JP7107352B2 - Substrate transport apparatus, exposure apparatus, flat panel display manufacturing method, device manufacturing method, substrate transport method, and exposure method - Google Patents

Description

The present invention relates to a substrate transfer apparatus, an exposure apparatus, a flat panel display manufacturing method, a device manufacturing method, a substrate transfer method, and an exposure method.

In the lithography process for manufacturing electronic devices such as liquid crystal display elements and semiconductor elements, a pattern formed on a mask (or reticle) is transferred onto a substrate (substrate made of glass, plastic, etc., semiconductor wafer, etc.) using an energy beam. A transfer exposure device is used.

In this type of exposure apparatus, an exposed substrate is unloaded from a stage device that holds the substrate, and a new substrate is loaded onto the stage device. As a method for transporting a substrate, for example, the method described in Patent Document 1 is known.

WO2013/150787

According to the first aspect, in the substrate transporting device that transports a substrate to a holding device, a first holding part that holds the substrate above the holding device; One of the holding device, the second holding portion, and the first holding portion is placed with respect to the other so that the second holding portion holding the part and the first holding portion are retracted from above the holding device. and a drive unit for relatively moving the holding unit, the first holding unit, and the second holding unit to hold the substrate during the relative movement by the drive unit.

According to a second aspect, there is provided an exposure apparatus comprising the above-described substrate transfer device and an optical system for irradiating the substrate transferred to the holding device with an energy beam and exposing the substrate. .

According to a third aspect, there is provided a flat panel display manufacturing method including exposing a substrate using the exposure apparatus described above and developing the exposed substrate.

According to a fourth aspect, there is provided a device manufacturing method including exposing a substrate using the above exposure apparatus and developing the exposed substrate. .

According to a fifth aspect, in the substrate transfer method for transferring a substrate to a holding device, the substrate is held above the holding device by a first holding portion and a second holding portion; moving one of the holding device and the second holding portion and the first holding portion relative to the other such that the is retracted from above the holding device; A substrate transfer method is provided in which the substrate is held by the holding device, the first holding portion, and the second holding portion.

According to the sixth aspect, the exposure method includes transferring the substrate to the holding device and irradiating the substrate with an energy beam to expose the substrate by the substrate transfer method described above. is provided.

According to a seventh aspect, there is provided a flat panel display manufacturing method including exposing the substrate using the above exposure method and developing the exposed substrate.

According to an eighth aspect, there is provided a device manufacturing method including exposing the substrate using the exposure method described above and developing the exposed substrate.

It should be noted that the configurations of the embodiments described later may be modified as appropriate, and at least a part of them may be replaced with other components. Furthermore, constituent elements whose arrangement is not particularly limited are not limited to the arrangement disclosed in the embodiments, and can be arranged at positions where their functions can be achieved.

FIG. 1 is a diagram schematically showing the configuration of an exposure apparatus according to the first embodiment. 2 is a plan view of a stage device and a substrate transfer device included in the exposure apparatus (partially omitted) of FIG. 1. FIG. 3(a) is a plan view of the stage device according to the first embodiment, FIG. 3(b) is a side view, and FIG. 3(c) is a cross-sectional view along line AA of FIG. 3(a). be. 4A to 4C are side views (part 1) of the exposure apparatus for explaining the substrate exchanging operation in the first embodiment. FIGS. 5A to 5C are side views (2) of the exposure apparatus for explaining the substrate exchanging operation in the first embodiment. 6A to 6C are side views (part 3) of the exposure apparatus for explaining the substrate exchanging operation in the first embodiment. 7A to 7C are side views (part 4) of the exposure apparatus for explaining the substrate exchanging operation in the first embodiment. FIGS. 8A to 8C are side views (5) of the exposure apparatus for explaining the substrate exchanging operation in the first embodiment. 9A to 9C are side views of the exposure apparatus for explaining the substrate exchange operation in the first modified example of the first embodiment. FIG. 10(a) is a perspective view of a substrate loading hand according to a second modification of the first embodiment, and FIG. 10(b) is a side view. FIGS. 11A and 11B are side views of the exposure apparatus for explaining the substrate exchange operation in the third modified example of the first embodiment. FIG. 12(a) is a top view of a substrate loading hand according to a fourth modification of the first embodiment, and FIG. 12(b) is a cross-sectional view taken along line AA of FIG. 12(a). FIGS. 13(a) and 13(b) are diagrams for explaining the substrate loading operation using the substrate loading hand according to the fourth modification of the first embodiment. 14(a) and 14(b) are cross-sectional views schematically showing substrate loading hands according to a fifth modification of the first embodiment. 15(a) and 15(b) are respectively a top view and a side view of an exposure apparatus according to the second embodiment. 16(a) and 16(b) are perspective views of a substrate loading hand according to the second embodiment. 17(a) and 17(b) are respectively a top view and a side view (No. 1) of the exposure apparatus for explaining the substrate exchanging operation in the second embodiment. FIGS. 18A and 18B are a top view and a side view (No. 2) of the exposure apparatus, respectively, for explaining the substrate exchanging operation in the second embodiment. FIGS. 19A and 19B are a top view and a side view (No. 3) of the exposure apparatus, respectively, for explaining the substrate exchanging operation in the second embodiment. FIGS. 20A and 20B are a top view and a side view (No. 4) of the exposure apparatus, respectively, for explaining the substrate exchanging operation in the second embodiment. FIGS. 21A and 21B are a top view and a side view (No. 5) of the exposure apparatus, respectively, for explaining the substrate exchanging operation in the second embodiment. 22(a) and 22(b) are respectively a top view and a side view (No. 6) of the exposure apparatus for explaining the substrate exchanging operation in the second embodiment. 23(a) and 23(b) are respectively a top view and a side view (7) of the exposure apparatus for explaining the substrate exchanging operation in the second embodiment. 24(a) and 24(b) are respectively a top view and a side view (8) of the exposure apparatus for explaining the substrate exchanging operation in the second embodiment. 25(a) and 25(b) are diagrams for explaining advantages of the substrate carrying-in hand according to the second embodiment. 26(a) and 26(b) are respectively a top view and a side view of the exposure apparatus for explaining the substrate exchanging operation in the first modified example of the second embodiment. 27(a) and 27(b) are respectively a top view and a side view (No. 1) of the exposure apparatus for explaining the substrate exchanging operation in the second modified example of the second embodiment. 28(a) and 28(b) are respectively a top view and a side view (No. 2) of the exposure apparatus for explaining the substrate exchanging operation in the second modified example of the second embodiment. 29(a) and 29(b) are respectively a top view and a side view (No. 3) of the exposure apparatus for explaining the substrate exchanging operation in the second modified example of the second embodiment. 30(a) and 30(b) are respectively a top view and a side view (No. 4) of the exposure apparatus for explaining the substrate exchanging operation in the second modified example of the second embodiment. FIGS. 31(a) and 31(b) are side views of the substrate transfer apparatus for explaining transfer of the substrate from the beam unit to the substrate loading hand in the third modified example of the second embodiment. 32(a) and 32(b) are respectively a top view and a side view of an exposure apparatus for explaining the transfer of the substrate from the beam unit to the substrate carrying-in hand in the fourth modified example of the second embodiment. 1). 33(a) and 33(b) are respectively a top view and a side view of an exposure apparatus for explaining the transfer of a substrate from a beam unit to a substrate carrying-in hand in the fourth modified example of the second embodiment (the 2). 34(a) and 34(b) are respectively a top view and a side view of an exposure apparatus for explaining the transfer of a substrate from an external transport device to a substrate carrying-in hand in the fifth modification of the second embodiment. 1). 35(a) and 35(b) are respectively a top view and a side view of an exposure apparatus for explaining the transfer of a substrate from an external transport device to a substrate loading hand in the fifth modification of the second embodiment ( 2). FIG. 36 is a perspective view showing a substrate loading hand according to a sixth modification of the second embodiment; FIGS. 37(a) and 37(b) are diagrams for explaining a configuration example of a board loading hand. FIG. 38 is a diagram for explaining a configuration example of a substrate transfer section; FIG. 39 is a diagram for explaining a configuration example of a surface plate. 40(a) and 40(b) are respectively a top view and a side view showing the configuration of the stage device in the first and second embodiments and their modifications. FIG. 41(a) is a top view showing another example of the stage device, and FIGS. 41(b) and 41(c) are cross-sectional views taken along line AA of FIG. 41(a). FIG. 42(a) is a top view showing another example of the stage device, and FIG. 42(b) is a cross-sectional view taken along the line AA of FIG. 42(a). 43(a) to 43(c) are side views for explaining how the substrate is placed on the stage apparatus shown in FIGS. 42(a) and 42(b).

<<First embodiment>>
First, a first embodiment according to the present invention will be described with reference to FIGS. 1 to 8(c).

FIG. 1 schematically shows the configuration of an exposure apparatus 10A according to the first embodiment. 2 is a plan view of a stage device 20A and a substrate transfer device 100A included in the exposure apparatus 10A (partially omitted) of FIG. 3(a) is a plan view of the stage device 20A, FIG. 3(b) is a side view of the stage device 20A, and FIG. 3(c) is a sectional view taken along line AA of FIG. 3(a). be.

The exposure apparatus 10A performs step-and-scan projection using a rectangular (square) glass substrate P (hereinafter simply referred to as substrate P) used for liquid crystal display devices (flat panel displays), for example. It is an exposure device, a so-called scanner.

As shown in FIG. 1, the exposure apparatus 10A includes an illumination system 12, a mask stage 14 that holds a mask M on which a pattern such as a circuit pattern is formed, a projection optical system 16, a surface (the surface facing +Z side in FIG. ), a stage device 20A for holding a substrate P coated with a resist (sensitizer), a substrate transfer device 100A, and a control system for these. Hereinafter, as shown in FIG. 1, X-, Y-, and Z-axes are set to be orthogonal to each other in the exposure apparatus 10A, and the mask M and the substrate P are aligned in the X-axis directions with respect to the projection optical system 16 during exposure. , and the Y-axis is set in the horizontal plane. Further, the rotation (tilt) directions about the X-axis, Y-axis, and Z-axis are described as θx, θy, and θz directions, respectively. Also, the positions in the X-axis, Y-axis, and Z-axis directions will be described as the X position, the Y position, and the Z position, respectively.

The illumination system 12 is configured similarly to the illumination system disclosed in, for example, US Pat. No. 5,729,331, and irradiates the mask M with exposure illumination light (illumination light) IL. As illumination light IL, for example, light containing at least one wavelength of i-line (wavelength 365 nm), g-line (wavelength 436 nm), and h-line (wavelength 405 nm) is used. In addition, the light source used in the illumination system 12 and the wavelength of the illumination light IL emitted from the light source are not particularly limited. Light or vacuum ultraviolet light such as F2 laser light (wavelength 157 nm) may be used.

The mask stage 14 holds a light transmissive mask M. As shown in FIG. The mask stage 14 is driven by a predetermined stroke at least in the scanning direction (X-axis direction) by a mask stage drive system (not shown) including, for example, a linear motor. Also, the mask stage 14 is driven by a fine movement drive system that moves its X position and Y position by a stroke in order to adjust the relative position with at least one of the illumination system 12, the stage device 20A, and the projection optical system 16. The positional information of the mask stage 14 is obtained by, for example, a mask stage position measurement system (not shown) including a linear encoder system and an interferometer system.

A projection optical system 16 is arranged below the mask stage 14 . The projection optical system 16 is a so-called multi-lens type projection optical system having the same configuration as the projection optical system disclosed in, for example, US Pat. No. 6,552,775, and forms an erect image, for example. It is equipped with multiple telecentric optical systems on both sides. Note that the projection optical system 16 does not have to be of the multi-lens type. It may be composed of one projection optical system such as that used in a semiconductor exposure apparatus.

In the exposure apparatus 10A, when the mask M positioned within a predetermined illumination area is illuminated by the illumination light IL from the illumination system 12, a projected image (partial pattern image) of the pattern of the mask M within the illumination area is produced. is formed in the exposure area by the projection optical system 16 . The mask M moves in the scanning direction relative to the illumination area (illumination light IL), and the substrate P moves relative to the exposure area in the scanning direction, whereby scanning exposure is performed on the substrate P. A pattern formed on the mask M (the entire pattern corresponding to the scanning range of the mask M) is transferred.

(Stage device 20A)
The stage device 20A includes a surface plate 22, a substrate table 24, a support device 26, and a substrate holder 28A.

The surface plate 22 consists of a rectangular plate-like member in a plan view (viewed from the +Z side) arranged so that its upper surface (+Z surface) is parallel to the XY plane. Located on F. The support device 26 is placed on the surface plate 22 in a non-contact manner and supports the substrate table 24 from below in a non-contact manner. The substrate holder 28A is arranged on the substrate table 24, and the substrate table 24 and the substrate holder 28A are integrally driven by a stage drive system (not shown) provided in the stage device 20A. The stage drive system includes, for example, a linear motor, etc., and includes a coarse movement system capable of driving the substrate table 24 in the X-axis and Y-axis directions (along the upper surface of the platen 22) with a predetermined stroke, and a voice coil motor, for example. and a fine movement system for finely driving the substrate table 24 in directions of six degrees of freedom (X-axis, Y-axis, Z-axis, θx, θy, and θz). Further, the stage device 20A includes, for example, an optical interferometer system, an encoder system, and the like, and has a stage measurement system for obtaining positional information of the substrate table 24 in directions of the six degrees of freedom.

As shown in FIG. 3A, the substrate P is placed on the upper surface TS (+Z side surface) of the substrate holder 28A which is rectangular in plan view. The top surface TS has substantially the same aspect ratio as the substrate P. As an example, the lengths of the long and short sides of the top surface TS are set slightly shorter than the lengths of the long and short sides of the substrate P, respectively.

