JP2006331973A - Manufacturing method of multiply imposed metal mask - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a manufacturing method of a multiply imposed metal mask, enhancing positional accuracy of an individual unit mask by reducing the frequency of mounting the unit masks to a multiple imposition frame, when a large sized multiply imposed metal mask is manufactured. <P>SOLUTION: First, the multiply imposing mask is divided to prepare divided metal masks 10R and 10L, the divided metal masks 10R and 10L are aligned to produce a composite metal mask 20, and the composite metal mask 20 is fixed to an imposition frame 30. The jointed region 13 of the composite metal mask 20 is plucked from a plucking line 15, and the divided metal masks 10R and the divided metal mask 10L are formed on the imposition frame 30. Thereby, this multiply imposed metal mask 100 which is formed by imposing 24 unit masks 11 is obtained. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for manufacturing a multi-faced metal mask used when forming a display medium of an organic electroluminescence (hereinafter referred to as organic EL) element by vapor deposition, sputtering, or the like.

  The organic EL element is self-luminous, so it has no viewing angle dependency, excellent visibility, fast response speed, low power consumption, suitable for video display, and simple structure. Since it has features such as being light and thin, it is one of the display elements that have attracted considerable attention.

  The organic EL element is configured by sequentially laminating a transparent electrode, an organic EL medium, and a metal electrode on a transparent substrate. For example, the organic EL medium is a single layer of an organic light emitting layer, or a medium of a three-layer structure of an organic hole transport layer, an organic light emitting layer and an organic electron transport layer, or a layer structure of an organic hole transport layer and an organic light emitting layer. And a laminated medium in which an electron or hole injection layer is inserted between these appropriate layers.

The matrix display type organic EL display panel is configured by sequentially laminating a row electrode including a transparent electrode layer, an organic EL medium, and a column electrode including a metal electrode layer intersecting the row electrode. The row electrodes are each formed in a strip shape and are arranged so as to be parallel to each other at a predetermined interval, and the same applies to the column electrodes.
As described above, the matrix display type organic EL display panel performs image display by arranging light emitting pixels made of organic EL elements at intersections of electrodes in a plurality of rows and columns.

On the other hand, in the manufacturing process of an organic EL display panel, an organic EL medium is formed after forming a transparent electrode layer on a transparent substrate. The organic EL medium is a thin film having one or more layers corresponding to the light emitting pixels, but is usually formed by an evaporation method using a metal mask.
This is because when the organic EL medium thin film is patterned by a commonly used photolithography method, the solvent in the photoresist penetrates into the organic EL medium thin film, the high temperature atmosphere in the resist baking, the resist developer or the etching solution. There is a problem that the characteristics of the obtained organic EL element deteriorate due to the penetration into the organic EL medium thin film and the damage to the organic EL medium thin film due to the plasma at the time of dry etching. An organic EL element is produced.

  When manufacturing an organic EL display panel, if the organic EL display panel is a small display panel, in order to increase manufacturing efficiency, the panel is manufactured using a large processing substrate on which a small organic EL panel is multifaceted. A multi-sided manufacturing process in which a desired organic EL display panel is manufactured by cutting and dividing is employed.

  In the step of manufacturing an organic EL element by a vapor deposition method using a metal mask in a multi-face manufacturing process of an organic EL display panel, a desired number of unit masks 120 as shown in FIGS. 6A and 6B are used. An impositioned metal mask 200 for multi-chamfering has been proposed (see, for example, Patent Document 1).

The multi-sided metal mask 200 is obtained by attaching a predetermined number (eight in this case) of unit metal masks 120 for vapor deposition to the multi-sided frame 111.
The unit metal mask 120 includes a metal frame 122 and a mask region 121, and the mask region 121 has a plurality of through openings (not shown) through which a vapor deposition material from a vapor deposition source passes. .

The unit metal mask 120 is manufactured by patterning nickel or stainless steel using a photo-etching method, and the metal frame 122 is spot welded to the edge of the opening 112 provided in the multi-faced frame 111 or attached by tape. (See FIGS. 7A and 7B).
An alignment mark for alignment with the unit metal mask 120 is applied to the edge of the opening 112 by laser marking or the like.

