JP4853836B2 - Precision fine positioning apparatus and fine positioning stage equipped with the same - Google Patents

Description

  The present invention relates to a semiconductor and liquid crystal manufacturing apparatus, and more particularly to an apparatus for accurately positioning a mask and a substrate using an exposure apparatus and an inspection apparatus.

The devices described in Patent Document 1 and Patent Document 2 will be described as conventional precision fine movement positioning devices.
10 and 11 are diagrams for explaining the apparatus of Patent Document 1. FIG. The stage base 21 has a concave shape so that the movable stage 22 can be installed at the center thereof. The movable stage 22 is supported on the inner wall of the concave portion of the stage base 21 by a support member 30 in at least three axes of the X, Y, and Z axes. Is supported so as to be movable. One end of the actuator 4 is fixed to the stage base 21, and the other end of the actuator 4 is in contact with the movable stage 22. At least one such actuator 4 is provided in parallel to the X-axis direction, the Y-axis direction, and the Z-axis direction of the movable stage 22. In the precision positioning device configured as described above, a voltage is applied to the actuator 4. When it is expanded and contracted, the movable stage 22 moves while deforming the support member 30 with respect to the stage base 21.
FIG. 12 is a diagram for explaining the apparatus of Patent Document 2. In FIG. A lower plate 32 and an upper plate 33 are attached above and below the piezoelectric element 31, and a bellows 10 that surrounds and seals the piezoelectric element 31 is between the lower plate 32 and the upper plate 33. When a voltage is applied to the electrode 34 in this device, the piezoelectric element 31 expands and contracts. At this time, the piezoelectric element 31 generates thrust in a state where the piezoelectric element 31 is blocked from the outside atmosphere by the lower plate 32, the upper plate 33 and the bellows 10. It is.
JP 62-266490 A (FIGS. 1 and 2) JP-A-61-284350 (FIG. 1)

The precision positioning apparatus described in Patent Document 1 supports only the lateral side surface of the movable stage 22 with a support member 30, and only the actuator 4 is disposed below the movable stage 22. Since the entire weight is supported by the actuator 4, there is a problem that the actuator 4 needs a thrust for supporting the weight of the movable stage 22 in addition to the thrust for driving the movable stage 22, and the actuator 4 becomes large. Further, although Patent Document 1 does not describe a sensor for detecting the position of the movable stage 22, the actual precision fine positioning device requires the sensor. There is a problem that a space for arranging the sensor is required, and the apparatus becomes large.
On the other hand, Patent Document 2 is originally intended to block the piezoelectric element 31 from the outside air, but if a combination of the lower plate 32, the upper plate 33 and the bellows 10 is regarded as a support member, Since the piezoelectric element 31 as an actuator is disposed on the actuator, there is an effect that the precision positioning device can be reduced in size. However, in the configuration of Patent Document 2, the bellows 10 only expands and contracts only in the thrust generation direction of the piezoelectric element 31, and cannot be deformed in a direction orthogonal to the thrust generation direction and a direction rotating around an axis orthogonal to the thrust generation direction. There is a problem that the degree of freedom is limited as a precision fine movement positioning device.
SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a precision fine movement positioning device that is small and has many degrees of freedom.

