it may be observed whether the mask 100 corresponds to the mask cell region CR through a microscope. Since the template 50 compresses the mask 100, the mask 100 and the frame 200 may closely contact each other.

Meanwhile, the lower support 70 may be further disposed under the frame 200 . The lower support 70 may have a size sufficient to fit within the hollow region R of the frame rim 210 and may have a flat plate shape. In addition, a predetermined support groove (not shown) corresponding to the shape of the mask cell sheet portion 220 may be formed on the upper surface of the lower support body 70 . In this case, the edge sheet portion 221 and the first and second grid sheet portions 223 and 225 are fitted into the support groove, so that the mask cell sheet portion 220 can be better fixed.

The lower support 70 may compress the opposite surface of the mask cell region CR, which the mask 100 contacts. That is, the lower support 70 supports the mask cell sheet portion 220 in an upward direction to prevent the mask cell sheet portion 220 from sagging downward during the bonding process of the mask 100 . At the same time, since the lower support 70 and the template 50 compress the edge of the mask 100 and the frame 200 (or the mask cell sheet portion 220) in opposite directions, the mask 100 The alignment state can be maintained without being disturbed.

In this way, simply by attaching the mask 100 on the template 50 and loading the template 50 onto the frame 200, the mask 100 is placed in a region corresponding to the mask cell region CR of the frame 200. Since the process is completed, no tensile force may be applied to the mask 100 during this process.

Subsequently, the mask 100 may be irradiated with a laser L to attach the mask 100 to the frame 200 by laser welding. A welding bead WB is generated at the weld portion of the laser-welded mask, and the welding bead WB has the same material as the mask 100/frame 200 and may be integrally connected.

17 is a schematic diagram illustrating a process of separating the mask 100 and the template 50 after attaching the mask 100 to the frame 200 according to an embodiment of the present invention.

Referring to FIG. 17 , after attaching the mask 100 to the frame 200 , the mask 100 and the template 50 may be debonded. Separation of the mask 100 and the template 50 may be performed by at least one of heat application (ET), chemical treatment (CM), ultrasonic application (US), and UV application (UV) to the temporary adhesive portion 55. there is. Since the mask 100 remains attached to the frame 200, only the template 50 can be lifted. For example, when heat at a temperature higher than 85° C. to 100° C. is applied (ET), the viscosity of the temporary adhesive portion 55 is lowered, and the adhesive force between the mask 100 and the template 50 is weakened. ) and the template 50 may be separated. As another example, the mask 100 and the template 50 may be separated by dissolving or removing the temporary adhesive portion 55 by immersing (CM) the temporary adhesive portion 55 in a chemical such as IPA, acetone, or ethanol. there is. As another example, when ultrasound is applied (US) or UV is applied (UV), the adhesive force between the mask 100 and the template 50 is weakened, and thus the mask 100 and the template 50 may be separated.

More specifically, since the temporary bonding portion 55 mediating the bonding between the mask 100 and the template 50 is a TBDB adhesive material (temporary bonding & debonding adhesive), various debonding methods can be used.

For example, a solvent debonding method according to chemical treatment (CM) may be used. As the temporary adhesive portion 55 is dissolved by penetration of a solvent, debonding may be performed. At this time, since the pattern P is formed on the mask 100 , the solvent may permeate through the mask pattern P and the interface between the mask 100 and the template 50 . Solvent debonding has the advantage of being relatively economical compared to other debonding methods because debonding is possible at room temperature and does not require a separately designed and complex debonding facility.

As another example, a heat debonding method according to heat application (ET) may be used. When the temporary adhesive portion 55 is decomposed using high-temperature heat and the adhesive strength between the mask 100 and the template 50 decreases, debonding may proceed in a vertical direction or a left-right direction.

As another example, a peelable adhesive debonding method according to heat application (ET), UV application (UV), or the like may be used. In the case where the temporary adhesive portion 55 is a heat release tape, debonding can be performed by a peel adhesive debonding method, and this method does not require high-temperature heat treatment and expensive heat treatment equipment like the heat debonding method, and the progress process has the advantage of being relatively simple.