The upper surface TS of the substrate holder 28A is finished flat over the entire surface. In addition, a plurality of minute holes (not shown) for air blowing and minute holes (not shown) for vacuum suction are formed on the upper surface of the substrate holder 28A. It should be noted that a common hole may be used as both the minute hole for blowing air and the minute hole for vacuum suction. The substrate holder 28A uses a vacuum suction force supplied from a vacuum device (not shown) to suck the air between the upper surface and the substrate P through the plurality of holes, thereby sucking the substrate P onto the upper surface TS. It is possible to correct the surface (correct the surface). The substrate holder 28A is a so-called pin chuck type holder, and has a plurality of pins (pins with a very small diameter of, for example, about 1 mm) arranged at substantially equal intervals. By having the plurality of pins, the substrate holder 28A can reduce the possibility of supporting the substrate P with dust or foreign matter caught in the rear surface thereof, and can reduce the possibility of deformation of the substrate P due to the foreign matter being caught. The substrate P is held (supported) on the upper surfaces of the pins. The XY plane formed by the top surfaces of these pins is the top surface of the substrate holder 28A. Further, the substrate holder 28A supplies (supplies) pressurized gas (for example, air) from a pressurized gas supply device (not shown) between the upper surface TS and the substrate P through the hole. , the back surface of the substrate P attracted to the substrate holder 28A can be separated from the top surface TS (float the substrate P). In addition, in each of the plurality of holes formed in the substrate holder 28A, the timing of supplying the pressurized gas may be different, or the holes to be vacuum-sucked and the holes to be supplied with the pressurized gas may be different. The grounding state of the substrate P is controlled (for example, an air pool between the back surface of the substrate P and the top surface of the substrate holder 28A) is controlled by appropriately changing the location or changing the air pressure between suction and air supply. so that it does not occur).

The substrate holder 28A may correct the flatness of the substrate in a state in which the substrate is levitated instead of being sucked to the upper surface TS. In this case, the substrate holder 28A supplies (supplies) a pressurized gas (for example, air) from a pressurized gas supply device (not shown) to the back surface of the substrate P through the hole. A gas is interposed between the lower surface of P and the upper surface of the substrate holder 28A (that is, a gas film is formed). Further, the substrate holder 28A uses a vacuum suction device to suck the gas between the substrate holder 28A and the substrate P through the holes for vacuum suction, and the substrate P is subjected to a downward force (preload) in the direction of gravity. ) imparts rigidity in the direction of gravity to the gas film. The substrate holder 28A holds (supports) the substrate P in a non-contact manner by floating the substrate P in the Z-axis direction via a minute clearance by the balance between the pressure and flow rate of the pressurized gas and the vacuum suction force. A force for controlling the flatness (for example, a force for correcting or correcting the flatness) may be applied to P. Each hole may be formed by processing the substrate holder 28A, or the substrate holder 28A may be made of a porous material to supply or suck air. In addition, the upper surface TS of the substrate holder 28A that floats and supports the substrate P is not the surface where the hole is formed, but a virtual surface located above the surface by the above-described clearance, that is, the lower surface of the substrate whose plane has been corrected. is the top surface TS.

Further, as shown in FIG. 3A, two notches 28b, for example, are formed apart in the Y-axis direction at the +X side end of the upper surface TS of the substrate holder 28A. As shown in FIG. 3(c), the notch 28b opens to the top surface TS and the side surface on the +X side of the substrate holder 28A.

(Substrate transfer device 100A)
As shown in FIG. 1, the substrate transfer device 100A has a port section 150A, a substrate transfer section 160A, and a transfer device 180A. The port section 150A and the substrate transfer section 160A are installed on the +X side with respect to the stage device 20A. For example, the transfer of the substrate P between an external device (not shown) such as a coater/developer and the exposure device is performed by the substrate transfer device 100A. The substrate transfer section 160A is for transferring the exposed substrate P (P1) from the substrate holder 28A to the port section 150A, and for transferring the substrate P (P2) to be newly exposed from the port section 150A to the substrate holder 28A. be. The substrate P2 may be an unexposed substrate (that has not been exposed even once), or may be a substrate that will be exposed for the second and subsequent times.

Also, the transfer of the substrate P between the external device and the exposure apparatus 10A is performed by a chamber (not shown) housing the illumination system 12, the mask stage 14, the projection optical system 16, the stage device 20A, the substrate transfer device 100A, and the like. This is done by an external conveying device 300 arranged outside. The external transport device 300 has a fork-shaped robot hand, and can transport the mounted substrate P from the external device to the port section 150A in the exposure apparatus 10A. Then, as described above, the substrate transfer section 160A transfers the substrate P from the port section 150A to the substrate holder 28A. The external transport device 300 can transport the exposed substrate P transported to the port section 150A by the substrate transport device 100A from inside the chamber to an external device.

As shown in FIG. 2, the port section 150A has a beam unit 152 composed of a plurality of (e.g., eight in the first embodiment) beams 153 arranged at predetermined intervals in the Y-axis direction. . A plurality of minute holes (not shown) for blowing out air are formed in the upper surface of each beam 153 . The beam unit 152 supplies pressurized gas (for example, air) from a pressurized gas supply device (not shown) between the back surface of the substrate P and the top surface of the beam unit 152 through the hole. ), it is possible to separate the back surface of the substrate P from the upper surface of the beam unit 152 (float the substrate P). The distance between the plurality of beams 153 in the Y-axis direction is such that the substrate P can be supported from below by the beam unit 152, and when the robot hand of the external transfer device 300 is arranged at the same height as the beam unit 152, the robot hand is is set so that it can be arranged (inserted and removed) between the plurality of beams 153 .

The length in the longitudinal direction (X-axis direction) of each beam 153 is slightly longer than the length in the longitudinal direction of the substrate P, and the length in the width direction (Y-axis direction) is the length of the substrate P in the width direction. For example, it is set to about 1/50, or about 10 to 50 times the thickness of the substrate P, for example.

As shown in FIG. 1, each of the plurality of beams 153 (in FIG. 1, they overlap in the depth direction of the paper surface) is positioned inside both ends in the X-axis direction by means of a plurality (for example, two) rod-shaped legs 154. supported from below. A plurality of legs 154 that support each beam 153 have their lower ends connected to the base portion 157 via joint portions 155a, and their upper ends connected to the beams 153 via joint portions 155b. In the substrate transfer apparatus 100A, a link mechanism composed of a beam 153, a leg 154, joint portions 155a and 155b, and a base portion 157 is used to integrally change the position of the beam unit 152 in the X-axis direction and the Z-axis direction. It has become. In the link mechanism, when the beam unit 152 stops at the substrate transfer position with the substrate holder 28A, the upper surface TS of the substrate holder 28A, the upper surface of the offset beam 185a described later, and the upper surface of the beam unit 152 are arranged substantially in the same plane. configured to be included.

Returning to FIG. 2, the substrate transfer section 160A has a fork-shaped hand 161A (hereinafter referred to as a substrate loading hand 161A) similar to the external transfer device 300 (see FIGS. 1 and 2). The substrate carrying-in hand 161A has a plurality of (for example, seven in the first embodiment) finger portions 162A. described).

The finger portions 162A are connected to each other by a connecting member 163A in the vicinity of the +X side end portion. On the other hand, the ends of the plurality of finger portions 162A on the -X side (substrate holder 28A (see FIG. 2) side) are free ends, and the adjacent finger portions 162A are on the substrate holder 28A side. is open.

As shown in FIG. 1, the substrate holding surface formed by the plurality of fingers 162A is inclined with respect to the holding surface on which the substrate holder 28A holds the substrate (hereinafter referred to as holder substrate holding surface). That is, the substrate carrying-in hand 161A has a substrate holding surface that is inclined with respect to the holder substrate holding surface of the substrate holder 28A and holds the substrate P (P2). Therefore, the board loading hand 161A holds the +X side end of the board P2 at a position (+Z side) higher than the -X side end of the board P2. As for the Z position of the substrate loading hand 161A, the −X side end of the substrate loading hand 161A is closer to the substrate holder 28A than the +X side end. Further, in the vicinity of the distal ends (−X side) of the plurality of finger portions 162A, the thickness of the finger portions 162A becomes thinner toward the distal ends. In other words, finger 162A has a tapered shape with a tapered tip. Since the fingers 162A have a tapered shape, the −X side end of the substrate P2 can be brought closer to the top surface TS of the substrate holder 28A compared to fingers 162A having a uniform thickness. . Further, since the area of the substrate loading hand 161A where the Z position is close to the substrate holder 28A can be reduced, the risk of contact between the substrate loading hand 161A and the substrate holder 28A can be reduced.

Each finger 162A of the substrate carrying-in hand 161A does not overlap the beam 153 of the beam unit 152 in plan view in the Y-axis direction, similarly to the robot hand (see FIG. 2) of the external transport device 300 described above. are placed. A plurality of support pads 164A for supporting the back surface of the substrate P are attached to each finger portion 162A, and the support pads 164A form a substrate holding surface of the substrate loading hand 161A. The substrate P does not have to be supported entirely on the support pads 164A. The substrate holding surface is formed by virtually connecting the support surfaces of the support pads 164A.

As shown in FIG. 2, the connecting member 163A is rectangular in plan view, is made of a thin hollow member, and extends in the Y-axis direction in which the beams 153 are arranged. Both ends of the connecting member 163A in the Y-axis direction are connected to a pair of X-axis driving devices 164 for moving the substrate loading hand 161A in the X-axis direction. The pair of X-axis drive devices 164 may be driven independently, or may be mechanically connected by gears or belts and driven simultaneously by one drive motor. Alternatively, the connecting member 163A may be configured to be moved only by the X-axis driving device 164 on one side, not limited to a pair, in the Y-axis direction. Also, the pair of X-axis driving devices 164 can be vertically moved by a Z-axis driving device (not shown). This allows the substrate loading hand 161A to move between a position higher than the upper surface of the beam unit 152 (+Z side) and a position lower than the beam unit 152 (-Z side).

Further, the substrate transfer section 160A includes one or a plurality of (for example, two in the first embodiment) substrate unloading hands 170A. In the first embodiment, two substrate unloading hands 170A are spaced apart in the Y-axis direction.

Each substrate unloading hand 170A has a holding pad 171A. The holding pad 171A can suck and hold the lower surface of the substrate P by a vacuum suction force supplied from a vacuum device (not shown).

The substrate unloading hand 170A is configured as, for example, an articulated robot or a parallel link robot, and can change the X-position, Y-position, and Z-position of the holding pad 171A.

(Conveyor 180A)
The transfer device 180A is a device that cooperates with the substrate transfer section 160A during substrate replacement. In other words, in the exposure apparatus 10A, the substrate P is transferred into and out of the substrate holder 28A using the substrate transfer section 160A and the transfer device 180A. The transport device 180A is also used for positioning the substrate P when the substrate P is placed on the substrate holder 28A. The conveying device 180A will be described in detail with reference to FIGS. 3(a) to 3(c).

The transfer device 180A includes a pair of substrate loading bearer devices 182A, a pair of substrate unloading bearer devices 183A, and an offset beam section 185, as shown in FIGS. 3(a) to 3(c).

The substrate carrying-in bearer device 182A includes a holding pad 184a, an X actuator 186x, and a Z actuator 186z, as shown in FIG. 3(b).

The holding pad 184a is made of a plate-like member that is rectangular in plan view, and is capable of sucking and holding the lower surface of the substrate P by a vacuum suction force supplied from a vacuum device (not shown). Also, as shown in FIG. 3B, the holding pad 184a can be driven in the Z-axis direction by a Z actuator 186z. Also, the holding pad 184a and the Z actuator 186z can be integrally driven in the X-axis direction by an X actuator 186x attached to the substrate table 24. As shown in FIG.

The substrate unloading bearer device 183A includes a holding pad 184b, an X actuator 186x, and a Z actuator 186z, as shown in FIG. 3(c). As shown in FIG. 3(c), the holding pad 184b of the substrate unloading bearer device 183A on one side (+Y side) is located on one side (+Y side) of, for example, two notches 28b formed in the substrate holder 28A. A part is inserted in the notch 28b. Also, the holding pad 184b of the other (-Y side) board unloading bearer device 183A is partially inserted into the other (-Y side) notch 28b.

The holding pad 184b is made of a plate-like member that is rectangular in plan view, and is capable of sucking and holding the lower surface of the substrate P by a vacuum suction force supplied from a vacuum device (not shown).

As shown in FIG. 3(c), the holding pad 184b can be driven in the Z-axis direction by a Z actuator 186z. Also, the holding pad 184b and the Z actuator 186z can be integrally driven in the X-axis direction by an X actuator 186x attached to the substrate table 24. As shown in FIG. Z-actuator 186z includes a post that supports retaining pad 184b and is located outside substrate holder 28A. The holding pad 184b is driven in the notch 28b by the Z actuator 186z, so that it can move between a position where it can be held in contact with the bottom surface of the substrate P and a position where it is separated from the bottom surface of the substrate P. ing. Also, the holding pad 184b can be moved between a position partially accommodated in the notch 28b and a position higher than the upper surface of the substrate holder 28A by means of a Z actuator 186z. Further, the holding pad 184b is movable in the X-axis direction by being driven integrally with the Z actuator 186z by the X actuator 186x.

The offset beam section 185 has a plurality of (for example, eight in the first embodiment) offset beams 185a arranged at predetermined intervals in the Y-axis direction. The offset beam 185a is supported by a support member 185b attached to the substrate table 24, and arranged so that its upper surface and the upper surface TS of the substrate holder 28A are included in substantially the same plane. A plurality of minute holes (not shown) for blowing out air are formed on the upper surface of the offset beam 185a. The offset beam 185a supplies pressurized gas (air) supplied from a pressurized gas supply device (not shown) between the upper surface of the offset beam 185a and the back surface of the substrate P through the hole. do. This makes it possible to separate the back surface of the substrate P from the top surface of the offset beam 185a (float the substrate P).

Details of the operation of the transport device 180A will be described later.

The configurations of the board loading bearer device 182A and the board unloading bearer device 183A can be changed as appropriate. For example, each bearer device 182A, 183A is attached to the substrate table 24 in this embodiment, but is not limited to this. (not shown). Also, the positions and number of the bearer devices 182A and 183A are not limited to this, and may be attached to the +Y side and -Y side sides of the substrate table 24, for example.