In order to solve the above problem, the present invention is configured as follows.
The invention according to claim 1 is opposed to the fixed base, the pair of stators erected on the fixed base, and the pair of stators through a certain gap, respectively. An electromagnetic actuator, a bellows, an upper end and a lower end flange for sealing the upper end and the lower end of the bellows, respectively, and a working fluid having a predetermined pressure filled in the bellows. The fine support positioning device comprises: an elastic support mechanism in which the lower end flange is attached to the fixed base; and a movable base supported by the mover and the upper end flange. A displacement sensor provided in the lower end flange so as to be accommodated in the bellows, and provided in the upper end flange, penetrating into the bellows. A screw hole, a shaft inserted into the screw hole, a displacement sensor detector provided on the shaft so that the displacement sensor can detect, and a sealing means for closing a gap between the screw hole and the shaft; And the movable base is provided with a through hole at a position corresponding to the shaft .
The invention according to claim 2 is characterized in that a lock nut is provided on the shaft, and the shaft is fixed to the upper end flange by the lock nut. To do.
According to a third aspect of the present invention, in the electromagnetic actuator, the positional relationship between the mover and the stator is reversed. It is.
According to a fourth aspect of the present invention, there is provided at least three precision fine positioning devices according to claim 1, 2 or 3, and a stage base that supports the fixed base of each of the at least three precision fine positioning devices; A movable stage supported by the movable base of each of the at least three precision fine positioning devices, and the movable stage has a position corresponding to the shaft of each of the at least three precision fine positioning devices. The fine movement positioning stage is characterized in that a through-hole is further provided at a position corresponding to the through-hole provided in the .
According to a fifth aspect of the present invention, the movable base of each of the at least three precision fine positioning devices is a plate-like base having a step in the vertical direction, and the elastic support mechanism is provided on the lower surface of the lower step of the step. 5. The fine movement positioning stage according to claim 4, wherein the upper end flange of the step is fixed, the movable element is fixed to the lower surface of the upper stage of the step, and the movable stage is supported on the upper surface of the lower stage of the step. It is what.
The invention described in claim 6 is characterized in that a spherical support portion is provided between the movable base of each of the at least three precision fine positioning devices and the movable stage. 5. The fine movement positioning stage described in 5 is used.
According to a seventh aspect of the present invention, there is provided a rod-like member in which a diameter of a part of a metal round bar is thinned between the movable base of each of the at least three precision fine positioning devices and the movable stage. 6. The fine movement positioning stage according to claim 4, further comprising a formed bending support portion .

According to the present invention, since the displacement sensor is provided inside the elastic support mechanism, and the elastic support mechanism and the actuator are provided on the common fixed base, the precision fine positioning device can be made small. Further, a multi-degree-of-freedom precision fine positioning device can be realized by an electromagnetic actuator having a gap between the stator and the mover and an elastic support mechanism that elastically supports the mover in a three-dimensional manner.
According to the present invention, the bellows can be adjusted to an arbitrary position by the pressure of the working fluid, and the movable base is reliably supported by the elastic support mechanism, so that the electromagnetic actuator can be made small.
According to the present invention, since the working fluid supply port is provided in the flange at the lower end on the fixed side, the supply port does not move, so that the risk of fluid leaking from the joint can be reduced.
According to the present invention, the elastic support mechanism can be adjusted by a general fluid.
According to the present invention, the sensor unit can be configured by a general displacement sensor.
According to the present invention, the sensor unit can be adjusted despite the presence of the elastic support mechanism, and the airtightness of the elastic support mechanism can be maintained.
According to the present invention, the shaft can be fixed after the sensor unit is adjusted.
According to the present invention, the sensor unit can be adjusted from above the movable base.
According to the present invention, since the weight of the movable stage is supported by the elastic support mechanism, the actuator only needs to generate a thrust force that can generate acceleration in the movable stage, and since the displacement sensor is built in the bellows, A compact fine positioning stage can be configured.
According to the present invention, if an external force is applied to the stage in a direction orthogonal to the thrust generation direction of the actuator, the bellows of the elastic support mechanism is bent, so that a fine movement positioning stage having six degrees of freedom can be configured.
According to the present invention, the movable base of the Z-axis actuator has a step, and the lower stage enters the movable stage to support it. Therefore, a compact fine movement positioning stage can be configured.
According to the present invention, since the electromagnetic actuator that drives the movable stage in the X-axis and Y-axis directions also has a gap between the movable element and the stator, the movable stage is orthogonal to the thrust generation direction of the electromagnetic actuator. The movable stage can be controlled in position and posture by an electromagnetic actuator while having 6 degrees of freedom.
According to the present invention, a compact fine movement positioning stage can be configured.
According to the present invention, the bellows can be adjusted to an arbitrary position by the pressure of the working fluid, and the movable stage is securely supported by the elastic support mechanism, so that the electromagnetic actuator can be made small, and a compact fine movement positioning stage can be configured. .
According to the present invention, the sensor unit can be configured by a general displacement sensor.
According to the present invention, the sensor unit can be adjusted despite the presence of the elastic support mechanism, and the airtightness of the elastic support mechanism can be maintained.
According to the present invention, the sensor unit can be adjusted from above the movable stage.
According to the present invention, the posture of the movable stage with six degrees of freedom can be calculated, and a compact fine movement positioning stage can be configured.
According to the present invention, the sensor unit can be configured by a general displacement sensor.
According to the present invention, even when the bellows of the elastic support mechanism is bent and the movable base is inclined, the movable stage can be kept horizontal by the action of the spherical support portion or the deflection support portion.
According to the present invention, a compact exposure apparatus or inspection apparatus for semiconductor manufacturing or liquid crystal manufacturing can be provided.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 and 2 are a front view and a side view, respectively, of the fine fine positioning device of the present invention. In the precision fine positioning apparatus, the stator 5 and the elastic support mechanism 3 of the actuator 4 are generally mounted on the fixed base 1, and the movable base 2 and the actuator 4 are elastically supported so as to be held between the fixed base 1. It is provided in the upper part with the mechanism 3.
The movable base 2 is a plate-like base having a level difference in the vertical direction, and the lower surface of the lower stage is fastened and supported by an upper fixed flange 9 of an elastic support mechanism 3 described later. One end of the movable element 6 of the actuator 4 is fixed to the upper lower surface of the movable base 2, and the movable element 6 hangs down from the lower surface of the movable base 2. The stator 5 of the actuator 4 includes two plate-like yokes 5a each having a plurality of magnets 5b attached to one surface, and these are opposed to each other on the surface side to which the magnets 5b are attached. Yes. On the other hand, the mover 6 has a structure in which the coil 6b is attached to both surfaces of the plate-like coil base 6a, and the coil 6b is disposed so as to face the magnet 5b of the stator 5 through the gap m7.