As described above, the multi-sided metal mask 200 is manufactured by attaching a predetermined number of unit metal masks 120 to the multi-sided frame 111, so that the display screen of the organic EL display panel is required to have a larger size and higher definition. In addition, there is a problem that the alignment accuracy when the unit metal mask 120 is attached to the multi-chamfer frame 111 cannot be fully handled.
Further, in the manufacturing process of the organic EL display panel, a large-sized multi-sided metal mask is required in order to increase the number of impositions on a single substrate and reduce the manufacturing cost of the organic EL display panel.
JP 2001-237073 A

  The present invention has been devised in view of the above problems and requirements.When manufacturing a large-sized multi-faced metal mask, the number of times the unit mask is attached to the multi-faced frame is reduced, and the position accuracy of each unit mask is increased. An object of the present invention is to provide a method for manufacturing a multi-faced metal mask that can be improved.

In order to achieve the above object, the present invention provides a method for producing a multi-faced metal mask characterized by comprising at least the following steps.
(A) Dividing a multi-sided mask in which a plurality of unit metal masks are arranged into blocks, and having a joining area on the outer periphery, an alignment fixing area having an alignment mark at an end, and a squeezed line A step of obtaining a metal mask.
(B) A step of producing a composite metal mask in which the alignment regions are fixed by aligning using the alignment marks of the alignment regions of the divided metal mask.
(C) The process of joining the joining area | region of a composite metal mask on the support frame of a multi-faced frame.
(D) A step of squeezing the mating and fixing region with a squeezing line.

In the method for manufacturing a multi-sided metal mask of the present invention, first, the multi-sided mask is divided to create a divided metal mask, and this divided metal mask is aligned to produce a composite metal mask. A multi-sided metal mask is manufactured by fixing to an imposition frame.
Therefore, even if the multi-faced metal mask is enlarged, if the size of the divided metal mask is set within a size that can be processed by a patterning processing apparatus that has been conventionally used, the existing metal mask patterning processing equipment can be used as it is.
In addition, since the composite metal mask is manufactured by aligning the divided metal masks and the multi-sided metal mask of a predetermined size is manufactured, the surface positioning accuracy of the unit metal mask can be confirmed, and the multi-sides with excellent positional accuracy An attached metal mask can be obtained.
Further, since the overlapping portion of the divided metal mask is removed after the composite metal mask is fixed to the imposition frame, the flatness of the metal mask can be ensured.

An embodiment of the method for manufacturing a multi-faced metal mask of the present invention will be described.
1A is a schematic plan view of a multi-faced metal mask 100 manufactured by the method for manufacturing a multi-faced metal mask, and FIG. 1B is a schematic plan view of FIG. FIG.
In the multi-faced metal mask 100 of this example, it is composed of two divided metal masks 10R and 10L, and the divided metal mask 10R and the divided metal mask 10L on which the unit mask 11 is 12-faced are the frame 21 of the imposition frame 30 and It is fixed on the support frame 22.

Hereinafter, the manufacturing method of the multi-faced metal mask of the present invention will be described.
When an organic EL display panel is manufactured recently, if the organic EL display panel is a small display panel, in order to reduce the cost of the panel and increase the manufacturing efficiency, the panel is manufactured using a large processing substrate with a multifaceted small organic EL panel. And a multi-sided manufacturing process is employed in which a desired organic EL display panel is manufactured by dividing into small pieces at the end.
A large-sized multi-sided metal mask is also used as an evaporation mask for manufacturing an EL element used in the multi-sided manufacturing process.

Multi-faced metal masks are manufactured by patterning nickel or stainless steel using photo-etching. Therefore, if the size of the multi-faced metal mask exceeds the size that can be processed by the patterning equipment, it is necessary to divide the multi-faced metal mask. There is.
As a result of intensive studies on how to accurately place the unit metal mask on the imposition frame when producing the divided multi-imposition metal mask, the present inventors have developed a method for producing a multi-imposition metal mask according to the present invention. It came to devise.