In the exposure apparatus 10A (see FIG. 1) configured as described above, a mask loader (not shown) loads the mask M onto the mask stage 14 under the control of a main controller (not shown). , the substrate transfer device 100A carries the substrate P onto the substrate holder 28A. After that, the main controller performs alignment measurement using an alignment detection system (not shown), and after the alignment measurement is completed, a plurality of shot areas set on the substrate P are sequentially exposed by the step-and-scan method. Action is performed. Since this exposure operation is the same as the conventional step-and-scan exposure operation, the X direction is set as the scanning direction. A detailed description of the step-and-scan exposure operation will be omitted. Then, the substrate P (P1) that has undergone the exposure process is unloaded from the substrate holder 28A by the substrate transport device 100A, and another substrate P (P2) to be exposed next is loaded into the substrate holder 28A. , the substrates P on the substrate holder 28A are exchanged, and a series of exposure operations for a plurality of substrates P is performed.

(Substrate replacement operation)
The exchange operation of the substrate P on the substrate holder 28A in the exposure apparatus 10A will be described below with reference to FIGS. 4 to 8. FIG. The following board exchange operation is controlled by a main controller (not shown). 4 to 8 for explaining the substrate exchanging operation, illustration of the X-axis driving device 164 and the like is appropriately omitted in order to facilitate understanding of the operation of the substrate transfer section 160A.

Further, in the following description, an exposed substrate P1 is placed on the substrate holder 28A of the stage device 20A in advance. A carrying-in operation for placing the substrate on the substrate holder 28A will be described. In each of FIGS. 4 to 8, the operating directions of the components are schematically indicated by white arrows for easy understanding. A group of black arrows schematically indicates the state of sucking or supplying (supplying) gas.

As shown in FIGS. 4(a) and 4(b), the substrate loading hand 161A has the upper surface of the substrate loading hand 161A that is positioned at the beam unit until the substrate P2 is transported to the port section 150A by the external transport device 300. As shown in FIGS. 152 is moved. At this time, the leg 154 of the port portion 150A is rotationally driven in the θy direction. Thereby, the substrate loading hand 161A is arranged below the beam unit 152 so that the robot hand of the external transport device 300 can be arranged between the beam unit 152 and the substrate loading hand 161A in the Z direction.

This position of the port portion 150A is the board transfer position with respect to the external transfer device 300. As shown in FIG.

The robot hand of the external transfer device 300 holding the substrate P2 is moved in the -X direction so that the substrate P2 is positioned above the beam unit 152 (+Z side). At this time, the robot hand of the external transport device 300 and the fork-shaped robot hand of the external transport device 300 are arranged so that the fingers of the fork-shaped robot hand of the external transport device 300 are positioned in the gaps between the beam units 152 adjacent to each other in the Y-axis direction in plan view. The Y position with beam unit 152 is positioned.

Next, as shown in FIG. 4(c), the robot hand of the external transport device 300 is driven to descend, and each finger of the robot hand passes through the gaps between the beams of the beam unit 152, whereby the external transport is performed. Apparatus 300 delivers substrate P2 onto beam unit 152 . The Z position of the robot hand of the external transport device 300 is controlled so as not to contact the substrate transport section 160A waiting below the beam unit 152 . After that, the robot hand of the external transport device 300 is driven in the +X direction to leave the exposure apparatus 10A.

The substrate transfer section 160A is moved upward (moved in the +Z direction), and the holding pad 171A of the substrate unloading hand 170A holds the lower surface of the substrate P2 on the beam unit 152 by suction. After that, as shown in FIG. 5A, pressurized gas is supplied to each of the beams 153 of the beam unit 152 of the port section 150A, and the pressurized gas is supplied from the upper surface of each of the beams 153. Air is supplied (jetted) toward the lower surface of the substrate P2. As a result, the substrate P2 is floated with respect to the beam unit 152 with a small gap (for example, several tens of micrometers to several hundreds of micrometers) while being sucked and supported by the substrate transfer section 160A. Also, the beam unit 152 is moved in the -X direction and the -Z direction by rotationally driving the leg 154 of the port portion 150A in the θy direction.

The holding pad 171A of the substrate unloading hand 170A sucking and gripping the lower surface of the substrate P2 is finely driven in the X-axis, Y-axis, and θz directions (three degrees of freedom in the horizontal plane). position adjustment (alignment) is performed. Since the substrate P2 is supported by the beam unit 152 in a non-contact manner, it is possible to adjust the position of the substrate P2 in the directions of three degrees of freedom in the horizontal plane (move by minute amounts) in a low-friction state. Note that the position adjustment (alignment) of the substrate P2 described here can be omitted, and may be controlled to be performed as necessary.

Thereafter, the substrate transfer section 160A is driven upward in the +Z direction to the position shown in FIG. 5(b). As a result, the substrate P2 on the beam unit 152 is transferred to the substrate carry-in hand 161A. In other words, the substrate P2 on the beam unit 152 is scooped up from below by the substrate carry-in hand 161A.

The beam unit 152 is further driven in the -X direction by further rotationally driving the leg 154 in the θy direction, and is moved to the substrate transfer position (Fig. 5 ( c) to the position illustrated in).

In addition, in parallel with the operation of transferring the substrate P2 from the external transport device 300 to the substrate loading hand 161A via the port portion 150A (including an alignment operation as appropriate), the exposed substrate P1 is placed on the stage device 20A. The substrate table 24 is moved in the +X direction so that the placed substrate holder 28A is placed at a predetermined substrate exchange position (substrate transfer position with respect to the port portion 150A). In the first embodiment, the board exchange position of the board holder 28A is the position on the -X side with respect to the port section 150A. For ease of understanding, the substrate holder 28A is shown at the same position in FIGS. 4A and 5B. The exposure operation for the substrate P1 is performed in parallel with the transfer operation from the apparatus 300 to the substrate carry-in hand 161A, and the substrate holder 28A is appropriately moved in the X and Y directions at that time.

In parallel with the operation of moving the substrate holder 28A to the substrate exchange position, the holding pads 184b of the pair of substrate unloading bearer devices 183A are driven upward. The holding pad 184b holds a part of the substrate P1 held by vacuum adsorption on the upper surface of the substrate holder 28A (the part arranged on the notch 28b (see FIGS. 3A and 3C)). Suction and grip from.

Thereafter, as shown in FIG. 5(c), the substrate carrying-in hand 161A supporting the substrate P2 is moved in the -X direction. As a result, the substrate carrying-in hand 161A is moved above the substrate holder 28A positioned at the substrate exchange position. On the other hand, the Z position of the upper surface of the beam unit 152 and the Z position of the upper surface of the substrate holder 28A are set at substantially the same height. In setting these to substantially the same height, the substrate holder 28A may be driven in the Z-axis direction to adjust the height.

In the offset beam portion 185, pressurized gas is jetted from the upper surface of the offset beam 185a.

Further, in the stage device 20A, the pressurized gas is supplied (jetted) from the upper surface of the substrate holder 28A to the lower surface of the substrate P1. As a result, the substrate P1 floats from the top surface TS of the substrate holder 28A, and the friction between the bottom surface of the substrate P1 and the top surface TS of the substrate holder 28A becomes low.

Further, in the stage device 20A, the holding pads 184b of the substrate carry-out bearer device 183A are driven slightly upward in the +Z direction so as to follow the floating operation of the substrate P1, and a part of the substrate P1 is suction-held. , it is moved in the +X direction (port portion 150A side) with a predetermined stroke. The amount of movement of the holding pad 184b (that is, the substrate P1) is set to, for example, approximately 50 mm to 100 mm. As a result, the +X side end of the substrate P1 is supported by the offset beam 185a in a non-contact manner, and the position of the substrate P1 is offset from the substrate holder 28A in the X direction by a predetermined amount in the +X direction.

Furthermore, in the stage device 20A, the holding pads 184a of the pair of substrate carry-in bearer devices 182A are moved in the +X direction with a predetermined stroke.

As shown in FIG. 6A, the substrate loading hand 161A supporting the substrate P2 is arranged at a predetermined position above the substrate holder 28A. As a result, the substrate P2 is positioned almost directly above the substrate holder 28A positioned at the substrate replacement position. At this time, the substrate carry-in hand 161A and the substrate holder 28A are positioned such that the Y position of the substrate P1 and the Y position of the substrate P2 substantially match. On the other hand, with respect to the X direction, the substrates P1 and P2 are arranged at different positions. Specifically, as described above, the X positions of the substrates P1 and P2 are relatively different by the amount that the substrate P1 is offset from the substrate holder 28A to the +X side, and the edge of the substrate P2 on the -X side is is arranged (protrudes) on the -X side of the -X side end of the substrate P1. At this time, the substrate P2 on the substrate carrying-in hand 161A may be suction-held by the substrate carrying-out hand 170A at its lower surface, or may be held by the fingers 162A by suction-holding or frictional force. Note that the notch 28b may not be formed in the substrate holder 28A. As described above, when the lengths of the long and short sides of the upper surface of the substrate holder 28A are set slightly shorter than the lengths of the long and short sides of the substrate P, the substrate holder 28A protrudes from the substrate holder 28A. If the substrate P can be moved in the +X-axis direction while being held by the holding pad 184b, and the substrate P can be offset from the upper surface TS of the substrate holder 28A to the +X side, the notch 28b can be positioned on the substrate holder 28A. need not be formed. In this case, even at the edge of the substrate P, the flatness of the substrate holder 28A can be corrected.

After that, as shown in FIG. 6B, the substrate carrying-in hand 161A is driven in the -Z direction to a position where it does not come into contact with the substrate holder 28A. The board loading hand 161A brings the -X side end of the board P2 (part of the board P2) into contact with the holding pad 184a of the board loading bearer device 182A. The holding pad 184a sucks and holds a portion of the substrate P2 on the substrate loading hand 161A from below. The holding pad 184a sucks and holds a part of the substrate P2 at a position in the Z-axis direction between the upper surface of the substrate holder 28A and the substrate holding surface of the substrate carrying-in hand 161A. When holding the substrate P2 by suction, the holding pad 184a constrains the X position and the Y position of the substrate P2. This can prevent the substrate P2 from being moved outside the substrate loading hand 161A. The board carry-in bearer device 182A holds the narrow area of the -X side end of the board P2. More specifically, the area is such that the substrate carrying-in bearer device 182A alone cannot support the entire substrate P2. Although it has been described that the X-direction dimension of the finger portion of the substrate loading hand 161A is shorter than the X-direction dimension of the substrate P2, the same dimension may be used, and the X-direction dimension of the substrate loading hand 161A finger portion may be smaller. can be longer. In that case, the holding pad 184a should hold the area between the fingers of the board loading hand 161A.

In parallel with the suction holding operation of the substrate P2 by the holding pads 184a, the substrate carry-out hand 170A that released the suction grip of the substrate P2 is driven, and the portion of the substrate P1 offset to the +X side from the substrate holder 28A is moved. Suction grips the lower surface. Also, the beam unit 152 ejects pressurized gas.

After that, as shown in FIG. 6(c), the holding pad 184a of the board carry-in bearer device 182A sucks and holds a part (-X side end) of the board P2, and the board transfer section 160A moves in the unloading direction ( +X direction). At this time, it is preferable to supply (spout) the pressurized gas from the finger portion 162A of the substrate carrying-in hand 161A to the lower surface of the substrate P2 to reduce the contact friction.

The substrate transfer unit 160A is driven in the unloading direction (+X direction), and the substrate unloading hand 170A holding the substrate P1 is driven in the +X direction. As a result, the substrate P1 moves from the substrate holder 28A onto the port section 150A (beam unit 152). At this time, since the pressurized gas is jetted from the upper surface of each of the beams 153 of the beam unit 152, the substrate P1 is held in a non-contact state (floating state) with respect to the substrate holder 28A and the port section 150A. 28A is carried out. Further, the holding pads 184b of each of the pair of substrate unloading bearer devices 183A are arranged in a −Z direction so that a part thereof is accommodated in the notch 28b (see FIGS. 3A and 3C) of the substrate holder 28A. and -X directions.

Further, as shown in FIGS. 6(c) and 7(a) to 7(c), by moving the substrate loading hand 161A in the +X direction, the substrate P2 partly held by the holding pads 184a is moved. , the substrate carrying-in hand 161A is moved relative to the X direction. Then, as shown in FIG. 7C, the substrate loading hand 161A is moved to the +X side of the substrate holder 28A in the X direction, so that the substrate loading hand 161A moves above the substrate holder 28A (on the +Z side). space) and below the substrate P2 (space on the −Z side). In other words, the substrate carrying-in hand 161A is moved to the +X side of the substrate holder 28A, thereby retreating from the space between the substrate P2 partly held by the holding pad 184a and the substrate holder 28A. When moving to the +X side of the substrate holder 28A, the substrate loading hand 161A moves above the substrate holder 28A, that is, in a position where the Z position is higher than the upper surface of the substrate holder 28A. In this way, the substrate P2 is transferred from the substrate loading hand 161A to the substrate holder 28A by retracting the substrate loading hand 161A from the space between the substrate P2 and the substrate holder 28A. That is, the substrate P2 is loaded from the substrate loading hand 161A to the substrate holder 28A. A region of the substrate P2 between the substrate loading hand 161A and the holding pad 184a is held by the substrate holder 28A.

Here, the holding pad 184a holds a part of the substrate P2 by suction, thereby fixing the relative position of the substrate P2 with respect to the substrate holder 28A or limiting it within a predetermined minute movable range in the X direction and the Y direction. ing. This predetermined movable range is set by the driving range of the holding pad 184a with respect to the substrate holder 28A (or substrate table 24). Note that the holding pad 184a does not necessarily need to be the substrate table 24 (or It may not be installed on the substrate holder 28A). For example, it may be installed on a structure such as a column (not shown) of the exposure apparatus 10A and suspended from above the substrate holder 28A. In this case, the holding pad 184a may hold the upper surface of the substrate P2.