As another example, a room temperature debonding method according to chemical treatment (CM), ultrasonic application (US), UV application (UV), etc. may be used. If a non-sticky treatment is applied to a part (central part) of the mask 100 or the template 50, only the edge part can be bonded by the temporary adhesive part 55. And, at the time of debonding, the debonding is performed by dissolution of the entrance examination adhesive portion 55 by penetrating the solvent into the edge portion. This method has the advantage that during bonding and debonding, there is no direct loss or defects due to adhesive material residue during debonding in the rest of the area except for the edge area of the mask 100 and the template 50 during bonding and debonding. there is In addition, unlike the thermal debonding method, since a high-temperature heat treatment process is not required during debonding, there is an advantage in that process costs can be relatively reduced.

18 is a schematic diagram showing a state in which the mask 100 is attached to the frame 200 according to an embodiment of the present invention.

Referring to FIG. 18 , one mask 100 may be attached to one cell region CR of the frame 200.

Since the mask cell sheet portion 220 of the frame 200 has a thin thickness, when it is attached to the mask cell sheet portion 220 with tension applied to the mask 100, the tension remaining in the mask 100 is applied to the mask. It may act on the cell sheet portion 220 and the mask cell region CR to deform them. Therefore, it is necessary to attach the mask 100 to the mask cell sheet portion 220 without applying a tensile force to the mask 100 . In the present invention, the mask 100 corresponds to the mask cell region CR of the frame 200 simply by attaching the mask 100 on the template 50 and loading the template 50 onto the frame 200. Since the process is completed, no tensile force may be applied to the mask 100 during this process. Thus, it is possible to prevent the frame 200 (or the mask cell sheet portion 220) from being deformed by the tensile force applied to the mask 100 acting as a tension to the frame 200 on the contrary.

The conventional mask 10 of FIG. 1 includes 6 cells (C1 to C6) and thus has a long length, whereas the mask 100 of the present invention includes 1 cell (C) and has a short length. The degree to which pixel position accuracy (PPA) is distorted may be reduced. For example, assuming that the length of the mask 10 including the plurality of cells C1 to C6, ... is 1 m, and a PPA error of 10 μm occurs in the entire length of 1 m, the mask 100 of the present invention may make the above error range 1/n according to the relative length reduction (corresponding to the reduction in the number of cells C). For example, if the length of the mask 100 of the present invention is 100 mm, since it has a length reduced from 1 m of the conventional mask 10 to 1/10, a PPA error of 1 μm occurs in the entire length of 100 mm, , there is an effect that the alignment error is significantly reduced.

Meanwhile, even if the mask 100 includes a plurality of cells C and each cell C corresponds to each cell region CR of the frame 200, within a range in which alignment errors are minimized, The mask 100 may correspond to a plurality of mask cell regions CR of the frame 200 . Alternatively, the mask 100 having a plurality of cells C may correspond to one mask cell region CR. Even in this case, it is preferable that the mask 100 includes as few cells C as possible in consideration of process time and productivity according to alignment.

In the case of the present invention, since it is only necessary to match one cell (C) of the mask 100 and check the alignment, a plurality of cells (C: C1 to C6) must be simultaneously matched and the alignment must be checked. Compared to the conventional method [see Fig. 2], the manufacturing time can be significantly reduced.

That is, in the frame-integrated mask manufacturing method of the present invention, each of the cells C11 to C16 included in the six masks 100 corresponds to one cell region CR11 to CR16 and checks the alignment state. Through one process, the time can be significantly reduced compared to the conventional method in which the six cells C1 to C6 must be simultaneously corresponded and the alignment states of the six cells C1 to C6 must be checked at the same time.

In addition, in the frame-integrated mask manufacturing method of the present invention, the product yield in 30 processes of matching and aligning 30 masks 100 to 30 cell regions (CR: CR11 to CR56), respectively, is 6 cells (C1 ~ C6) may appear much higher than the conventional product yield in the five processes of corresponding and aligning the five masks 10 (see Fig. 2 (a)) including each of the frames 20. Since the conventional method of arranging six cells C1 to C6 in an area corresponding to six cells C at a time is a much cumbersome and difficult task, the product yield is low.

Meanwhile, as described in step (b) of FIG. 12 , when attaching the mask metal film 110 to the template 50 through the lamination process, a temperature of about 100° C. may be applied to the mask metal film 110. . As a result, the mask metal film 110 may be adhered to the template 50 in a state where a partial tensile force is applied. After that, when the mask 100 is attached to the frame 200 and the template 50 is separated from the mask 100, the mask 100 may shrink by a predetermined amount.