  FIG. 3 is an enlarged cross-sectional view of the elastic support mechanism 3 described above. The elastic support mechanism 3 has a lower fixing flange 8 and an upper fixing flange 9 attached to the lower side and the upper side of the bellows 10, respectively. There is a bellows 10 between the lower fixing flange 8 and the upper fixing flange 9, and the bellows 10 is fixed to the lower fixing flange 8 and the upper fixing flange 9 by welding all around so that the internal working fluid does not leak to the outside. A displacement sensor 11 is fixed on the lower fixing flange 8 inside the bellows 10. On the other hand, a hole is provided in the center of the upper fixing flange 9, and an upper portion of the hole is threaded, and an inner peripheral surface of the lower portion of the hole is subjected to O-ring groove processing. A shaft 13 is inserted into this hole, and an upper portion of the shaft 13 is processed with a position adjusting screw 13 a and engaged with a screw portion of the hole of the upper fixing flange 9. A lock nut 14 is inserted into the upper end of the shaft 13, thereby fixing the shaft 13 to the upper fixing flange 9. The lower part of the position adjusting screw 13a of the shaft 13 has a cylindrical shape with a uniform cross section, and is fitted into the hole of the upper fixing flange 9 to form a guide part 13b, and the O-ring groove in the lower part of the hole of the upper fixing flange 9 It is inserted in the O-ring 15 inserted in. A displacement sensor detection body 12 is attached to the lower end of the shaft 13, and the displacement sensor detection body 12 faces the displacement sensor 11 with a gap s17 interposed therebetween. The displacement sensor 11 is of a type that detects the distance to the detection body via a gap, such as a capacitance type or an eddy current type. A joint 16 is attached to the side surface of the lower fixing flange 8, and a hole is formed so that the joint 16 communicates with the inside of the bellows 10. A working fluid can be introduced into the bellows 10 by connecting a pipe (not shown) to the joint 16. Here, as the working fluid, air, nitrogen or inert gas is suitable.

In the precision fine positioning apparatus as described above, when the working fluid is introduced into the bellows 10 of the elastic support mechanism 3, the bellows 10 extends to push the movable base 2 upward. Here, when the pressure of the working fluid is adjusted with a pressure regulator (not shown), the position of the movable base 2 can be adjusted. In this way, the movable base 2 is supported by its weight by the elastic support mechanism 3.
If the distance between the displacement sensor 11 and the displacement sensor detector 12 is not appropriate, for example, when the movable base 2 is adjusted to an arbitrary position by the working fluid, the position of the displacement sensor detector 12 is not suitable. Need to be adjusted. In this case, the shaft 13 is rotated and the vertical position of the displacement sensor detection body 12 is adjusted by the position adjusting screw 13a. The movable base 2 has a through hole at a position corresponding to the position of the shaft 13 so that the shaft 13 can be accessed from the through hole, and the shaft 13 can be rotated here. Yes. At this time, the displacement sensor 11 and the displacement sensor detector 12 can be kept parallel by the action of the guide portion 13b. Further, since the O-ring 15 is engaged with the shaft 13, the inside of the bellows 10 can be kept airtight and the working fluid is prevented from flowing out.
Next, when the coil 6b of the actuator 4 is energized, a force for moving the mover 6 in the vertical direction is generated. The elastic support mechanism 3 supports the movable base 2 and can be displaced in the vertical direction by the compressibility of the working fluid and the elasticity of the bellows 10, so that the movable base 2 can be moved up and down by the thrust of the actuator 4. become. At this time, since the weight of the movable base 2 is supported by the elastic support mechanism 3, the actuator 4 only needs to generate a thrust that the movable base 2 can generate acceleration. Therefore, the actuator 4 can be made smaller than the conventional case in which the elastic support mechanism 3 is not provided and the weight of the movable base 2 is supported by the thrust of the actuator 4. Further, the position and speed of the movable base 2 can be controlled by feeding back information from the displacement sensor 11 to a controller of a precision fine movement positioning device (not shown).