As described above, the substrate loading hand 161A moves relative to the substrate holder 28A in the +X direction, that is, in the direction along the substrate holding surface of the substrate holder 28A and in the direction parallel to the substrate holding surface of the substrate holder 28A. Part of the substrate P2 is sequentially placed on the substrate holder 28A from the -X side as it is retracted from below P2. At this time, the area of the substrate P2 held by the substrate carrying-in hand 161A decreases, and the area of the substrate P2 supported by the holder substrate holding surface of the substrate holder 28A increases. As a result, the substrate loading hand 161A is moved from the space between the substrate holder 28A and the substrate P2 until the −X side tip of the substrate loading hand 161A is moved to the +X side of the substrate holder 28A. During at least a part of the period until retraction), the substrate loading hand 161A, the substrate holder 28A, and the holding pad 184a simultaneously support (or hold) different portions of the substrate P2. In other words, almost the entire surface of the substrate P2 is supported by the substrate carry-in hand 161A, the substrate holder 28A and the holding pad 184a during at least a part of the period (an arbitrary portion of the substrate P2 is supported by the substrate carry-in hand 161A, the substrate holder 28A and the holding pad 184a). supported by either of the retaining pads 184a). The support (or holding) of the substrate P2 by the substrate carrying-in hand 161A and the substrate holder 28A is not limited to a contact state, but is supported (or held) in a non-contact state via a gas (air gap). good too.

In addition, as described above, during the period until the -X side tip of the substrate loading hand 161A is moved to the +X side of the substrate holder 28A, the substrate P2 supported portion by the substrate loading hand 161A in the Z-axis direction ( The position (Z position) in the direction perpendicular to the holder substrate holding surface of the substrate holder 28A is higher than the Z position of the portion of the substrate P2 held by the holding pads 184a. Further, as the substrate loading hand 161A is retracted in the +X direction from the space between the substrate P2 and the substrate holder 28A as described above, the position of the supported portion of the substrate P2 supported by the substrate holder 28A in the Z-axis direction ( Z position) is gradually lowered. In the case where the substrate P2 has low flexibility (has rigidity and is hard to bend), as the substrate loading hand 161A is retracted, the substrate P2 is circular in the θy direction with the portion held by the holding pad 184a as the axis. It lands on the substrate holder 28A as if it were moving, but in this case also, the Z position of the supported portion of the substrate P2 by the substrate carry-in hand 161A is gradually lowered. Further, the position (X position) in the X-axis direction of the supported portion of the substrate P2 supported by the substrate holder 28A is gradually moved in the +X direction.

Further, as the substrate carrying-in hand 161A retreats from below the substrate P2 as described above, the substrate P2 is sequentially placed on the substrate holder 28A from the -X side. measures the position of the substrate P2 with respect to the substrate holder 28A. Based on the measurement results, the holding pads 184a of each of the pair of substrate carry-in bearer devices 182A are driven in at least one of the X-axis direction and the Y-axis direction. Thereby, the X-axis direction position, the Y-axis direction position, and the angle in the θz direction of the substrate P2 with respect to the substrate holder 28A are adjusted. When performing rotational adjustment in the θz direction, each holding pad 184a may be driven by a different amount. Note that the position measuring device (not shown) may be arranged, for example, at least one of the stage device 20A (for example, the substrate holder 28A and the substrate table 24) or a structure such as a column (not shown) included in the exposure apparatus 10A.

The substrate P2 transferred from the substrate carrying-in hand 161A to the substrate holder 28A is placed on the substrate holder 28A except for the portion held by suction by the holding pads 184a, as shown in FIG. 8(a). Note that the holding pad 184a may be driven in the Z-axis direction to assist the operation of transferring the substrate P2 to the substrate holder 28A. At this time, the supply (ejection) of the pressurized gas from the substrate holder 28A acts as air resistance, and the substrate P2 can be prevented from colliding directly with the substrate holder 28A, thereby preventing damage to the substrate P2. Moreover, even if the pressurized gas is not supplied (jetted) from the substrate holder 28A, the air between the upper surface of the substrate holder 28A and the substrate P2 acts as an air resistance, and the above effect can be obtained. Thereafter, by stopping the supply (jetting) of the pressurized gas from the substrate holder 28A, the substrate P2 lands on the upper surface TS of the substrate holder 28A and comes into contact with the upper surface TS. As a result, the X-axis position, the Y-axis position, and the angle in the θz direction of the substrate P2 with respect to the substrate holder 28A do not change.

Also, the beam unit 152 stops jetting the pressurized gas to the substrate P1. The board unloading hand 170A releases the grip of the board P1.

After the board unloading hand 170A releases the grip of the board P1, the board transfer section 160A is driven upward. The beam unit 152 with the substrate P1 placed thereon is moved to the substrate transfer position with respect to the external transport device 300 .

As shown in FIG. 8(b), when the substrate P2 is placed on the substrate holder 28A, the holding pads 184a release the adsorption grip of the substrate P2 and move in the -X direction so as to retreat from below the substrate P2. do. As a result, the portion of the substrate P2 held by the holding pads 184a is placed on the upper surface of the substrate holder 28A.

The robot hand of the external transport device 300 is driven in the −X direction at a Z position lower than the beam unit 152 and arranged below the beam unit 152 .

Thereafter, as shown in FIG. 8C, the stage device 20A moves to a predetermined exposure start position while holding the substrate P2 by suction with the substrate holder 28A. Description of the operation of the stage device 20A during the exposure operation for the substrate P2 will be omitted.

On the other hand, the robot hand of the external transfer device 300 is moved upward to pick up the substrate P1 on the beam unit 152 from below. The robot hand of the external transfer device 300 holding the exposed substrate P1 is moved in the +X direction and exits from the exposure device 10A.

Thereafter, in the port section 150A, the beam unit 152 is moved in the -X direction to avoid contact with the substrate loading hand 161A, and the substrate loading hand 161A is moved in the +X direction.

After the exposed substrate P1 is transferred to an external device (not shown) such as a coater/developer, the robot hand of the external transport device 300 holds the substrate P3, which is to be exposed next to the substrate P2. and is moved toward the port portion 150A.

Then, as described with reference to FIG. 4A, the upper surface of the substrate carry-in hand 161A is positioned below the lower surface of the beam unit 152 by the time the external transport device 300 carries the new substrate P3 to the port section 150A. The substrate transfer section 160A is moved downward (moved in the -Z direction) so as to be positioned. By repeating the operations shown in FIGS. 4(a) to 8(c) in this manner, the exposure operation and the like can be continuously performed on a plurality of substrates P. FIG.

As described in detail above, the substrate P2 changes from being held only by the substrate loading hand 161A to being held by the substrate loading hand 161A and the holding pad 184a. The substrate P2 is held by the substrate loading hand 161A, the substrate loading bearer device 182A and the substrate holder 28A as the substrate loading hand 161A moves relative to the substrate holder 28A. Then, as shown in FIG. 7C, when the substrate loading hand 161A is moved to a position where the X-axis direction position of the substrate loading hand 161A does not overlap the substrate holder 28A, the substrate P2 is transferred to the substrate loading bearer device 182A. It is held by the substrate holder 28A and finally supported only by the substrate holder 28A. The substrate P2 is loaded into the substrate holder 28A while being held by one of the substrate loading hand 161A, the substrate holder 28A, and the holding pad 184a.

As described in detail above, the operation of unloading the substrate P1 from the substrate holder 28A and the operation of loading the substrate P2 into the substrate holder 28A can be performed at least partially in parallel. time can be shortened. Further, when the substrate P2 is loaded into the substrate holder 28A, the substrate loading hand 161A moves above the substrate holder 28A (space on the +Z side). Hand 161A can be driven. As a result, the operation of loading the substrate P2 into the substrate holder 28A can be performed quickly, so that the substrate replacement time can be shortened. Further, by moving the substrate loading hand 161A above the substrate holder 28A to the +X side, the substrate P2 can be loaded into the substrate holder 28A while the substrate P1 is unloaded from the substrate holder 28A. In other words, since a common drive system is used for loading and unloading substrates, there is no need to provide separate drive systems for loading and unloading substrates, and the number of drive systems can be reduced.

As described above in detail, according to the first embodiment, in the substrate transfer device 100A that transfers the substrate P2 to the substrate holder 28A, the substrate carrying-in hand 161A that holds the substrate P2 above the substrate holder 28A and the substrate A substrate loading bearer device 182A that holds a portion of the substrate P2 held by the loading hand 161A, and a substrate holder 28A, the substrate loading bearer device 182A, and the substrate so that the substrate loading hand 161A is retracted from above the substrate holder 28A. and an X-axis driving device 164 that moves one of the loading hands 161A relative to the other. holds the substrate P2. As a result, the substrate P2 is placed on the substrate holder 28A in order from the end on the -X side (the side opposite to the port portion 150A), so that the substrate holder 28A and the substrate P2 are less likely to be scratched and dust is generated due to contact. decreases. In addition, air is less likely to be trapped between the substrate holder 28A and the substrate P2, and the substrate P2 is less likely to wrinkle. Moreover, it is possible to prevent the substrate P2 from moving on the substrate holder 28A. Furthermore, the placement of the substrate P2 on the substrate holder 28A can be controlled (for example, the placement can be stopped halfway) according to the withdrawal status (speed/position) of the substrate carry-in hand 161A. Therefore, it is not necessary to jet the pressurized gas in order to reduce the friction from the substrate carry-in hand 161A to the substrate P2. Also, a mechanism for driving the substrate carry-in bearer device 182A up and down can be omitted.

Further, according to the first embodiment, in the substrate transfer device 100A that transfers the substrate P2 to the holder substrate holding surface of the substrate holder 28A, the substrate P2 is provided above the holder substrate holding surface, and the part of the substrate P2 and the holder substrate holding surface are separated from each other. A substrate carry-in hand 161A holding a substrate P2 whose distance from the surface is shorter than the distance between the other portion of the substrate P2 and the holder substrate holding surface, and the other portion of the substrate P2 held by the substrate carry-in hand 161A. The substrate holder 28A, the substrate loading bearer device 182A, and the substrate loading hand 161A are moved in a direction along the holder substrate holding surface so that the substrate loading bearer device 182A and the substrate loading hand 161A are retracted from above the substrate holder 28A. and an X-axis drive 164 for moving. As a result, the substrate P2 can be placed on the substrate holder 28A in order from the end on the -X side (opposite side to the port portion 150A). Reduces dust generation due to In addition, air is less likely to be trapped between the substrate holder 28A and the substrate P2, and the substrate P2 is less likely to wrinkle. Moreover, it is possible to prevent the substrate P2 from moving on the substrate holder 28A. Furthermore, the placement of the substrate P2 on the substrate holder 28A can be controlled (for example, the placement can be stopped halfway) according to the withdrawal status (speed/position) of the substrate carry-in hand 161A. Therefore, it is not necessary to jet the pressurized gas in order to reduce the friction from the substrate carry-in hand 161A to the substrate P2. Also, a mechanism for vertically moving the substrate carry-in bearer device 182A can be omitted.

Further, according to the first embodiment, in the substrate transfer apparatus 100A that transfers the substrate P2 to the holder substrate holding surface of the substrate holder 28A capable of holding the substrate P2, the substrate holding device that holds the substrate P2 above the substrate holder 28A is provided. a substrate loading hand 161A having a surface, a substrate loading bearer device 182A holding a portion of the substrate P2 held by the substrate loading hand 161A at a position between the holder substrate holding surface and the substrate holding surface in the vertical direction; With the board carry-in bearer device 182A holding a part of the board P2 so that the board carry-in hand 161A is retracted from above the board holder 28A, the board holder 28A and the board carry-in bearer device 182A and the board carry-in hand 161A are moved. and an X-axis driving device 164 for relative movement. As a result, the substrate P2 can be placed on the substrate holder 28A in order from the end on the -X side (opposite side to the port portion 150A). Reduces dust generation due to In addition, air is less likely to be trapped between the substrate holder 28A and the substrate P2, and the substrate P2 is less likely to wrinkle. Moreover, it is possible to prevent the substrate P2 from moving on the substrate holder 28A. Furthermore, the placement of the substrate P2 on the substrate holder 28A can be controlled (for example, the placement can be stopped halfway) according to the withdrawal status (speed/position) of the substrate carry-in hand 161A. Therefore, it is not necessary to jet the pressurized gas in order to reduce the friction from the substrate carry-in hand 161A to the substrate P2. Also, a mechanism for vertically moving the substrate carry-in bearer device 182A can be omitted.

Further, according to the first embodiment, in the substrate transfer device 100A that transfers the substrate P2 to the holder substrate holding surface of the substrate holder 28A, the substrate loading hand 161A that holds the substrate P2 above the substrate holder 28A and the substrate loading hand 161A that holds the substrate P2 above the substrate holder 28A. A substrate loading bearer device 182A that holds a portion of the substrate P2 held by the hand 161A; and an X-axis driving device 164 for relatively moving the hand 161A and the hand 161A in a predetermined direction along the holder substrate holding surface. The substrate P2 is held so that the vertical position of the area held by the hand 161A approaches the substrate holder 28A. As a result, the substrate P2 can be placed on the substrate holder 28A in order from the end on the -X side (opposite side to the port portion 150A). Reduces dust generation due to In addition, air is less likely to be trapped between the substrate holder 28A and the substrate P2, and the substrate P2 is less likely to wrinkle. Moreover, it is possible to prevent the substrate P2 from moving on the substrate holder 28A. Furthermore, the placement of the substrate P2 on the substrate holder 28A can be controlled (for example, the placement can be stopped halfway) according to the withdrawal status (speed/position) of the substrate carry-in hand 161A. Therefore, it is not necessary to jet the pressurized gas in order to reduce the friction from the substrate carry-in hand 161A to the substrate P2. Also, a mechanism for vertically moving the substrate carry-in bearer device 182A can be omitted.

Further, in the first embodiment, the substrate holding surface of the substrate carrying-in hand 161A is inclined with respect to the holder substrate holding surface. As a result, when the substrate loading hand 161A retreats from between the substrate P2 and the substrate holder 28A, the substrate loading hand 161A moves away from the inclined lower surface of the substrate P2 (a direction different from the tangential direction to the lower surface of the substrate P2). Since it is retracted, contact wear can be reduced.

