KR101899781B1 - Exposure apparatus - Google Patents

Abstract

The present invention relates to a stage for mounting a substrate to be exposed, A light source for generating light for the exposure process; An optical assembly disposed on the stage, the optical assembly including a plurality of optical members for providing light formed in the light source to a substrate on the stage and a housing for fixing the plurality of optical members therein; And alignment means coupled to the housing for aligning the optical assembly, thereby simplifying the alignment of the optical member.

Description

Exposure apparatus

Field of the Invention [0002] The present invention relates to an exposure apparatus, and more particularly, to an exposure apparatus capable of simplifying an aligning operation by aligning a plurality of optical members at one time.

Various display devices capable of supporting display of information are being developed. The display device includes a liquid crystal display (LCD), a plasma display (PDP), an organic light emitting display (OLED), and a field emission display (EFD).

In these display devices, various patterns are formed. One of the important process devices used for forming these patterns is an exposure device.

Generally, the exposure apparatus allows the exposure pattern to be transferred directly to the substrate by the light irradiated to the substrate for display via the exposure pattern.

An exposure pattern which is necessarily used for such an exposure apparatus is required to produce a mask in which a pattern for exposure is formed on a quartz disk, which is very expensive. Since a large number of masks are required to manufacture the display device, the display device maker has a considerable burden on the side of the display device maker.

In order to solve such a problem, a maskless exposure apparatus employing a digital micromirror device (DMD) instead of a mask has recently been studied.

Such an exposure apparatus includes not only a DMD but also many optical members such as a beam expander, a multi-array lens, and a projection lens. At this time, since each of the optical members must be individually adjusted in order to align the plurality of optical members, the alignment process is complicated and takes a long time.

Accordingly, it is an object of the present invention to provide an exposure apparatus capable of simplifying an aligning operation by aligning a plurality of optical members at one time, in order to solve the problems that may occur in an exposure apparatus.

An exposure apparatus for solving the problem according to the present invention is provided. The exposure apparatus includes a stage on which a substrate to be exposed is placed; A light source for generating light for the exposure process; An optical assembly disposed on the stage, the optical assembly including a plurality of optical members for providing light formed in the light source to a substrate on the stage and a housing for fixing the plurality of optical members therein; And an alignment means coupled to the housing to position the optical assembly.

The exposure apparatus according to the embodiment of the present invention can simultaneously adjust a plurality of optical members through the alignment of the housing after fixing a plurality of optical members in one housing and thus simplifying the aligning process have.

1 is a schematic view showing an exposure apparatus according to an embodiment of the present invention.
2 is a cross-sectional view schematically showing the configuration of the aligning means according to the embodiment of the present invention.
Figure 3a is a schematic plan view of a rotating means according to an embodiment of the invention.
3b is a schematic plan view of the X-axis moving means according to an embodiment of the present invention.
3C is a schematic plan view of the Y-axis moving means according to an embodiment of the present invention.

Embodiments of the present invention will be described in detail with reference to the drawings of an exposure apparatus. The following embodiments are provided by way of example so that those skilled in the art can fully understand the spirit of the present invention.

Therefore, the present invention is not limited to the embodiments described below, but may be embodied in other forms. In the drawings, the size and thickness of an apparatus may be exaggerated for convenience. Like reference numerals designate like elements throughout the specification.

1 is a schematic view showing an exposure apparatus according to an embodiment of the present invention.

Referring to FIG. 1, an exposure apparatus according to an embodiment of the present invention may include a stage 110, a light source 120, an optical assembly 130, and an aligning means 140.

Here, the stage 110 may serve to fix the substrate S during the exposure process by placing the substrate S to be exposed. In addition, the stage 110 may move left and right to move the substrate S.

The light source 120 forms light for exposure. Here, a laser diode may be used as the light source 120, and the shape of the light source is not limited in the embodiment of the present invention.