First, a multi-sided mask in which a plurality of unit metal masks are arranged is divided into blocks, and divided into divided metal masks in which a predetermined number of unit metal masks are arranged (see FIGS. 2A and 2B).
In this example, the unit metal mask 11 is composed of a divided metal mask 10R and a divided metal mask 10L each having 12 faces. The size of the divided metal mask 10R and the divided metal mask 10L is the above-described metal mask patterning processing equipment. It is determined by the size that can be handled.
Further, the number of impositions 12 of the unit metal mask 11 is merely an example, and is appropriately set depending on the sizes of the unit metal mask 11 and the multi-faced metal mask.

At the end portions of the divided metal mask 10R and the divided metal mask 10L, an alignment fixing region 14 for aligning and fixing the divided metal mask 10R and the divided metal mask 10L in advance is provided.
Moreover, the joining area | region 13 fixed to the support frame of an imposition frame is provided in the outer peripheral part of the division | segmentation metal mask.
An alignment mark 16 is provided in the alignment fixing region 14, and the alignment mark 16 is used to align the divided metal mask 10R and the divided metal mask 10L.

  In addition, a half-processed line or a perforated through-hole 15 is provided between the bonding region 13 and the alignment fixing region 14, and the bonding region 13 is fixed to the support frame of the imposition frame. After that, the alignment fixing region 14 where the divided metal mask 10R and the divided metal mask 10L overlap is removed from the squeezed line 15.

  Next, using the alignment marks 16 provided at the ends of the divided metal mask 10R and the divided metal mask 10L, the divided metal mask 10R and the divided metal mask 10L are aligned, and the alignment mark 16 in the alignment fixing region 14 is set. The region to be removed is subjected to spot welding, ultrasonic welding, or the like, and the composite metal mask 20 in which the divided metal mask 10R and the divided metal mask 10L are combined and fixed in the fixed region 14 is manufactured (see FIGS. 3A and 3B). .

Here, the alignment of the divided metal mask 10R and the divided metal mask 10L is performed by forming an alignment through hole as an alignment mark 16 so that the divided metal mask is prepared, and separately providing a guide pin having the same pitch as the alignment mark 16 on the substrate. Are prepared, and the alignment holes 16 are aligned by inserting the through holes of the divided metal mask 10R and the divided metal mask 10L into the guide pins, and the region excluding the alignment mark 16 in the alignment fixing region 14 is spot welded, ultrasonic It is most efficient to remove the alignment jig on which the guide pins are formed after welding or the like, and alignment can be performed with high accuracy.
Before aligning the divided metal mask 10R and the divided metal mask 10L and fixing them by spot welding, ultrasonic welding, etc., the pitch of the unit metal mask 11 is confirmed with a length measuring machine, etc. A metal mask can be obtained.

  As another alignment method, an alignment mark 16 is formed as an alignment mark 16 in the divided metal mask 10R, and a through hole is formed in the divided metal mask 10L so that the divided metal mask 10L is formed. The alignment can also be performed by looking into the alignment mark + of the divided metal mask 10R from the hole.

Next, as shown in FIGS. 4A and 4B, an imposition frame 30 including a frame 31 and a support frame 32 is produced.
The imposition frame 30 is made of an aluminum base material by photoetching, machining, pressing, or the like.

  Next, the composite metal mask 20 in which the divided metal mask 10R and the divided metal mask 10L are combined and fixed in the fixing region 14 is positioned and placed on the imposition frame 30, and the bonding region 13 of the composite metal mask 20 is formed. The composite metal mask 20 is fixed to the imposition frame 30 by performing spot welding, ultrasonic welding, etc. on the support frame 32 of the imposition frame 30 and the metal frame 12 of the complex metal mask 20 on the imposition frame 30 respectively. .