When the template 50 and the masks 100 are separated after each mask 100 is attached to the corresponding mask cell region CR, tension is applied to contract the plurality of masks 100 in opposite directions. Because of this, the force is offset and deformation of the mask cell sheet portion 220 does not occur. For example, the first grid sheet portion 223 between the mask 100 attached to the CR11 cell area and the mask 100 attached to the CR12 cell area extends to the right of the mask 100 attached to the CR11 cell area. The tension acting and the tension acting in the left direction of the mask 100 attached to the CR12 cell region may be offset. Thus, deformation of the frame 200 (or the mask cell sheet portion 220) due to tension is minimized, so that an alignment error of the mask 100 (or the mask pattern P) can be minimized.

19 is a schematic diagram illustrating an OLED pixel deposition apparatus 1000 using frame-integrated masks 100 and 200 according to an embodiment of the present invention.

Referring to FIG. 19 , the OLED pixel deposition apparatus 1000 includes a magnet plate 300 in which a magnet 310 is accommodated and a cooling water line 350 is disposed, and an organic material source 600 from a lower portion of the magnet plate 300. ) and a deposition source supply unit 500 for supplying.

A target substrate 900 such as glass on which the organic material source 600 is deposited may be interposed between the magnet plate 300 and the source deposition unit 500 . The frame-integrated masks 100 and 200 (or FMM) for depositing the organic material source 600 pixel by pixel may be disposed on the target substrate 900 so as to be in close contact with or very close to each other. The magnet 310 generates a magnetic field and may adhere to the target substrate 900 by the magnetic field.

The deposition source supply unit 500 may supply the organic material source 600 by reciprocating left and right paths, and the organic material source 600 supplied from the deposition source supply unit 500 may form a pattern P formed on the frame integrated masks 100 and 200. ) and deposited on one side of the target substrate 900 . The deposited organic material source 600 passing through the pattern P of the frame-integrated masks 100 and 200 may serve as the pixel 700 of the OLED.

In order to prevent non-uniform deposition of the pixels 700 due to a shadow effect, the patterns of the frame-integrated masks 100 and 200 may be inclined (S) (or formed in a tapered shape (S)). . Since the organic material sources 600 passing through the pattern in a diagonal direction along the inclined surface may also contribute to the formation of the pixel 700, the pixel 700 may be deposited with a uniform thickness as a whole.

Since the mask 100 is attached and fixed to the frame 200 at a first temperature higher than the pixel deposition process temperature, even if the mask 100 is raised to the process temperature for pixel deposition, the position of the mask pattern P is hardly affected. The PPA between (100) and the mask (100) adjacent thereto may be maintained not to exceed 3 μm.

Although the present invention has been shown and described with preferred embodiments as described above, it is not limited to the above embodiments, and various variations can be made by those skilled in the art within the scope of not departing from the spirit of the present invention. Transformation and change are possible. Such modifications and variations are to be regarded as falling within the scope of this invention and the appended claims.

50: template
51: laser pass-through
55: temporary adhesive
70: lower support
100: mask
110: mask film
200: frame
210: border frame part
220: mask cell sheet portion
221: border seat portion
223: first grid sheet portion
225: second grid sheet portion
1000: OLED pixel deposition device
C: cell, mask cell
CM: chemical treatment
CR: mask cell area
DM: Dummy, Dummy Mask
ET: heat application
L: laser
R: Hollow area of the border frame part
P: mask pattern
US: ultrasound application
UV: Apply UV
W: welding
WB: weld bead

Claims (2)

As a template for adhesively supporting and moving a mask for forming OLED pixels onto a frame, attaching the mask in correspondence to the frame, and then separating the mask from the mask,
template;
Temporary adhesive formed on the template; and
A mask with a mask pattern attached to the template through the temporary adhesive part
including,
The temporary adhesive portion is formed on the entire surface of the template and the entire surface of the mask corresponding to the temporary adhesive portion is adhered, and the temporary adhesive portion can be separated by applying heat or can be separated by UV irradiation. It is a thermal release tape,
The mask can be matched to the frame only by controlling the position of the template, and after the mask is attached to the frame, the adhesive strength of the temporary adhesive portion of the template and the mask is weakened by either heat or UV applied to the temporary adhesive portion of the template. A mask support template, capable of detaching only the template from the mask attached to it. A method of manufacturing a frame-integrated mask in which at least one mask and a frame supporting the mask are integrally formed,
(a) loading a template according to claim 1 onto a frame having at least one mask cell region to correspond a mask to the mask cell region of the frame;
(b) attaching the mask to the frame;
(c) separating the template from the mask
A method of manufacturing a frame-integrated mask comprising a.

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