JP2012181285A - Exposure device using microlens array - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an exposure device using a microlens array, which is capable of efficiently using the microlens array in accordance with a size of a liquid crystal display panel for a mobile device.SOLUTION: An irradiation region of exposure light corresponds to a size of a microlens array 22, and the microlens array 22 has a length corresponding to a width of a mask or its integer fraction with respect to a direction vertical to a scanning direction. The microlens array 22 is constituted by arraying two or more units 28, 29, and 30 divided into lengths corresponding to panels 23, 24, and 25 to be manufactured.

Description

  The present invention relates to an exposure apparatus using a microlens array, and more particularly to an exposure apparatus using a microlens array suitable for exposure of a liquid crystal display panel for portable equipment.

  Unlike large liquid crystal display devices such as televisions, liquid crystal display devices mounted on devices such as mobile phones and portable information terminals are required to have smaller panels and higher definition panels. .

  As an exposure apparatus used when manufacturing a liquid crystal display panel of such a portable device, a stepper used for exposure of a semiconductor device is conventionally used for high-definition exposure.

  However, in this stepper, since the size of the area exposed by one objective lens is determined, when creating a plurality of panels on one glass substrate, the boundary of the exposure area of the objective lens May be located inside the panel. Then, in the panel, the areas on both sides of the boundary of the exposure area are exposed with different shots, and there is a problem that the position of the wiring or the like is shifted at the boundary. Therefore, at this boundary, it is necessary to perform a so-called “next” process such as thickening the wiring pattern, forming the inclined end portion, and overlapping the inclined portion. In addition, even if this “next” process is performed, the portions subjected to this “next” may continue on a straight line, resulting in stripes. It must be discarded. Further, even when the exposure pattern is a pattern that is difficult to process next, it is necessary to discard the panel at the boundary of the exposure area without making it a product.

  Thus, although an exposure apparatus using a microlens array has been proposed (Patent Document 1), an exposure apparatus using a conventional microlens array exposes a panel for a large liquid crystal display device such as a television. If this is applied as it is to a liquid crystal display device for a portable device, the liquid crystal display panel for a portable device is small and has various sizes, so that the production efficiency is poor. There is.

JP 2010-102149 A

  As described above, high-definition is required as in liquid crystal display panels for portable devices, and in the case of a small panel, the use of a conventional stepper requires a “next” exposure pattern, and a microlens array However, there is a problem that the production efficiency is poor.

  The present invention has been made in view of such problems, and an exposure apparatus using a microlens array that can efficiently use a microlens array in accordance with the size of a liquid crystal display panel for portable devices. The purpose is to provide.

  In the exposure apparatus using the microlens array according to the present invention, a light source that emits exposure light toward the substrate and a pattern corresponding to a plurality of panels that are exposed to the exposure light from the light source are formed. A mask, a microlens array that forms an erecting equal-magnification image of the mask pattern on the substrate when exposure light transmitted through the mask is incident, and a driving device that scans the exposure light on the substrate. In the driving device, the positional relationship between the microlens array and the light source is fixed, and the positional relationship between the mask and the substrate is fixed, the combination of the microlens array and the light source, and the mask And the combination of the substrate and the substrate are moved relative to each other in the first direction to scan the exposure light on the substrate. The projection area corresponds to the size of the microlens array, and the microlens array has a length in the second direction of the mask or the length thereof in a second direction perpendicular to the first direction. It has a length corresponding to a length of an integral number of the length, and is configured by arranging two or more units divided into lengths corresponding to a panel to be manufactured. To do. As the exposure light, mercury lamp light or the like is used.

  In the exposure apparatus using the microlens array, for example, the microlens array has a length corresponding to the length of the mask with respect to the second direction, and the microlens array has a length of 1 with respect to the mask. The pattern of the mask is transferred to the substrate by scanning relatively times.

  Alternatively, for example, the microlens array has a length of 1 / n of the length of the mask, where n is an integer equal to or greater than 2, with respect to the second direction, and the microlens array corresponds to the mask The mask pattern is transferred to the substrate by scanning each of the n-divided regions in the second direction.

  According to the present invention, a panel substrate having a size smaller than the mask can be exposed with high efficiency by effectively using the microlens array within the frame of the mask size.