The optical assembly 130 serves to provide the light formed by the light source 120 to the substrate S on the stage 110. Specifically, the optical assembly 130 may include a plurality of optical members and a housing 135 for fixing the optical member therein.

The plurality of optical members include a digital micromirror device (DMD) 131, a beam expander 132, and a Multi Array Lens (MAL) 131, which are sequentially disposed between the substrates S in the light source 120. [ 133, and a projection lens 134.

The digital micromirror element 131 may selectively reflect light provided by the light source 120 to provide light in a pattern form on the substrate S. [ Due to the adoption of the digital micromirror element 131, the exposure apparatus can selectively irradiate light onto the substrate S without a separate mask.

The digital micromirror element 131 has a plurality of small unit mirrors. Here, light can be reflected by adjusting the angle of each unit mirror. At this time, light can be selectively provided on the substrate S by the pattern information inputted through each unit mirror.

The beam expander 132 expands the light emitted from the digital micromirror element 131 and provides it to the multi-array lens 133, which will be described later.

The multi-array lens 133 has a plurality of lenses arrayed so that the light emitted from the beam expander 132 can be separated into a plurality of light beams and condensed.

The projection lens 134 adjusts the resolution of the light beams condensed by the multi-array lens 133 and transmits the adjusted light beams on the substrate S.

The housing 135 fixes a plurality of optical members therein, and can protect a plurality of optical members from the outside. Here, the housing 135 may have a through hole for receiving a plurality of optical members. The housing 135 may have openings exposing the top and bottom surfaces of the plurality of optical members, respectively. Accordingly, the plurality of optical members can be integrated through the housing 135.

Aligning means 150 may serve to adjust the position of optical assembly 130. Here, the aligning means 150 is connected to the housing 135 of the optical assembly 130 to adjust the position of the housing 135 so that the position of the optical member coupled to the inside of the housing 135 can be adjusted. That is, since a plurality of optical members can be simultaneously adjusted through the alignment of the housing 135, the alignment process can be simplified.

Hereinafter, the aligning means will be described in detail with reference to Fig.

2 is a cross-sectional view schematically showing the configuration of the aligning means according to the embodiment of the present invention.

2, the aligning means 150 according to the embodiment of the present invention includes a first aligning means 150a connected to the upper side of the housing 135 and a second aligning means 150b connected to the lower side of the housing 135, (150b).

The first and second aligning means 150b may be coupled to the housing 135 through a main body 151 coupled to one side of the housing 135. [ Here, the first and second aligning means 150a and 150b may be coupled to the upper and lower portions of the main body 151, respectively. At this time, the main body 151 may be fixed to the housing 135 while maintaining flatness.

Each of the first and second aligning means 150a and 150b includes a rotating means 152 for rotating the optical assembly 130, an X-axis moving means 153 for linearly moving the optical arrestor 130 in the X- And Y-axis moving means 154 for linearly moving the optical assembly 130 in the Y-axis direction. Here, the X axis may refer to the horizontal direction with respect to the upper surface of the optical assembly 130, and the Y axis may refer to the horizontal direction, that is, the direction intersecting the X axis direction with respect to the upper surface of the optical assembly 130 . At this time, the tilting of the optical assembly 130, that is, the tilt of the X axis and the tilt of the Y axis can be adjusted by driving the first and second aligning means 150a and 150b. That is, since the respective X-axis moving means of the first and second aligning means 150a, 150b are moved in opposite directions, the tilt of the X-axis of the housing 135 can be adjusted. Alternatively, since the respective Y-axis moving means of the first and second aligning means 150b are moved in opposite directions to each other, the tilt of the Y-axis of the housing 135 can be adjusted. Accordingly, the aligning means 150 is capable of simultaneously aligning the optical elements with the alignment of the optical assembly, by having the plurality of optical members simultaneously having adjustment elements of at least 5 axes such as X, Y, X-axis tilt, Y-axis tilt, It can be finely adjusted.