In addition, in the first embodiment, the X-axis driving device 164 moves one of the substrate holder 28A, the substrate carrying-in bearer device 182A, and the substrate carrying-in hand 161A in the direction along the holding surface where the substrate holder 28A holds the substrate P2. relative to the other. As a result, the substrate carry-in hand 161A retreats in a direction away from the inclined lower surface of the substrate P2 (a direction different from the tangential direction to the lower surface of the substrate P2), so contact wear can be reduced.

Further, in the first embodiment, the X-axis driving device 164 moves the substrate loading hand 161A in a direction parallel to the holder substrate holding surface of the substrate holder 28A. As a result, the substrate carrying-in hand 161A retreats in the direction away from the inclined lower surface of the substrate P2 (horizontal direction different from the tangential direction to the lower surface of the substrate P2), so contact wear can be reduced.

(First modification)
A first modified example is an example in which the configuration of the substrate transfer apparatus is changed. Specifically, the substrate transfer device 100B of the exposure apparatus 10B according to the first modified example has a state in which the upper surface of the substrate loading hand 161A is parallel to the holder substrate holding surface of the substrate holder 28A, and a state in which the upper surface of the substrate loading hand 161A is the substrate. A drive system is provided for switching between a state in which the holder 28A is tilted with respect to the holder substrate holding surface.

An exchange operation of the substrate P on the substrate holder 28A using the substrate transfer device 100B according to the first modified example will be described with reference to FIGS. 9(a) to 9(c).

The state of FIG. 9(a) shows the state where the stage device 20A is arranged at the substrate transfer position with respect to the port section 150A after the state of FIG. 5(a) in the first embodiment.

As shown in FIG. 9A, a substrate P2 is placed on the substrate loading hand 161A. At this time, the upper surface of the substrate loading hand 161A is parallel to the holder substrate holding surface of the substrate holder 28A.

After that, as shown in FIG. 9(b), the substrate loading hand 161A supporting the substrate P2 from below while keeping the upper surface of the substrate loading hand 161A substantially parallel to the holder substrate holding surface of the substrate holder 28A moves to -X. direction is driven. The operations of the stage device 20A, the substrate loading bearer device 182A, the substrate unloading bearer device 183A, and the offset beam 185a are the same as those described with reference to FIG.

After that, the substrate carrying-in hand 161A supporting the substrate P2 from below is arranged at a predetermined position above the substrate holder 28A.

Then, as shown in FIG. 9(c), the substrate carrying-in hand 161A is driven to tilt downward while being driven upward. That is, the substrate loading hand 161A is driven such that the upper surface of the substrate loading hand 161A is inclined with respect to the holder substrate holding surface of the substrate holder 28A. As a result, the tip of the board P2 comes into contact with the holding pad 184a of the board carry-in bearer device 182A. The holding pad 184a sucks and holds the vicinity of the −X side end of the substrate P2. The substrate loading hand 161A is positioned parallel to the holder substrate holding surface of the substrate holder 28A at the Z position where there is no risk of the tip coming into contact with the upper surface of the substrate holder 28A even if the tip is driven to tilt downward. It may be moved in the -X direction while being held.

Since subsequent operations are substantially the same as those of the first embodiment, description thereof is omitted.

According to the first modification, when the substrate P2 is transferred between the port portion 150A and the substrate loading hand 161A, the substrate P2 is loaded from one side while the substrate mounting surface of the port portion 150A and the top surface of the substrate loading hand 161A are parallel to each other. Since it can be transferred to the other, it is possible to reduce the possibility of damage to the substrate P2 during the transfer of the substrate.

Further, when the substrate loading hand 161A supporting the substrate P2 from below is moved in the -X direction, the distance in the Z direction between the port portion 150A and the substrate holder 28A and the substrate loading hand 161A can be increased. As a result, when the substrate loading hand 161A is moved in the -X direction, the possibility of contact between the port portion 150A and/or the substrate holder 28A and the substrate loading hand 161A is reduced.

The substrate loading hand 161A may be moved relative to the substrate holder 28A in the +X direction while gradually changing the inclination angle between the upper surface of the substrate loading hand 161A and the holder substrate holding surface of the substrate holder 28A. .

By tilting the substrate loading hand 161A as in the first modification, the substrate holding surface of the substrate loading hand 161A may be tilted with respect to the holder substrate holding surface of the substrate holder 28A.

(Second modification)
A second modified example is an example in which the shape of the finger portion of the board loading hand is changed. FIG. 10(a) is a perspective view of a substrate loading hand 161C according to the second modification, and FIG. 10(b) is a side view of the substrate loading hand 161C according to the second modification.

As shown in FIGS. 10(a) and 10(b), in a board loading hand 161C according to the second modification, the finger portion 162C is thicker at the +X side end and thinner toward the −X side end. It has a triangular cross section.

Note that the replacement operation of the substrate on the substrate holder 28A is the same as in the first embodiment, so the explanation is omitted.

As in the second modified example, the fingers of the substrate loading hand may have an XZ cross-sectional triangular shape that is thicker at the +X side end and thinner toward the −X side end. As a result, the rigidity of the fingers of the substrate loading hand is improved, so that the substrate loading hand 161C does not wobble when the substrate loading hand 161C is moved. can reduce the fear of Further, the driving mechanism for tilting the substrate loading hand 161A with respect to the substrate holder 28A (see FIG. 9(c)) as in the first modified example can be omitted.

(Third modification)
In the first embodiment, the tip of the board P2 is brought into contact with the holding pad 184a of the board carry-in bearer device 182A by moving the board carry-in hand to a predetermined position above the board holder 28A and then moving it down. In the third modification, the substrate carry-out hand 170A is used to bring the tip of the substrate P2 into contact with the holding pad 184a of the substrate carry-in bearer device 182A.

An exchange operation of the substrate P on the substrate holder 28A using the substrate transfer device 100D according to the third modification will be described with reference to FIGS. 11(a) and 11(b). 11(a) corresponds to the state of FIG. 6(a) of the first embodiment, and FIG. 11(b) corresponds to the state of FIG. 6(b) of the first embodiment.

As shown in FIGS. 11A and 11B, in a substrate transfer apparatus 100D according to the third modification, a substrate transfer section 160D includes a substrate loading hand 161C according to the second modification and a substrate unloading hand 170A. And prepare.

As shown in FIG. 11A, in the third modification, the substrate transfer position of the substrate loading hand 161C with the stage device 20A is on the +X side of the substrate transfer position of the substrate loading hand 161A in FIG. 6A. position.

Then, when the substrate carrying-in hand 161C reaches the substrate transfer position, the substrate carrying-out hand 170A sucking and gripping the lower surface of the substrate P2 is driven to extend its arm as shown in FIG. 11(b). As a result, the board P2 slides down along the board carry-in hand 161C, and the tip of the board P2 comes into contact with the holding pad 184a of the board carry-in bearer device 182A.

At this time, the support pad 164D attached to the upper surface of the finger portion 162C of the substrate loading hand 161C is preferably shaped like a rod extending in the extending direction of the finger portion 162C in order to smoothen the movement of the substrate. Also, when the substrate P2 is slid, pressurized gas may be ejected from the support pad 164D.

Note that the substrate transfer section 160D may include a plurality of substrate unloading hands 170A. While some of the plurality of substrate unloading hands 170A bring the tip of the substrate P2 into contact with the holding pad 184a, the remaining substrate unloading hands 170A may hold the exposed substrate P1 on the substrate holder 28A. good. As a result, when the tip of the substrate P2 is held by the holding pad 184a and the exposed substrate P1 is held by the remaining substrate unloading hand 170A, the substrate loading hand 161C is moved in the +X direction, and the substrate loading operation and the substrate unloading operation are performed. can be performed in parallel.

According to the third modification, only the substrate P2 is lowered by the substrate carry-out hand 170A, instead of moving the entire substrate transfer portion 160D, so that positioning can be performed more easily and accurately than by moving the entire substrate transfer portion 160D. can. In addition, the stroke of the substrate transfer section 160D in the X-axis direction can be shortened. Further, since the substrate P2 bends due to the action of gravity, even if the moving distance of the substrate loading hand 161C in the X-axis direction is shorter than the horizontal movement component of the substrate P2 due to the gradient of the substrate loading hand 161C, the tip of the substrate P2 can be bent. It can be brought close to the holding pads 184a of the substrate loading bearer apparatus 182A.

11A and 11B, the substrate loading hand 161C according to the second modification is used, but the substrate loading hand 161A according to the first embodiment may be used.

(Fourth modification)
A fourth modified example is an example in which the configuration of the board loading hand is changed. FIG. 12(a) is a top view of a substrate carrying-in hand 161E according to a fourth modification, and FIG. 12(b) is a cross-sectional view taken along line AA of FIG. 12(a).

As shown in FIG. 12(a), the board loading hand 161E includes a belt portion 166 at finger portions 162E1 at both ends in the Y-axis direction among a plurality of finger portions 162E. As shown in FIG. 12(b), the belt portion 166 includes a belt 166a and a pair of pulleys 166b. The belt 166a is arranged substantially parallel to the upper surface of the finger portion 162E1 so as to contact the back surface of the substrate P2 and form substantially the same surface as the upper surface of the support pad 164E placed on the finger portion 162E1. there is The belt 166a is made of a non-slip material with a large coefficient of friction, and is selected from, for example, stainless steel coated with urethane, silicon, rubber, or soft PVC (polyvinyl chloride).

13(a) and 13(b) are diagrams showing the operation of loading the substrate P2 into the substrate holder 28A using the substrate loading hand 161E.

As shown in FIG. 13A, after the tip of the board P2 is brought into contact with the holding pad 184a of the board carry-in bearer device 182A, the board carry-in hand 161E is moved while the holding pad 184a holds the tip of the board P2. It is moved relative to the substrate holder 28A in the +X direction. Then, since the belt 166a is made of a material having a large coefficient of friction, as shown in FIG. 166b circulates. As a result, the belt 166a obliquely descends on the substrate carrying-in hand 161E while restraining the position of the substrate P2 in the Y-axis direction. Therefore, the substrate P2 is carried into the substrate holder 28A while restrained by the belt 166a until just before the entire substrate P2 leaves the substrate carrying-in hand 161E.

In the first embodiment and the first to third modifications, the board loading hand is moved (retracted) in the +X direction while the -X side end of the board P2 is held by the holding pad 184a of the board loading bearer device 182A. (For example, FIG. 6(c), etc.). At this time, the portion of the substrate P2 other than the -X side end portion is in a state where the movement in the Y-axis direction is not restrained until it is supported by the substrate holder 28A.

On the other hand, in the fourth modification, while the substrate loading hand 161E is moving in the +X direction with the −X side edge of the substrate P2 held by the holding pad 184a, the +X side edge is moved by the substrate loading hand 161E. The substrate P2 is placed on the substrate holder 28A while being gripped and restrained from moving in the Y-axis direction. Therefore, according to the fourth modification, the substrate P2 can be restrained until just before the entire substrate P2 leaves the substrate carry-in hand 161E, so that the substrate P2 can be prevented from being dislocated.

It should be noted that the belt portion 166 may be controlled to feed by a motor or the like. In this case, the belt 166a may be sent out in synchronization with the timing of retracting the substrate carry-in hand 161E. Also, in this case, the belt 166a does not have to be an endless belt. Further, by independently moving the belts 166a provided on the finger portions 162E1 at both ends, the relative position adjustment (alignment) of the substrate P2 with respect to the substrate holder 28A can be performed on the substrate carrying-in hand 161E.

(Fifth modification)
A fifth modification is to change the configuration of the finger portion of the board loading hand. 14(a) and 14(b) are cross-sectional views schematically showing a substrate loading hand 161F according to the fifth modification.

As shown in FIG. 14A, the finger portion 162F of the board loading hand 161F has a first finger portion 162F1 and a second finger portion 162F2. The first finger portion 162F1 is hollow, and a wire rope 169A for moving the second finger portion 162F2 is arranged inside. The second finger portion 162F2 is connected to the first finger portion 162F1 via a pin 169B or the like so as to be rotatable around the Y axis. A wire rope 169A is connected to the second finger portion 162F2. By moving the wire rope 169A by a driving device (not shown), the second finger portion 162F2 rotates around the Y axis with the pin 169B as a fulcrum. As a result, only a partial area of the substrate P2 held by the second fingers 162F2 can be tilted with respect to the holder substrate holding surface of the substrate holder 28A.

Since other configurations are the same as those of the first embodiment, description thereof is omitted.

The board loading hand 161F may not have a drive mechanism with the wire rope 169A, and the second finger portion 162F2 may always be inclined with respect to the first finger portion 162F1.

According to the fifth modification, the drive mechanism for tilting the substrate carrying-in hand 161A (see FIG. 9C) as in the first modification can be omitted. Also, the tip portion of the second finger portion 162F2 can be thinned.

<<Second embodiment>>
Next, an exposure apparatus according to the second embodiment will be described with reference to FIGS. 15(a) to 25(b). The configuration of the exposure apparatus 10G according to the second embodiment is the same as that of the first embodiment except that the configuration and operation of a part of the substrate transport device are different. Elements having the same configurations and functions as those of the first embodiment are denoted by the same reference numerals as those of the first embodiment, and description thereof will be omitted.

15(a) and 15(b) are respectively a top view and a side view of an exposure apparatus 10G according to the second embodiment. 16(a) and 16(b) are perspective views of a substrate loading hand 161G according to the second embodiment.

(Stage device 20G)
In the first embodiment, the substrate holder 28A has the notch 28b for accommodating the holding pad 184b of the substrate unloading bearer device 183A (see FIGS. 3(a) and 3(c)). As shown in FIG. 15(a), the substrate holder 28G according to the second embodiment includes notches 28b for accommodating the holding pads 184a of the substrate carry-in bearer device 182G, in addition to the notches 28b.