1 is a perspective view showing an exposure apparatus using a microlens array according to a first embodiment of the present invention. It is a perspective view which shows a mask stage and a micro lens array. It is a perspective view which shows the whole mask stage. It is a top view which shows the structure of a micro lens array. It is a figure which shows the relationship between the exposure light and mask in a scanning exposure process. It is a figure which shows the relationship between the exposure light in a scanning exposure process, and a micro lens array. It is a figure which shows the next process of FIG. It is a top view which shows the structure of the microlens array which concerns on the modification of FIG. It is a figure which shows operation | movement of the 1st shot of exposure light and a micro lens array in the exposure apparatus using the micro lens array which concerns on 2nd Embodiment of this invention. Similarly, it is a figure which shows the operation | movement of the 2nd shot. Similarly, it is a figure which shows the operation | movement of the 3rd shot. Similarly, it is a figure which shows the operation | movement of the 4th shot.

  Hereinafter, embodiments of the present invention will be specifically described with reference to the accompanying drawings. FIG. 1 is a perspective view showing an exposure apparatus using the microlens array according to the first embodiment of the present invention, FIG. 2 is a perspective view showing one mask stage and a microlens array, and FIG. 3 shows the entire mask stage. It is a perspective view. A substrate stage 12 is placed in a first direction 1 on an XY stage 11 that can move a glass substrate in a scanning direction (first direction) 1 and a direction (second direction) 2 perpendicular to the scanning direction 1. It is installed to be movable. A gantry 13 is installed above the XY stage 11 and the substrate stage 12, and four light sources 14 are fixedly installed on the gantry 13 as an example. These light sources 14 are, for example, high-pressure mercury lamp light sources, and irradiate ultraviolet exposure light 15 having a wavelength of 365 nm downward. The irradiation area of the exposure light 15 is rectangular as shown in FIG.

  A mask stage 18 is disposed below the light source 14 of the exposure light 15. A first guide 16 extending in the second direction 2 is suspended from the gantry 13, and a second guide 17 extending in the first direction 1 is suspended from the guide 16. The first guide 16 is fixed on the gantry 13, and the second guide 17 is supported on the first guide 16 extending in the second direction 2 so as to be movable in the second direction 2. The four mask stages 18 are supported so as to be movable in the first direction 1 on the second guide 17 extending in the first direction 1 while maintaining the positional relationship with each other. The mask stage 18 is formed with a rectangular opening, and the mask 20 is supported in the opening. Accordingly, the mask 20 can be scanned with respect to the first direction 1 and can be shifted with respect to the second direction 2 by the first guide 16 and the second guide 17.

  A microlens array holder 21 is installed below the mask 20, and the microlens array 22 is supported in the opening of the holder 21. The microlens array 22 is formed with a large number of microlenses, so that each microlens forms an erecting equal-magnification image of the pattern of the mask 20 on a substrate disposed below the microlens array 22. It has become. The formation area of the microlens in the microlens array 22 coincides with the rectangular irradiation area of the exposure light 15 from the light source 14, and the exposure light 15 passes through a partial area of the mask 20, and then the microlens array 22 Projected onto the substrate.

  In the present embodiment, the mask 20 supported by the mask stage 18 and the substrate on the substrate stage 12 simultaneously scan in the first direction 1 and shift in the second direction 2. The light source 14 and the microlens array 22 are fixed on the gantry 13 in a state where the irradiation area of the exposure light 15 from the light source 14 coincides with the entire area of the microlens array 22 (the entire area having an optical action). . Accordingly, the exposure light from the light source 14 is held on the substrate by the microlens array 22 and the mask 20 and the substrate move in the first direction 1 so that the substrate is scanned with the exposure light. The mask pattern is exposed and transferred onto the substrate.

  The size of the mask 20 held on the mask stage 18 is, for example, a width in the second direction 2 of 400 mm, and the width of the microlens array 22 in the second direction 2 is also 400 mm in accordance with the mask width.

  If the total length of the mask 20 (second direction 2) is such that three types of liquid crystal panels for portable devices can be collected, the microlens array 22 has 3 as shown in FIG. It is divided. For example, when a 4-inch panel 23 of a cellular phone, an 8-inch panel 24 of a portable information terminal, and a 3-inch panel 25 of a cellular phone are exposed simultaneously with a single mask 20, the microlens array 22 is 4 inches. A unit 28 having a width in the width direction of the panel 23, a unit 29 having a length in the width direction of the 8-inch panel 24, and a unit 30 having a length in the width direction of the 3-inch panel 25; Each of them is arranged so as to be connected at end edges 26 and 27 in the width direction. In this case, the units 28, 29, and 30 do not need to be joined to each other, and may be arranged so as to be separable. One mask 20 is formed with a pattern for a 4-inch panel 23, a pattern for an 8-inch panel 24, and a pattern for a 3-inch panel 25. Further, the edges 26 and 27 of the microlens array 22 are located between the panel 23 and the panel 24 and between the panel 24 and the panel 25, and are not located within the panels 23, 24, and 25. As such, its position is determined. That is, the microlens array is usually produced with a width of 150 mm, for example, and this microlens array is purchased and cut into the width of the panels 23, 24, and 25. In this case, the cutting position is determined so as to obtain a microlens array unit having a width equal to or larger than the panel width in consideration of the cutting allowance and the like. A plurality of microlens units 28, 29, and 30 are combined so that the total length corresponds to, for example, 400 mm corresponding to the width of the mask 20, and the units 28, 29, and 30 are arranged, whereby the width is 400 mm. The microlens array 22 corresponding to is configured.