The rotating means 152, the X-axis moving means 153 and the Y-axis moving means 154 may be stacked and coupled on the main body 151. [ Here, the rotating means 152, the X-axis moving means 153 and the Y-axis moving means 154 may be spaced apart from each other so as not to affect the mutual movement. In the embodiment of the present invention The rotation means 152, the X-axis movement means 153 and the Y-axis movement means 154 are sequentially stacked on the upper portion or the lower portion of the main body 151. However, The X-axis moving means 152, the X-axis moving means 153 and the Y-axis moving means 154 can be sufficiently changed.

Each of the rotating means 152, the X-axis moving means 153 and the Y-axis moving means 154 is a flexure hinge that moves the optical assembly 130 by displacement of a piezo actuator and a piezo actuator. ).

Hereinafter, the configurations of the rotating means, the X-axis moving means, and the Y-axis moving means provided in the aligning means will be described in detail with reference to FIGS. 3A to 3C.

Figure 3a is a schematic plan view of a rotating means according to an embodiment of the invention.

Referring to FIG. 3A, the rotating means 152 may include a first flexure hinge 152a and a first piezo actuator 152b.

The first collection hinge 152a may be connected to the housing 135. [ The first flexure hinge 152a can reduce the wear rate compared to other moving devices and can make continuous motion using the elastic deformation of the solid structure and can minimize movement in undesired directions. The first flexure hinge 152a may be formed of an aluminum alloy, and the first flexure hinge 152a may have an elastic force to cause elastic deformation.

The first piezo actuator 152b generates displacement according to the applied voltage and moves the first flexure hinge 152a connected to the first piezo actuator 152b.

That is, the first flexure hinge 152a is elastically deformed by the stretching force or the compressive force of the first piezo actuator 152b, and the resilient deformation of the first flexure hinge 152a causes the housing 135 to be rotated have.

Specifically, the first flexure hinge 152a may include a first rotary arm 152a1 and a second rotary arm 152a2 that are connected to each other through the first piezoelectric actuator 152b. Here, the first rotary arm 152a1 may be connected to the housing 135. At this time, one end of the first rotary arm 152a1 may be coupled to a part of the housing 135, for example, at least a half of the housing 135. The other end of the first rotary arm 152a1 may have a step. At this time, both sides of the other end of the first rotary arm 152a1 may have a depression 152c depressed toward the housing 135, respectively. The other end of the first rotary arm 152a1 may have a step corresponding to the second rotary arm 152a2. At this time, both ends of one end of the second rotary arm 152a2 may have a protrusion 152d corresponding to the depression 152c and protruding toward the housing 135. [ A first piezoactuator 152b may be provided between the other end of the first rotary arm 152a1 and one end of the second rotary arm 152a2. In this case, when a voltage is applied to the first piezo actuator 152b, the first piezo actuator 152b is extended so that the protruding portion 152d of the second rotary arm 152a2 is moved to the upper depression portion 152a1 of the first rotary arm 152a1, And the first rotary arm 152a1 is brought into contact with the second rotary arm 152c. Due to the movement of the first rotary arm 152a1, the housing 135 can rotate.

In addition, first elastic members 152e may be provided on both sides of the first piezo actuator 152b. At this time, when the applied voltage of the first piezo actuator 152b is removed, the stretching force of the first piezo actuator 152b is reduced, and at the same time, the elastic force of the first elastic member 152e causes the first and second rotations The arms 152a1 and 152a2 are moved in the direction opposite to the direction of movement by the extension of the first piezo actuator 152b. Accordingly, when the applied voltage of the first piezoactuator 152b is removed, the housing 135 can rotate in the opposite direction rotating by the extension of the first piezoactuator 152b.

3b is a schematic plan view of the X-axis moving means according to an embodiment of the present invention.

Referring to FIG. 3B, the X-axis moving unit 153 according to the embodiment of the present invention may include a second flexure hinge 153a and a second piezo actuator 153b.