Further, the alignment fixing region 14 of the composite metal mask 20 is removed from the squeeze line 15 so that the divided metal mask 10R and the divided metal mask 10L are formed at predetermined positions on the imposition frame 30, and the unit metal mask 11 is 24. An impositioned multi-faced metal mask 100 is obtained (see FIGS. 1A and 1B).
Here, the alignment fixing region 14 of the composite metal mask 20 is removed from the squeeze line 15 by removing the overlapping portion of the alignment fixing region 14 between the divided metal mask 10R and the divided metal mask 10L. The flatness of the attached metal mask is ensured.
In the above-described method for manufacturing a multifaceted metal mask, the case where the number of divisions of the divided metal mask is two has been described. However, this is only an example, and the number of divisions of the divided metal mask is two or more. It doesn't matter how many.

Thus, in the method for producing a multi-faced metal mask of the present invention, first, the multi-faceted mask is divided to create a divided metal mask, and the divided metal mask is aligned to produce a composite metal mask, Since the composite metal mask is fixed to the imposition frame to produce a multi-faced metal mask, even if the multi-faced metal mask is enlarged, if the size of the divided metal mask is set to a size that can be processed by the patterning processing apparatus, Existing metal mask patterning equipment can be used as is.
In addition, since the composite metal mask is manufactured by aligning the divided metal masks and the multi-sided metal mask of a predetermined size is manufactured, the surface positioning accuracy of the unit metal mask can be confirmed, and the multi-sides with excellent positional accuracy An attached metal mask can be obtained.
Further, since the overlapping portion of the divided metal mask is removed after the composite metal mask is fixed to the imposition frame, the flatness of the metal mask can be ensured.

(A) is a schematic plan view which shows an example of the multi-sided metal mask produced with the manufacturing method of the multi-sided metal mask of this invention. (B) is a schematic cross-sectional view taken along the line A-A ′ of the schematic plan view of (a). (A) is a schematic top view which shows an example of a division | segmentation metal mask. (B) is a schematic cross-sectional view taken along the line A-A ′ of the schematic plan view of (a). (A) is a schematic plan view which shows an example of a composite metal mask. (B) is a schematic cross-sectional view taken along the line A-A ′ of the schematic plan view of (a). (A) is a schematic top view which shows an example of an imposition frame. (B) is a schematic cross-sectional view taken along the line A-A ′ of the schematic plan view of (a). (A) is a schematic top view which shows the state which fixed the composite metal mask to the imposition frame. (B) is a schematic cross-sectional view taken along the line A-A ′ of the schematic plan view of (a). (A) is a schematic plan view which shows an example of a multi-sided metal mask. (B) is a schematic cross-sectional view taken along the line A-A ′ of the schematic plan view of (a). (A) is a schematic plan view which shows the state which has attached the unit mask to the multi-faced frame. (B) is a schematic plan view which shows an example of a unit mask. (C) is a schematic cross-sectional view taken along the line A-A ′ of the schematic plan view of (a).

Explanation of symbols

10L, 10R ... Divided metal mask 11, 120 ... Unit metal mask 12, 122 ... Metal frame 13 ... Bonding area 14 ... Alignment fixing area 15 ... Mussel line 16 ... Alignment mark 20 ... Composite metal Mask 30 ... Imposition frame 31 ... Frame 32 ... Support frame 100 ... Multi-surface metal mask 111 ... Multi-surface chamfer 112 ... Opening 121 ... Mask area 200 ... Multi-surface metal mask

Claims (1)

A method for producing a multi-faced metal mask, comprising at least the following steps. (A) Dividing a multi-sided mask in which a plurality of unit metal masks are arranged into blocks, and having a joining area on the outer periphery, an alignment fixing area having an alignment mark at an end, and a squeezed line A step of obtaining a metal mask.
(B) A step of producing a composite metal mask in which the alignment regions are fixed by aligning using the alignment marks of the alignment regions of the divided metal mask.
(C) The process of joining the joining area | region of a composite metal mask on the support frame of a multi-faced frame.
(D) A step of squeezing the mating and fixing region with a squeezing line.

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