(Substrate transfer device 100G)
In the substrate transfer apparatus 100G according to the second embodiment, each of the plurality of beams 153 included in the beam unit 152 is extended from both ends in the X-axis direction by a plurality (for example, two) rod-shaped legs 154 extending in the Z-axis direction. It is supported from below at the medial position. A plurality of legs 154 supporting each beam 153 are connected by a base plate 156 in the vicinity of their lower ends. In the substrate transfer apparatus 100G, the beam unit 152 is integrally moved in the X-axis direction by a predetermined stroke by moving the base plate 156 in the X-axis direction by a predetermined stroke by an X actuator (not shown). ing. Also, the beam unit 152 can move vertically in the Z-axis direction integrally by moving the base plate 156 in the Z-axis direction by the Z-actuator 158 . Note that the illustration of the base plate 156 is omitted in FIG. 15(a) and subsequent top views.

In the substrate transfer section 160G according to the second embodiment, as shown in FIG. 15A, the substrate loading hand 161G has a plurality of (e.g., eight in this embodiment) fingers 162G. The plurality of finger portions 162G are connected to each other by a connecting member 163G near the ends on the -X side. The connecting member 163G is configured to float and support the substrate P by supplying gas to the rear surface of the substrate P held by the substrate loading hand 161G. On the other hand, the +X side ends of the plurality of finger portions 162G are free ends, and the adjacent finger portions 162G are open to the port portion 150G side. Further, as shown in FIG. 15A, each finger 162G is arranged so that the positions in the Y-axis direction do not overlap with the plurality of beams of the beam unit 152 in plan view.

As shown in FIGS. 16A and 16B, among the plurality of finger portions 162G, finger portions 162G1 at both ends in the Y-axis direction have a thickness of -X side (substrate holder 28G side) in side view. It has a triangular shape that is thin and thicker on the +X side (port portion 150G side). On the other hand, the inner finger portion 162G2 is thinner on the port side than the finger portions 162G1 at both ends.

Arms 168 of a board loading hand 161G are attached to finger portions 162G1 at both ends of FIGS. 16(a) and 16(b). As shown in FIG. 15( a ), both ends of the arm 168 are connected to the X-axis driving device 164 .

As shown in FIGS. 15A and 15B, the substrate loading hand 161G has a pair of substrate picking hands 167G provided on finger portions 162G1 at both ends in the Y-axis direction. The substrate pick hand 167G can be moved by a predetermined stroke in the X-axis direction and the Z-axis direction by a driving device (not shown).

Further, the substrate pick hand 167G can suck and hold the lower surface of the substrate P by a vacuum suction force supplied from a vacuum device (not shown).

(Conveyor 180G)
The board carry-in bearer apparatus 182G differs from the board carry-in bearer apparatus 182A of the first embodiment in that the X actuator 186x is omitted. As shown in FIG. 15(b), the holding pad 184a of the substrate carry-in bearer device 182G is moved within the notch 28a by the Z actuator 186z, and moves to the position where it contacts the lower surface of the substrate P and the lower surface of the substrate P. As shown in FIG. It is movable between a position separated from the Also, the holding pad 184a can be moved between a position partially accommodated in the notch 28a and a position higher than the upper surface of the substrate holder 28G by the Z actuator 186z.

(Substrate replacement operation)
The operation of exchanging the substrate P on the substrate holder 28G in the exposure apparatus 10G according to the second embodiment will be described below with reference to FIGS. 17(a) to 24(b).

As shown in FIGS. 17A and 17B, while the stage device 20G is performing exposure processing, the external transport device 300 is moved in the −Z direction to place the substrate P2 on the beam unit 152. . After that, the external transport device 300 moves in the +X direction and leaves the exposure apparatus.

The substrate loading hand 161G is driven in the +X direction and enters under the beam unit 152 from the -X side (substrate holder 28G side).

After that, as shown in FIGS. 18(a) and 18(b), the stage device 20G that has completed the exposure process moves to the substrate transfer position with the substrate transfer section 160G.

The beam unit 152 is driven downward (driven in the -Z direction) by the Z actuator 158 while holding the substrate P2. At this time, a portion of the substrate P2 on the beam unit 152 comes into contact with the substrate pick hand 167G of the substrate carry-in hand 161G. The substrate pick hand 167G sucks and grips the lower surface of the substrate P2.

Thereafter, as shown in FIGS. 19A and 19B, in the stage device 20G, the substrate P1 on the substrate holder 28G is offset in the +X direction by the substrate unloading bearer device 183A. At this time, the substrate holder 28G and the offset beam 185a supply gas to the rear surface of the substrate P1 so that the substrate P is moved in a floated state.

Pressurized gas is ejected from each beam 153 of the beam unit 152 . Also, the beam unit 152 continues to descend gradually.

The substrate carry-in hand 161G is gradually moved in the -X direction while holding the substrate P2 on the beam unit 152 by suction with the substrate pick hand 167G. The substrate P2 moves in the -X direction as the substrate loading hand 161G moves in the -X direction.

Thereafter, as shown in FIGS. 20(a) and 20(b), the substrate loading hand 161G is moved in the -X direction to the X position where the crotch portion of the finger portion 162G and the beam unit 152 do not overlap in plan view. be.

The beam unit 152 is lowered to below the substrate loading hand 161G, and completely transfers the new substrate P2 to the substrate loading hand 161G. At this time, on the substrate loading hand 161G, the relative position of the substrate P2 with respect to the substrate loading hand 161G may be adjusted by a pair of substrate pick hands 167G.

After that, as shown in FIGS. 21(a) and 21(b), the substrate carrying-in hand 161G is moved in the -X direction while holding the substrate P2 to place it at a predetermined position above the substrate holder 28G.

In the stage device 20G, the holding pad 184a of the substrate carry-in bearer device 182G is driven upward by the Z actuator 186z. The substrate carry-in hand 161G pushes out the substrate P2 obliquely downward by the substrate pick hand 167G. As a result, the −X side end of the substrate P2 comes into contact with the holding pad 184a. As a result, the holding pad 184a contacts the substrate P2 on the substrate carrying-in hand 161G waiting above the substrate holder 28G from below, and sucks and holds the vicinity of the −X side end of the substrate P2. At this timing, the substrate pick hand 167G may adjust the position of the substrate P2 with respect to the substrate holder 28G.

In parallel with the suction holding operation of the substrate P2 by the holding pad 184a, the substrate unloading hand 170A is moved to suck and hold the lower surface of the portion of the substrate P1 offset to the +X side from the substrate holder 28G.

The beam unit 152 is moved in the -X and -Z directions and stops at the substrate transfer position with the substrate holder 28G. Also, pressurized gas is ejected from each beam 153 of the beam unit 152 . Thereby, the beam unit 152 serves as a guide for supporting the substrate P1 unloaded from the substrate holder 28G.

After that, the grip of the board P2 by the board pick hand 167G of the board loading hand 161G is released, and as shown in FIGS. With the −X side end portion sucked and held, the substrate transfer section 160G is driven in the unloading direction (+X side). When the substrate transfer section 160G is driven in the unloading direction (+X side), the substrate unloading hand 170A holding the substrate P1 is also driven in the +X direction.

As a result, the substrate P1 moves from the substrate holder 28G onto the port section 150G (beam unit 152). At this time, since the pressurized gas is jetted from the upper surface of the beam unit 152, the substrate P1 is placed on the substrate holder 28G and the port section 150G in a non-contact state (excluding the portion held by the substrate unloading hand 170A). ) is floated and transported.

Thereafter, as shown in FIGS. 23(a) and 23(b), the substrate carry-out hand 170A releases the grip of the substrate P1 and is moved in the -X direction together with the substrate carry-in hand 161G. The port section 150G is moved in the +X direction while holding the substrate P2 on the beam unit 152. FIG.

In the stage device 20G, after the substrate carry-in bearer device 182G has adjusted the position of the substrate P2 with respect to the substrate holder 28G, it is moved in the -Z direction by the Z actuator 186z, and partially accommodated in the notch 28a. As a result, the substrate P2 is attracted to the holder substrate holding surface of the substrate holder 28G. Note that the position adjustment (alignment) of the substrate P2 described here can be omitted, and may be controlled to be performed as necessary.

After that, as shown in FIGS. 24A and 24B, when the substrate loading hand 161G moves to a position where it does not interfere with the substrate P1, the beam unit 152 is moved in the +Z direction, and the substrate between the external transport device 300 and the external transport device 300 is moved. Move to the delivery position.

After recovering the substrate P1 on the beam unit 152, the external transport device 300 transports a new substrate P3 to the port section 150A.

As described above in detail, according to the second embodiment, the port portion 150G side is open between the adjacent finger portions 162G of the board loading hand 161G. As a result, the substrate carry-in hand 161G enters directly below the beam unit 152 from the substrate holder 28G side, and is driven upwardly of the beam unit 152 to pick up the substrate P2 on the beam unit 152 and move the substrate holder. It can move to the 28G side. Therefore, even when the substrate P2 is placed on the beam unit 152, the substrate loading hand 161G can enter below the substrate P2 with a short moving distance in the X-axis direction. That is, the substrate loading hand 161G can receive the substrate P2 on the beam unit 152 without moving to the position on the +X side of the port section 150G. Further, the substrate carry-in hand 161G can transfer the exposed substrate P1 onto the beam unit 152 without moving it to the position on the +X side of the port section 150G. That is, a series of operations of loading the substrate P2 and unloading the substrate P1 can be performed without changing the positional relationship in the X direction among the external transport device 300, the port section 150G, the substrate loading hand 161G, and the substrate holder 28G. Furthermore, since it is not necessary to install the chamber so as to provide a space for the substrate loading hand 161G to move to the position on the +X side of the port section 150G, the footprint of the exposure apparatus, that is, the installation area of the exposure apparatus 10G can be reduced. can. In addition, when a problem occurs in the exposure apparatus, or when performing work such as initial setting, etc., the substrate P carried out to the port section 150G (beam unit 152) can be carried in again without the external transport device 300. It can be transferred to the hand 161G and loaded into the substrate holder 28G.

Further, according to the second embodiment, the plurality of fingers 162G of the substrate loading hand 161G are connected to each other by the connecting member 163G near the end on the -X side (substrate holder 28G side). Accordingly, the substrate loading hand 161G according to the second embodiment can place the substrate P2 on the substrate holder 28G without distortion compared to the substrate loading hand 161A.

Specifically, as shown in FIG. 25(a), in the substrate loading hand 161A according to the first embodiment, the fingers 162A are open on the -X side. Therefore, as shown in FIG. 25(a), the edge of the substrate P2 on the -X side just before it is placed on the substrate holder 28A has a region supported by the finger portions 162A and a region not supported, so that a very small amount of However, it is wavy, and it may be difficult to set the substrate P2 on the substrate holder 28A without distortion. On the other hand, as shown in FIGS. 16(a) and 16(b), in the substrate carrying-in hand 161G according to the second embodiment, the adjacent fingers 162G on the -X side are not open and are continuous. , the −X side edge of the substrate P2 can be supported by a surface. As a result, as shown in FIG. 25(b), the −X side edge of the substrate P2 immediately before being placed on the substrate holder 28G is less likely to be wavy. Therefore, the substrate loading hand 161G according to the second embodiment can place the substrate P2 on the substrate holder 28G without distortion as compared with the substrate loading hand 161A.

Further, according to the second embodiment, by moving the substrate transfer section 160G (substrate loading hand 161G) and the stage device 20G (substrate holder 28G) in opposite directions, the substrate loading hand 161G is moved between the substrate P2 and the substrate holder. 28G. As a result, the time required to carry the substrate P2 into the substrate holder 28G can be shortened.

Further, according to the second embodiment, in the finger portions 162G of the substrate loading hand 161G, the inner finger portions 162G2 other than the finger portions 162G1 at both ends are thinner on the port portion side than the finger portions 162G1 at both ends. (see, for example, FIG. 16(b)). As a result, the weight of the board loading hand 161G can be reduced.

Further, according to the second embodiment, since the arms 168 of the substrate loading hand 161G are attached to the finger portions 162G1 at both ends, the substrate loading hand 161G can support the central portion of the substrate P2, The carry-in hand 161G can be made smaller. Furthermore, since the arms 168 of the substrate loading hand 161G are attached to the finger portions 162G1 at both ends, the center of gravity of the entire substrate loading hand 161G is supported, so that the substrate loading hand 161G can be prevented from bending.

(First modification)
In the second embodiment, the Z position (pass line) for transferring the substrate between the external transport device 300 and the beam unit 152 of the port section 150G is set higher than the upper surface of the substrate holder 28G. , the height of the pass line can be freely set (there is no limit).

FIGS. 26(a) and 26(b) are diagrams for explaining the board exchange operation in the first modified example.

As shown in FIGS. 26(a) and 26(b), the external transfer device 300 places the substrate P2 on the beam unit 152 stopped at a position lower than the top surface TS of the substrate holder 28G.

After that, as shown in FIGS. 17A and 17B of the second embodiment, when the beam unit 152 rises to a position higher than the highest portion of the substrate loading hand 161G, the substrate loading hand 161G is moved up and down. The substrate P2 can be transferred to the substrate carry-in hand 161G even if there is no driving device that moves the substrate P2. As a result, for example, when a problem occurs in the exposure apparatus, or when performing work such as initial setting, etc., the substrate transported to the port section 150G (beam unit 152) can be transported again without the external transport device 300. The substrate can be transferred to the substrate loading hand 161G and loaded into the substrate holder 28G.

(Second modification)
A second modification is an example in which the configuration of the substrate transfer apparatus is changed.

In the substrate transfer apparatus 100I according to the second modified example, the substrate transfer section 160I includes a drive system that rotates the substrate loading hand 161I around the Y axis. That is, the substrate carrying-in hand 161I can incline the substrate holding surface around the Y-axis by the driving system.

Further, in the second modified example, as shown in FIG. 27A, the stroke of the substrate pick hand 167I provided in the substrate loading hand 161I is longer than that of the substrate pick hand 167G of the second embodiment. In the second modification, as shown in FIG. 27(a), the distance from the -X side end of the board loading hand 161I to the root of the finger portion 162I, that is, the width of the connecting member 163I in the X-axis direction is , is longer than the connecting member 163G of the second embodiment.