  Next, the operation of the exposure apparatus that uses the microlens array configured as described above will be described. The glass substrate 40 on which the resist film is formed is transferred onto the substrate stage 12 and set at a position facing the mask 20 supported by the four mask stages 18. The guides 16 and 17 and the substrate stage 12 and the XY stage 11 drive the substrate 40 and the mask 20 at the same time while maintaining a fixed positional relationship.

  In the present embodiment, as shown in FIG. 3, the masks 20 are respectively held on the four mask stages 18, and the four exposure lights 15 from the four light sources 14 enter each mask 20. The rectangular irradiation region of the exposure light 15 has a length in the width direction corresponding to the entire length of the mask 20 in the second direction 2 (direction orthogonal to the scanning direction). As shown in FIG. 5, the exposure light 15 scans the mask 20 with a white arrow as the mask 20 moves relative to the exposure light 15 in the first direction 1. Scan in the direction.

  FIG. 6 is a perspective view showing a state where the mask 20 is removed. As shown in FIG. 6, the rectangular irradiation area of the exposure light 15 corresponds to the microlens formation area of the microlens array 22 supported in the opening of the microlens array holder 21. The positional relationship between the exposure light 15 and the microlens array 22 is fixed. While the mask 20 and the substrate 40 move together at the same time, as shown in FIG. The microlens array 22 is scanned relative to the mask 20 and the substrate 40 in the scanning direction indicated by the white arrow, and the exposure light 15 transmitted through the mask 20 is imaged on the substrate 40. As a result, the pattern of the mask 20 is transferred onto the substrate 40 as an erect life-size image, and an exposure pattern 41 is formed on the resist.

  In this embodiment, the microlens array 22 is a unit obtained by, for example, cutting an off-the-shelf microlens array manufactured with a width of 150 mm in accordance with the size of the panels 23, 24, and 25 of the portable device. 28, 29, and 30 are arranged so as to be connected by the edges 26 and 27 in the width direction, and the entire microlens array 22 has a width of, for example, 400 mm, which matches the width of the mask 20. It has become a thing. Therefore, three types of panels can be exposed simultaneously by one scan operation on the resist film on the glass substrate 40, and the exposure operation can be made highly efficient. At this time, the panels 28, 29, and 30 do not have a seam of the microlens array inside, and the seam is located between the panels 28, 29, and 30. There is no need to perform the next process. Therefore, exposure unevenness does not occur in the exposure pattern. Further, the mask is usually about 400 mm in width, but if such a long microlens array is to be manufactured, the cost increases. Microlens arrays usually have a length (width) of about 150 mm, but the relative manufacturing cost per unit length is low. Therefore, a plurality of microlens arrays are connected to form a microlens array corresponding to the mask width, or the microlens array holder 21 is provided with a microlens array having a length of, for example, 150 mm. It is necessary to form a Cr film on the mask portion in the region where no exposure exists so as to block transmission of exposure light. In the latter case, an area that is not used for the glass substrate 40 (an area that does not become a panel) is generated, which is useless. Therefore, it is preferable to connect a plurality of microlens arrays to form a microlens array corresponding to the mask width. At this time, as in this embodiment, a microlens array having a general-purpose length of 150 mm is used. Is cut in accordance with the panel, and the cut panels are joined together to form a microlens array 22 having a length corresponding to the width of the mask 20, so that a so-called "next" exists in the exposure pattern of the panel. In addition, since many and other types of panels can be exposed at the same time, it is efficient.