The second flexure hinge 153a may include a first X axis shift arm 153a1 coupled to the housing 135 and a second X axis shift arm 153a2 that is spaced apart from the first X axis shift arm 153a1. have. One end of the first X-axis movable arm 153a1 is connected to the housing 135 and the other end of the first X-axis movable arm 153a1 is disposed to face the second X-axis movable arm 153a2. At this time, the other end of the first X-axis movable arm 153a1 may have a depression corresponding to a part of the second portion 153a3 of the second X-axis movable arm 153a2, for example, the upper end of the third portion 153a3. The second X-axis moveable arm 153a2 may include a first portion 153a3 corresponding to the first depression of the first X-axis moveable arm 153a1. In addition, the second X-axis movable arm 153a2 may have a second depression for receiving a part of the first arm 153a3, for example, the upper end of the second arm 153a3. At this time, the shape of the Z-shaped portion 153a3 may be a Y-shaped shape, but it is not limited to the shape of the Z-shaped portion 153a3 in the embodiment of the present invention.

The second piezoactuator 153b may be connected to the lower end of the Z-tail portion 153a3 of the second X-axis movable arm 153a2, for example, the Z-tail portion 153a3. When the voltage is applied to the second piezoelectric actuator 153b to compress the second piezoelectric actuator 153b, the lower end of the first portion 153a3 is moved in a direction opposite to the housing 135, and the upper end of the first portion 153a3 is moved in the X- Axis moving arm 153a1 is in contact with the step portion forming the first depression 152c of the first X-axis movable arm 153a1 and moves the first X-axis movable arm 153a1 in the X-axis direction. At this time, by the movement of the first X-axis movable arm 153a1, the housing 135 connected to the first X-axis movable arm 153a1 can be moved in the X-axis direction.

Further, a second elastic member 153c may be provided on both sides of the second piezo actuator 153b. At this time, when the applied voltage of the second piezo actuator 153b is removed, the compressive force of the second piezo actuator 153b is reduced, and at the same time, the elastic force of the second elastic member 153c causes the first and second X The axle moveable arms 153a1 and 153a2 move in the direction opposite to the direction of movement by the compression of the second piezo actuator 153b. Accordingly, when the applied voltage of the second piezoactuator 153b is removed, the housing 135 can be moved in the direction opposite to the direction of movement by the compression of the second piezoactuator 153b.

3C is a schematic plan view of the Y-axis moving means according to an embodiment of the present invention.

Referring to FIG. 3C, the Y-axis moving unit 154 according to the embodiment of the present invention may include a third flexure hinge 154a and a third piezo actuator 154b.

The third flexure hinge 154a may include a first Y axis arm 154a1 connected to the housing 135 and a second Y axis arm 154a2 spaced apart from and facing the first Y axis arm 154a1 . Here, the second Y-axis movable arm 154a2 may include first and second branches branched from top to bottom. For example, the second Y-axis shift arm 154a2 may have an 'n' shape. The third piezo actuator 154b may be disposed to connect the first and second branch portions of the second Y-axis movable arm 154a2 to each other. At this time, when the third piezoelectric actuator 154b is elongated by the applied voltage, the first branching portion 154a1 of the second Y-axis movable arm 154a2 facing the first Y- It is possible to move the first Y-axis movable arm 154a1 in the Y-axis direction in contact with the axis movable arm 154a1. Here, due to the movement of the first Y-axis movable arm 154a1, the housing 135 can be moved in the Y-axis direction.

Further, the third elastic actuator 154c may be provided on both sides of the third piezo actuator 154b. At this time, when the applied voltage of the third piezoactuator 154b is removed, the stretching force of the third piezoactuator 154b is reduced and at the same time, the elastic force of the third elastic member 154c causes the first and second Y The axially movable arms 154a1 and 154a2 move in the direction opposite to the direction of movement due to the extension of the third piezo actuator 154b. Accordingly, when the applied voltage of the third piezoactuator 154b is removed, the housing 135 can move in the opposite direction by extension of the third piezoactuator 154b.