A substrate exchanging operation using the substrate transfer apparatus 100I according to the second modified example will be described with reference to FIGS. 27(a) to 30(b). The states of FIGS. 27(a) and 27(b) respectively correspond to the states of FIGS. 17(a) and 17(b) in the second embodiment.

As shown in FIGS. 27(a) and 27(b), while the stage device 20G is performing exposure processing, the external transport device 300 is moved in the −Z direction to mount a new substrate P2 on the beam unit 152. After that, it is moved in the +X direction and exits from the exposure apparatus 10I.

The substrate loading hand 161I is moved in the +X direction and enters under the beam unit 152 from the -X side (substrate holder 28G side). Then, the crotch portion of the finger portion 162I of the substrate loading hand 161I is stopped at a position not overlapping the -X side end portion of the beam unit 152 in plan view.

After that, as shown in FIGS. 28(a) and 28(b), the stage device 20G that has finished the exposure process moves to the substrate transfer position with the port section 150G.

The substrate loading hand 161I is rotationally driven around the Y axis so that the substrate holding surface of the substrate loading hand 161I is substantially parallel to the substrate P2 on the beam unit 152 . The beam unit 152 is lowered (moved in the -Z direction) while holding the substrate P2, and stops at a position where a part of the substrate P2 on the beam unit 152 contacts the substrate pick hand 167I of the substrate carry-in hand 161I. The substrate pick hand 167I sucks and grips the back surface of the substrate P2.

After that, as shown in FIGS. 29(a) and 29(b), in the stage device 20G, the substrate P1 on the substrate holder 28G is offset in the +X direction by the substrate unloading bearer device 183A.

The substrate pick hand 167I of the substrate loading hand 161I is moved in the -X direction while gripping the substrate P2 on the beam unit 152. FIG. As a result, the substrate P2 is moved onto the substrate loading hand 161I while being held by the substrate loading hand 161I and the beam unit 152 . At this time, the pressurized gas is jetted from above the beam unit 152 and above the substrate unloading hand 161I. Since the substrate pick hand 167I holds the substrate P2 by suction, there is no fear that the substrate P2 will drop from the beam unit 152 or the substrate unloading hand 161I. Since the substrate P2 is held by the substrate loading hand 161I and the beam unit 152, the substrate loading hand 161I moves in the +Z direction with respect to the beam unit 152, and the substrate P2 is placed on the substrate loading hand 161I from the beam unit 152. There is less load on the substrate P2 than if it were placed there. Therefore, the risk of damage to the substrate P2 during transfer of the substrate P2 between the substrate loading hand 161I and the beam unit 152 can be reduced.

After that, as shown in FIGS. 30(a) and 30(b), the beam unit 152 is driven downward to below the substrate loading hand 161I, and completely transfers the substrate P2 to the substrate loading hand 161I. When the substrate P2 is placed on the substrate loading hand 161I, the substrate loading hand 161I is rotationally driven around the Y-axis, and the substrate holding surface of the substrate loading hand 161I is inclined with respect to the holder substrate holding surface of the substrate holder 28G. 27(b)).

Since subsequent operations are the same as those of the second embodiment, description thereof is omitted.

According to the second modification, after the substrate loading hand 161I is rotationally driven around the Y-axis so that the substrate holding surface of the substrate loading hand 161I is substantially parallel to the substrate P2 on the beam unit 152, the beam unit 152 is moved. The substrate P2 is transferred to the substrate carry-in hand 161I. As a result, the substrate P2 can be reliably transferred to the substrate carry-in hand 161I without being bent.

Further, according to the second modification, the width of the connecting member 163I in the X-axis direction is large. Thereby, the length of the finger portion 162I of the substrate loading hand 161I can be shortened, and the rigidity of the substrate loading hand 161I as a whole can be increased.

(Third modification)
In the second modification, the substrate P2 is moved from the beam unit 152 to the substrate loading hand 161I by tilting the substrate loading hand 161I, but in the third modification, the beam unit 152 is tilted.

As shown in FIG. 31(a), in the substrate transfer apparatus 100J according to the third modified example, the port section 150J includes legs 154a and 154b whose upper ends are connected to the beam 153 of the beam unit 152. As shown in FIG. In addition, the port section 150J includes Z actuators 158a and 158b capable of independently extending and contracting the legs 154a and 154b in the Z-axis direction. The Z actuators 158a and 158b change the amount of expansion and contraction of the legs 154a and 154b, thereby changing the inclination of the upper surface of the beam unit 152. FIG. Note that FIG. 31(a) shows the beam unit 152 arranged between the finger portions 162I1 at both ends and the inner finger portion 162I2.

Next, transfer of the substrate P2 from the beam unit 152 to the substrate loading hand 161I will be described.

31(a) shows a state in which the substrate P2 is placed on the beam unit 152 by the external transfer device 300. FIG. At this time, the substrate loading hand 161I is moved from the −X side of the beam unit 152 in the +X direction, and the crotch portion of the finger portion 162G does not overlap the −X side end of the beam unit 152 in plan view. be stopped.

Next, as shown in FIG. 31(b), the Z actuators 158a and 158b are used to change the expansion/contraction amounts of the legs 154a and 154b so that the upper surface of the beam unit 152 and the substrate holding surface of the substrate loading hand 161I are substantially flush with each other. The beam unit 152 is tilted to form a

Next, the substrate P2 held by the beam unit 152 is gripped by the substrate pick hand 167I as the beam unit 152 descends, and transferred to the substrate carry-in hand 161I while the substrate position is shifted by the movement of the substrate pick hand 167I.

The substrate P2 may be moved from the beam unit 152 to the substrate loading hand 161I by tilting the beam unit 152 as in the third modification.

(Fourth modification)
A fourth modified example is an example in which the configuration of the finger portion of the board loading hand is changed.

As shown in FIGS. 32(a) and 33(a), a board loading hand 161K according to the fourth modification has a finger portion 162K having a length substantially equal to the board dimension in the X-axis direction. Further, as shown in FIG. 32(b) and the like, the substrate loading hand 161K is shaped like a rhombus with pointed ends when viewed from the side. is installed.

Transfer of the substrate from the beam unit 152 to the substrate loading hand 161K in the fourth modified example will be described with reference to FIGS. 32(a) to 33(b).

As shown in FIGS. 32(a) and 32(b), the substrate loading hand 161K is arranged at a position where the crotch portion of the finger portion 162K does not overlap the -X side end portion of the beam unit 152 in plan view.

Thereafter, when the external transport device 300 delivers the substrate P2 onto the beam unit 152, the beam unit 152 is moved in the -Z direction as shown in FIGS. 33(a) and 33(b). Since the length of the finger portion 162K of the substrate loading hand 161K is substantially the same as the length of the substrate P2, the substrate P2 is placed on the substrate loading hand 161K by moving the beam unit 152 in the -Z-axis direction. After that, the substrate P2 is slid to the slope side by the substrate pick hand 167K. As a result, a portion of the substrate P2 is inclined with respect to the holder substrate holding surface of the substrate holder 28G. Subsequent operations are substantially the same as those of the second embodiment, and detailed description thereof will be omitted.

According to the fourth modification, since the length (length in the X-axis direction) of the finger portion 162K of the substrate loading hand 161K is substantially the same as the length of the substrate, the substrate P2 placed on the beam unit 152 is When the substrate P2 is received by the substrate loading hand 161K, the substrate P2 can be scooped up simply by passing the substrate loading hand 161K through the beam unit 152 from the bottom to the top. Therefore, the operation is simple, and there is an effect that damage to the substrate P2 and generation of dust are unlikely to occur.

(Fifth modification)
The fifth modified example is an example in which the substrate is directly transferred from the external transport device 300 to the substrate carry-in hand 161K.

In the fifth modification, as shown in FIG. 34(a), the fork of the external transfer device 300 is arranged so that the finger portion 162K of the board loading hand 161K does not overlap the position in the Y-axis direction in plan view. . Also, the beam 153 of the beam unit 152 is arranged so as not to overlap the forks of the external transport device 300 in plan view. As a result, in the fifth modified example, the finger portion 162K of the substrate loading hand 161K and the beam 153 of the beam unit 152 are arranged at overlapping positions in plan view.

Transfer of the substrate from the external transport device 300 to the substrate loading hand 161K in the fifth modification will be described below with reference to FIGS. 34(a) to 35(b).

As shown in FIGS. 34( a ) and 34 ( b ), the substrate loading hand 161K is driven in the +X direction so as to be placed at the substrate transfer position with respect to the external transport device 300 . The external transport device 300, while holding the substrate P2, is moved in the -X direction until it reaches the substrate transfer position with the substrate loading hand 161K.

After that, as shown in FIGS. 35(a) and 35(b), the stage device 20G that has completed the exposure processing moves to the substrate transfer position with the beam unit 152. FIG. Further, in the stage device 20G, the substrate P1 on the substrate holder 28G is offset in the +X direction by the substrate unloading bearer device 183A.

When the external transport device 300 is moved in the -Z direction, the bottom surface of the substrate P2 contacts the substrate pick hand 167K. The substrate pick hand 167K sucks and grips the lower surface of the substrate P2.

The substrate pick hand 167K, which sucks and grips the lower surface of the substrate P2, is driven in the -X direction. As a result, the substrate P2 on the external transport device 300 is moved to the substrate carry-in hand 161K. The external transport device 300 is driven downward as it is, and when the substrate P2 is completely transferred onto the substrate loading hand 161K, it is driven in the +X direction and exits from the exposure apparatus 10L.

The beam unit 152 is moved in the -Z direction and the -X direction toward the substrate transfer position with the stage device 20G.

Since subsequent operations are substantially the same as those of the second embodiment, detailed description thereof will be omitted.

As described above, according to the fifth modification, when the substrate P2 is to be loaded, the substrate loading hand 161K can directly receive the substrate P2 from the external transport device 300 without going through the port portion 150G. As a result, two transfer operations, that is, the transfer of the substrate P2 from the external transport device 300 to the port section 150G and the transfer of the substrate P2 from the port section 150G to the substrate loading hand 161K, have been required so far. Only one transfer from the transfer device 300 to the substrate carrying-in hand 161K is sufficient, and the number of transfers of the substrate P2 is reduced, so that the time required to carry in the substrate P2 can be shortened and damage and dust generation of the substrate P2 can be prevented. can be done.

In addition, in the fifth modification, the substrate P1 is transferred from the beam unit 152 to the external transport device 300 in the same manner as in the second embodiment for collecting (carrying out) the substrate P1.

In the fifth modification, the beam 153 of the beam unit 152 and the finger 162K of the substrate loading hand 161K are arranged so that the beam unit 152 and the fingers of the robot hand of the external transport device 300 do not overlap in plan view. Although they are arranged so as to overlap in a plan view, they are not limited to this. The beam 153 of the beam unit 152 and the finger portion 162K of the substrate loading hand 161K may also be arranged so as not to overlap in plan view. In this case, the beam unit 152 may be able to shift by one finger 162K in the Y-axis direction. As a result, the substrate carried out from the substrate holder 28G to the port portion 150G can be scooped up again by the substrate carry-in hand.

In order to prevent the beam 153 from overlapping the fingers 162K in plan view when transferring the substrate, the external transport device 300 is shifted in the Y-axis direction instead of the beam unit 152 in the Y-axis direction. Alternatively, the substrate loading hand 161K may be shifted in the Y-axis direction.

(Sixth modification)
A sixth modification is obtained by changing the configuration of the board loading hand.

FIG. 36 is a perspective view showing a board loading hand 161L according to the sixth modification. As shown in FIG. 36, the board loading hand 161L has a plate portion 263 having a triangular XZ cross section, and an arm portion 265 that supports the plate portion 263 . The upper surface of the plate portion 263 is inclined with respect to the XY plane.

As shown in the sixth modified example, the board loading hand may not have fingers. That is, the substrate loading hand does not have to have a fork shape.

In addition, as shown in FIG. 37(a), the upper surface of the plate portion 263 of the substrate loading hand 161L may be curved. By curving the upper surface (holder substrate holding surface) of the plate portion 263 in this manner, the section modulus of the substrate can be increased. That is, it is possible to obtain the same effect as when the thickness of the substrate is several to several hundred times greater than the actual thickness with respect to the deflection of the substrate.

By doing so, even if the substrate P is placed on the substrate carrying-in hand 161L with the −X end protruding as shown in FIG. ) can be suppressed. In addition, since the substrate P is prevented from sagging (sagging), when the substrate P is brought into contact with the substrate holder, the substrate P can be brought into contact with the center portion of the -X side in the Y-axis direction. , the −X end of the substrate P can be made less likely to wrinkle.

Further, as shown in FIG. 38, a cover 199 may be provided for the substrate transfer sections 160A to 160L. By providing the cover 199, it is possible to prevent dust from adhering to the substrate P and to keep the temperature of the substrate P constant.

In addition, in the second embodiment and its modification, the stage device 20A according to the first embodiment may be used instead of the stage device 20G. Also, the stage device 20G may be applied to the first embodiment and its modification.

Also, in the first and second embodiments and their modifications, as shown in FIG. , a part may be chamfered (30a) so as not to interfere with the board loading hand. Note that FIG. 39 shows a case where the substrate loading hand is the substrate loading hand 161G according to the second embodiment. Thereby, the height of the entire exposure apparatus can be reduced.