  The microlens array 22 shown in FIG. 4 corresponds to the three types of panels 23, 24, and 25. However, the present invention is not limited to this, and for example, as shown in FIG. For example, a 4-inch panel 23 can be exposed at the same time. In this case, the microlens array 22 is composed of two units 28 having a size corresponding to the 4-inch panel 23 and a unit 28a having a size obtained by subtracting the width of the two units 28 from the width of the mask. The The unit 28a is larger than the unit 28 and can be used for the entire exposure of the 4-inch panel 23. Of course, the position of the edge of each unit 28, 28a is not located inside the panel 23.

  Next, a second embodiment of the present invention will be described with reference to FIGS. The first embodiment shown in FIG. 1 to FIG. 7 is a case where four masks 20 are installed on four mask stages 18, but the second embodiment uses a large mask. The resist film on the glass substrate is to be exposed. 9 to 12, the mask is not shown to show the microlens array 22, but is supported by the frame of the mask stage 42. As shown in FIG. 9, one mask (not shown) supported by one mask stage 42 is disposed on the substrate 40, and the exposure light 15 enters the microlens array 22 through the mask. Then, the exposure light transmitted through the mask is condensed by the microlens array 22 and converged on the substrate 40. An erecting equal-magnification image of the mask pattern is formed on the substrate 40, and the exposure pattern 41 is formed. It is formed.

  In the present embodiment, the entire area of the substrate 40 is exposed by four shots. First, as shown in FIG. 9, the substrate (mask) is divided into four parts in the vertical and horizontal directions and divided into 16 equal area regions. Each exposure light from each light source 14 is divided into a white region in the upper left region of the divided region. Scan in the direction of the pull arrow (first shot). Next, as shown in FIG. 10, the exposure light 15 scans the substrate area adjacent to the right of the first shot (right side in the second direction) in the direction indicated by the white arrow in the direction opposite to that of the first shot. (Second shot) After that, as shown in FIG. 11, the substrate region adjacent to the first direction of the second shot is scanned in the direction indicated by the white arrow in the direction opposite to the second shot (third shot). Thereafter, as shown in FIG. 12, the substrate area adjacent to the second direction of the third shot is scanned in the direction indicated by the white arrow in the direction opposite to the third shot (fourth shot). Thereby, the entire region of the substrate 40 is exposed.

  In the present embodiment, when n is an integer of 2 or more, the microlens array 22 having a size of 1 / n of the mask width (that is, n = 4 and 1 / n is 1/4 in this embodiment) is provided. Using four, the entire area of the substrate is exposed in four shots. Also in this embodiment, the microlens array 22 is configured by connecting a plurality of units cut in accordance with the size of the panel, and the connection between the units is provided in the area between the panels exposed on the substrate. There is a line corresponding to the line (edge of the unit), and there is no line corresponding to the connection line between the units in the panel. Therefore, exposure unevenness due to “next” does not occur in the panel.

  Therefore, the present embodiment has the same effect as the first embodiment.

1: First direction (scan direction)
2: Second direction (direction perpendicular to the scanning direction)
14: Light source 15: Exposure light 18, 42: Mask stage 20: Mask 21: Micro lens array holder 22: Micro lens array 23, 24, 25: Panel 26, 27: Edges 28, 29, 30: Micro lens array unit 40: Substrate 41: Exposure pattern

Claims (3)

A light source that emits exposure light toward the substrate, a mask on which exposure light from the light source is incident and a pattern corresponding to a plurality of panels to be exposed is formed, and exposure light that is transmitted through the mask is incident on the mask A microlens array that forms an erecting equal-magnification image of the pattern on the substrate, and a driving device that scans the exposure light on the substrate, the driving device including the microlens array and the light source The positional relationship between the mask and the substrate is fixed, and the combination of the microlens array and the light source and the combination of the mask and the substrate are in the first direction. The exposure light is scanned on the substrate by relatively moving, and the irradiation area of the exposure light corresponds to the size of the microlens array. And the microlens array has a length corresponding to a length of the mask in the second direction or a fraction of the length of the mask in the second direction perpendicular to the first direction. An exposure apparatus using a microlens array, characterized by comprising two or more units divided into lengths corresponding to the panel to be manufactured. The microlens array has a length corresponding to the length of the mask with respect to the second direction, and the microlens array scans the mask relative to the mask once to thereby form a pattern of the mask. The exposure apparatus using the microlens array according to claim 1, wherein the image is transferred to the substrate. The microlens array has a length of 1 / n of the length of the mask, where n is an integer greater than or equal to 2 with respect to the second direction, and the microlens array 2. The exposure apparatus using a microlens array according to claim 1, wherein the pattern of the mask is transferred to the substrate by scanning each of the n-divided regions in the direction of 2.

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