Accordingly, the shape of the piezoactuator and flexure hinge can be changed to variously change the position of the housing, i.e., the optical assembly.

Accordingly, the exposure apparatus according to the embodiment of the present invention can simultaneously adjust a plurality of optical members through the alignment of the housing after a plurality of optical members are fixed and installed in one housing, thereby simplifying the alignment process .

110: stage
120: Light source
130: housing
140: optical member
150: Alliin Sudan
152: rotating means
153: X-axis moving means
154: Y-axis moving means

Claims (9)

A stage on which a substrate to be exposed is placed;
A light source for generating light for an exposure process;
A housing disposed on the stage;
A plurality of light sources provided in the housing, the plurality of light sources being fixed to a predetermined position inside the housing by being coupled with each other, An optical member; And
An aligning means connected to one side of the housing; ≪ / RTI >
Wherein said aligning means comprises:
Aligning the plurality of optical members so that light having the exposure pattern is emitted by adjusting the rotation, linear movement, and tilting position of the housing,
Wherein the housing is provided with a through hole for receiving the plurality of optical members,
Wherein the housing has an opening exposing an upper surface and a lower surface, respectively, of the plurality of optical members,
Wherein the aligning means comprises a first aligning means arranged on the upper side of the housing and a second aligning means arranged on the lower side of the housing,
Each of the first and second aligning means includes rotating means for rotating the plurality of optical members, X-axis moving means for moving the plurality of optical members in a linear direction in the X-axis direction, and X- And Y-axis moving means for moving the Y-
Wherein the first and second alignment means comprise:
A main body coupled to one side of the housing and coupled with the housing,
The first and second aligning means are respectively coupled to the upper and lower portions of the main body,
Wherein the main body is fixed to the housing while maintaining a predetermined flatness,
The rotating means includes a first flexure hinge connected to the housing and a first piezo actuator connected to the first flexure hinge and generating a displacement according to an applied voltage to move the first flexure hinge ,
The first flexure hinge is formed of an aluminum alloy,
The first flexure hinge forms an elastic force so as to cause elastic deformation,
Wherein the first flexure hinge has a first rotary arm and a second rotary arm connected through the first piezo actuator,
Wherein the X-axis moving means includes a second flexure hinge and a second piezo actuator, and a second elastic member provided on both sides of the second piezo actuator,
The second flexure hinge includes a first X-axis movable arm connected to the housing and a second X-axis movable arm spaced apart from the first X-axis movable arm,
The second piezoactuator is connected to the lower end of the grip portion of the second X-axis movable arm,
Wherein the Y axis moving means includes a third flexure hinge, a third piezo actuator, and a third elastic member provided on both sides of the third piezo actuator,
The third flexure hinge includes a first Y-axis movable arm connected to the housing and a second Y-axis movable arm spaced apart from the first Y-axis movable arm,
The second Y-axis movable rocker has first and second branch portions branched from the upper portion to the lower portion,
And the third piezoactuator connects the first and second branch portions of the second Y-
Exposure apparatus.
The method according to claim 1,
The plurality of optical members include a digital micromirror device (DMD) for emitting the light provided by the light source as light having the exposure pattern; A beam expander for expanding the light emitted from the digital micromirror device; A Multi Array Lens (MAL) for condensing the light emitted from the beam expander into a plurality of light beams; And a projection lens for adjusting and transmitting the resolution of the light condensed by the multi-array lens.
delete delete The method according to claim 1,
And adjusts the tilt of the plurality of optical members by driving the first and second alignment means.
delete delete delete The method according to claim 1,
The rotating means, the X-axis moving means, and the Y-axis moving means.
And are stacked on and bonded to the main body,
Exposure apparatus.

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