Further, in the first and second embodiments and their modified examples, the stage devices 20A and 20G as the substrate position measuring device described above are arranged to measure the substrate P as shown in FIGS. 40A and 40B. It is equipped with CCD cameras 31x and 31y (image processing edge detection) for edge detection. The CCD camera 31x is arranged so as to observe two sides on the -X side of the substrate P before it is placed on the substrate holders 28A and 28G. The CCD camera 31y is arranged so that one point on the −Y side (or +Y side) of the substrate P can be observed from below. Thereby, the X position, Y position, and θz position of the substrate P with respect to the stage devices 20A and 20G can be known. These pieces of information are used for stage control as correction of the position of the substrate P2 before mounting and positional information of the substrate P2 after mounting. It should be noted that, instead of the CCD cameras 31x and 31y for detecting the edge of the substrate P, for example, a known edge sensor provided with a light source and a light receiving section may be used. The light source is arranged at the same position as the CCD cameras 31x and 31y, and the light receiving section is arranged so as to face the light source with the substrate P interposed therebetween. A cross section perpendicular to the optical axis of the measurement light emitted from the light source is linear, and the light receiving unit detects the edge of the substrate P by receiving the measurement light. In this manner, the X position, Y position, and θz position of the substrate P with respect to the stage devices 20A and 20G are detected based on the detection results obtained by measuring the X-axis direction end portion and the Y-axis direction end portion of the substrate P. You may make it

Further, in the first and second embodiments and modifications thereof, the stage device 20M shown in FIGS. 41(a) to 41(c) may be used.

In the stage device 20M, as shown in FIG. 41(a), two substrate carry-in bearer devices 182M are provided at the −X side end of the substrate holder 28M. As shown in FIG. 41(b), the substrate carry-in bearer device 182M is partially housed in the notch 28a formed in the −X side end of the substrate holder 28M, and the upper surface of the holding pad 184a is held. The height is set to be substantially the same as the top surface of the substrate holder 28M. Therefore, even after the substrate P2 is mounted, the holding pad 184a does not need to be moved in the -X direction and retracted from the substrate holder 28M.

In addition, as shown in FIG. 41(c), the substrate carry-in bearer device 182M can be tilted so that the back surface of the substrate P2 which is carried in obliquely can be reliably sucked and fixed. Further, the substrate carry-in bearer device 182M is movable in the horizontal direction (X-axis direction or X-axis and Y-axis directions) so as to adjust the relative position (alignment) of the substrate P2 with respect to the substrate holder 28M.

According to the stage device 20M, since the holding pad 184a can be tilted, the back surface of the substrate P2 can be reliably sucked and fixed.

Further, in the first and second embodiments and modifications thereof, the stage device 20N shown in FIGS. 42(a) and 42(b) may be used.

The stage device 20N does not have the independently moving substrate loading bearer device described in the first and second embodiments. In the stage device 20N, the loaded substrate is placed at one or a plurality of locations near the −X side end surface of the substrate holder so that a part of the upper surface of the substrate holder 28N serves as a holding pad 184a for sucking and holding the leading end of the loaded substrate. A suction area (bearer area) 187 is provided for suction-holding the tip of the carrier.

Since the stage device 20N does not have a substrate carry-in bearer device that moves independently, the relative position adjustment (alignment) of the carried-in substrate P with respect to the substrate holder 28N cannot be performed by the substrate carry-in bearer device. , the position of the substrate P may be adjusted on the substrate loading hand using a pair of substrate unloading hands. After mounting the substrate P on the substrate holder 28N, if it is desired to adjust the relative position (alignment) of the substrate P with respect to the substrate holder 28N, the substrate unloading bearer device 183A may be used.

If the stage device does not have a substrate loading bearer device that moves independently, for example, the substrate loading hand 161A is retracted from between the substrate P and the substrate holder 28N as shown in FIGS. When the substrate P2 is placed on the substrate holder 28N, the substrate holder 28N draws in air to attract the substrate P2 to the holder substrate holding surface, thereby stably loading the substrate P2. can be done.

In addition, in the above-described first and second embodiments and their modifications, the support pads on the finger portions of the substrate loading hand may be omitted.

Further, in each of the above-described embodiments, the projection optical system 16 is a unity magnification system, but is not limited to this, and a reduction system or an enlargement system may be used.

The application of the exposure apparatus is not limited to the exposure apparatus for liquid crystals that transfers the liquid crystal display element pattern to a rectangular glass plate. exposure equipment, thin-film magnetic heads, micromachines, and exposure equipment for manufacturing DNA chips. In addition to microdevices such as semiconductor elements, glass substrates, silicon wafers, etc. are also used for manufacturing masks or reticles used in optical exposure apparatuses, EUV exposure apparatuses, X-ray exposure apparatuses, electron beam exposure apparatuses, and the like. It can also be applied to an exposure apparatus that transfers a circuit pattern to a substrate.

Also, the substrate to be exposed is not limited to a glass plate, and may be other objects such as a wafer, a ceramic substrate, a film member, or mask blanks. Moreover, when the exposure target is a substrate for a flat panel display, the thickness of the substrate is not particularly limited, and includes, for example, a film-like (flexible sheet-like member). Note that the exposure apparatus of the present embodiment is particularly effective when the exposure target is a substrate having a side length or a diagonal length of 500 mm or more. Moreover, when the substrate to be exposed is in the form of a flexible sheet, the sheet may be formed into a roll.

《Device manufacturing method》
Next, a method of manufacturing a microdevice using the exposure apparatuses 10A to 10L according to the above embodiments in the lithography process will be described. In the exposure apparatuses 10A to 10L of the above embodiments, a liquid crystal display element as a microdevice can be obtained by forming a predetermined pattern (circuit pattern, electrode pattern, etc.) on the substrate.
<Pattern formation process>
First, a so-called photolithography process is performed in which a pattern image is formed on a photosensitive substrate (such as a glass substrate coated with a resist) using the exposure apparatus according to each of the embodiments described above. Through this photolithography process, a predetermined pattern including a large number of electrodes and the like is formed on the photosensitive substrate. After that, the exposed substrate undergoes each process such as a development process, an etching process, a resist stripping process, etc., thereby forming a predetermined pattern on the substrate.
<Color filter forming process>
Next, a large number of sets of three dots corresponding to R (Red), G (Green), and B (Blue) are arranged in a matrix, or a filter set of three stripes of R, G, and B is A plurality of color filters arranged in the horizontal scanning line direction are formed.
<Cell assembly process>
Next, a liquid crystal panel (liquid crystal cell) is assembled using the substrate having the predetermined pattern obtained in the pattern forming process and the color filters obtained in the color filter forming process. For example, a liquid crystal panel (liquid crystal cell) is manufactured by injecting liquid crystal between a substrate having a predetermined pattern obtained in the pattern forming process and the color filter obtained in the color filter forming process.
<Module assembly process>
After that, each component such as an electric circuit for performing display operation of the assembled liquid crystal panel (liquid crystal cell) and a backlight is attached to complete a liquid crystal display element.

In this case, in the pattern forming process, the substrate is exposed with high throughput and high accuracy using the exposure apparatus according to each of the above embodiments, so that the productivity of the liquid crystal display element can be improved as a result.

The above-described embodiments are examples of preferred implementations of the present invention. However, the present invention is not limited to this, and various modifications can be made without departing from the scope of the present invention.

10A to 10L Exposure device 20A, 20G, 20M, 20N Stage device 28A, 28G, 28M, 28N Substrate holder 100A to 100L Substrate transfer device 160A to 160L Substrate transfer section 161A to 161L Substrate loading hand 164 X-axis drive device 182A, 182G, 182M Substrate carry-in bearer device 184a Holding pad P, P1, P2, P3 Substrate

Claims (38)

In a substrate transfer device that transfers a substrate to a holding surface of a holding device,
It is provided above the holding surface and holds a portion of the other side of the substrate in a state where the distance between the one side of the substrate and the holding surface is shorter than the distance between the other side of the substrate and the holding surface. a first holding portion for
a second holding portion holding the other portion of the substrate held by the first holding portion;
a drive unit that relatively moves the holding device, the second holding portion, and the first holding portion in a direction along the holding surface so that the first holding portion is retracted from above the holding device;
A substrate transport device comprising: 2. The substrate transfer apparatus according to claim 1, wherein said holding device holds said substrate in order from said other portion of said substrate to said one portion. 3. The substrate transfer apparatus according to claim 1, wherein said driving section moves said first holding section from above said holding device to a position not vertically overlapping said holding device. The first holding part has a substrate holding surface for holding the substrate,
4. The substrate transfer apparatus according to any one of claims 1 to 3, wherein said substrate holding surface is provided so as to be inclined with respect to said holding surface. The substrate holding surface has a first surface that holds the other portion of the substrate and is inclined with respect to the holding surface, and a surface that holds the portion of the substrate and is parallel to the holding surface. 5. The substrate transport apparatus of claim 4, comprising a second surface. 6. The substrate transfer apparatus according to claim 5, wherein said first holding part has a driving part that drives said first surface to be inclined with respect to said second surface. The substrate transfer apparatus according to any one of claims 1 to 6, wherein the holding device holds an area of the substrate that is released from the holding by the first holding portion by relative movement by the driving portion. . The substrate transfer apparatus according to any one of claims 1 to 7, wherein the second holding section transfers the other portion of the substrate to the holding apparatus. The drive section moves the first holding section from the holding device and the second holding section toward the other end of the holding device from one end side of the holding device where the second holding section conveys the other portion of the substrate. 9. The substrate transfer apparatus according to claim 8, wherein the substrate transfer apparatus is relatively moved with respect to the 2 holders. 10. The substrate transfer apparatus according to claim 9, wherein said holding device holds said portion of said substrate on the other end side of said holding device. The substrate transfer apparatus according to any one of claims 1 to 10, wherein the second holding section is provided in the holding device. 12. The substrate transfer apparatus according to claim 11, wherein said second holding portion is provided on an upper surface of said holding device. 13. The substrate transfer apparatus according to claim 1, wherein said second holding portion adjusts the position of said substrate with respect to said holding device while holding said other portion of said substrate. An unloading device for unloading a substrate different from the substrate from the holding device,
14. The unloading device according to any one of claims 1 to 13, wherein the unloading device unloads the different substrate during relative movement between the holding device and the second holding unit and the first holding unit by the driving unit. 11. The substrate transfer device according to claim 1. 15. The substrate transfer apparatus according to claim 14, wherein said unloading device moves said another substrate at a position between said first holding unit and said holding device in the vertical direction. The unloading device is provided in the first holding unit,
16. The substrate conveying apparatus according to claim 14, wherein said driving section relatively moves said first holding section with respect to said second holding section and said holding device, and moves said unloading device. The holding device has an air supply hole for supplying gas for floating the another substrate,
17. The substrate transfer apparatus according to any one of claims 14 to 16, wherein said unloading device moves said another substrate floated on said holding device along said holding surface of said holding device. A substrate transfer apparatus according to any one of claims 1 to 17;
an optical system that irradiates the substrate transported to the holding device with an energy beam to expose the substrate;
an exposure apparatus. 19. The exposure apparatus according to claim 18, wherein said substrate has at least one side length or diagonal length of 500 mm or more, and is for a flat panel display. exposing a substrate using the exposure apparatus of claim 19;
developing the exposed substrate;
A flat panel display manufacturing method comprising: A device manufacturing method comprising:
exposing a substrate using the exposure apparatus according to claim 18 or 19;
developing the exposed substrate;
A device manufacturing method comprising: In a substrate transport method for transporting a substrate to a holding surface of a holding device,
holding the substrate by a first holding portion and a second holding portion above the holding surface;
The first holding part holds a portion of the other side of the substrate in a state where the distance between the one side of the substrate and the holding surface is shorter than the distance between the other side of the substrate and the holding surface. The second holding portion and the first holding portion for holding the other portion of the substrate held by the holding device and the first holding portion are arranged along the holding surface so as to be retracted from above the device. relatively moving in a direction;
A substrate transfer method comprising: 23. The substrate transfer method according to claim 22, wherein said substrate is held by said holding device in order from said other portion of said substrate to said portion of said substrate. 24. The substrate transfer method according to claim 22 or 23, wherein said relative movement moves said first holding part from above said holding device to a position not vertically overlapping said holding device. The holding includes a first surface that holds the other portion of the substrate and is inclined with respect to the holding surface, and a surface that holds the portion of the substrate and is parallel to the holding surface. 25. The substrate transfer method according to any one of claims 22 to 24, wherein the substrate is held by the first holding portion including the second surface. 26. The substrate transfer method of claim 25, comprising driving the first surface to be inclined with respect to the second surface. 27. The substrate transfer method according to any one of claims 22 to 26, wherein the relative movement causes the holding device to hold the region of the substrate that is released from the holding of the first holding part. 28. The substrate transfer method according to any one of claims 22 to 27, comprising transferring the other part of the substrate to the holding device by the second holding part. The relative movement is performed by moving the first holding part and the holding device from one end side of the holding device where the second holding part conveys the other part of the substrate toward the other end side of the holding device. 29. The substrate transfer method according to claim 28, wherein the substrate is moved relative to the second holding part. 30. The substrate transfer method according to any one of claims 22 to 29, including adjusting the position of the substrate with respect to the holding device while the second holding portion holds the other portion of the substrate. Method. unloading another substrate different from the substrate from the holding device;
23. From claim 22, wherein in the unloading, the another substrate is unloaded during relative movement between the holding device and the second holding unit, the first holding unit, the holding device and the second holding unit 31. A method of transporting a substrate according to any one of claims 30. 32. The substrate transfer method according to claim 31, wherein in the carrying out, the another substrate is moved to a position between the first holding unit and the holding device in the vertical direction. 33. The substrate according to claim 31, wherein in the relative movement, the first holding part is moved relative to the second holding part and the holding device, and the another substrate is unloaded. Conveyance method. 34. The substrate transfer method according to any one of claims 31 to 33, wherein in the carrying out, the another substrate floated on the holding device is moved along the holding surface of the holding device. . transferring a substrate using the substrate transfer method according to any one of claims 22 to 34;
irradiating the substrate transported to the holding device with an energy beam to expose the substrate;
exposure method, including 36. The exposure method according to claim 35, wherein said substrate has at least one side length or diagonal length of 500 mm or more and is for a flat panel display. exposing a substrate using the exposure method of claim 36;
developing the exposed substrate;
A flat panel display manufacturing method comprising: A device manufacturing method comprising:
exposing a substrate using the exposure method according to claim 35 or 36;
developing the exposed substrate;
A device manufacturing method comprising:

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