6 and 7 show examples in which a fine movement positioning stage is configured by combining a plurality of precision fine movement positioning apparatuses of the present invention. 6 is a top view thereof, and FIG. 7 is a front view thereof. This stage is used for finely positioning a reticle or mask of an exposure apparatus or inspection apparatus in a semiconductor or liquid crystal manufacturing apparatus.
In the figure, the fine movement positioning stage has a total of six degrees of freedom, that is, the degree of freedom of translation in each direction of the X axis 27, the Y axis 28, and the Z axis 29 and the degree of freedom of rotation around the three axes. is there. On the plate-like stage base 21, the three precision fine positioning devices described in the first embodiment are arranged so that the thrust generation direction coincides with the Z-axis 29 direction. A plate-like movable stage 22 is mounted on each movable base of the three precision fine positioning devices. As shown in FIG. 6, the three fine fine positioning devices are arranged in the vicinity of a rectangular movable stage 22 as viewed from above, and one fine fine positioning device is arranged at the approximate center of one side, and 2 on the opposite side. A precision micro-positioning device for the table is arranged. Hereinafter, for convenience of explanation, the fine fine positioning device arranged on one side is referred to as the first fine fine positioning device 40, and the two fine fine positioning devices opposed thereto are respectively the second and third fine fine positioning devices. Let them be devices 41 and 42.

Here, a contact portion between the precision fine movement positioning device and the movable stage 22 will be described. Since the contact portions of the three precision fine movement positioning devices with the movable stage have the same configuration, a description will be given of one precision fine movement positioning device.
FIG. 4 is a side view showing a contact portion between the precision fine movement positioning device and the movable stage. The contact portion shown in FIG. 4 is obtained by fixing the spherical support portion 18 on the movable base 2 of the precision fine positioning device and attaching the pedestal 20 to the upper side of the spherical support portion 18. The lower surface of the movable stage 22 is fixed to the upper surface of the pedestal 20. In the spherical support portion 18, the tip of a bar protruding upward is processed into a spherical shape. On the other hand, the lower surface of the pedestal 20 that comes into contact therewith is also recessed into a spherical shape so as to wrap the tip of the spherical support portion 18.
When the contact portion has such a configuration, the pedestal 20 can move freely with respect to the movable base 2 by the action of the spherical support portion 18.

As described above, in the fine movement positioning stage, the movable stage 22 is fixed on each of the bases 20 of the spherical surface support portions 18 of the three precision fine movement positioning devices via the contact portions shown in FIG.
Further, on the side surface of the movable stage 22, one X-axis actuator 23 capable of driving the movable stage 22 in the X-axis 27 direction and two Y-axis actuators 24 capable of driving in the Y-axis 28 direction are provided. It is attached. The X-axis actuator 23 is a side to which the second and third precision fine positioning devices described above are attached, and is disposed between these two units. Two Y-axis actuators 24 are arranged on the side where the X-axis actuator 23 and the precision fine positioning device are not arranged. With this arrangement, the above-described six-axis drive can be realized, and the entire configuration of the fine movement positioning stage can be reduced.
Here, the configuration of the X-axis actuator 23 and the Y-axis actuator 24 includes an electromagnetic actuator similar to the actuator 4 described in the first embodiment, and has a gap m between the stator and the mover. Is. However, the X-axis and Y-axis actuators do not need a portion that elastically supports the movable stage 22 as in the elastic support mechanism 3. This is because the elastic support mechanisms 3 of the three precision fine positioning devices functioning as Z-axis actuators support the movable stage 22 in the direction of gravity and elastically in each direction of XYZ.
In addition, as for the actuator 4 of the precision fine movement positioning device which supports the movable stage 22 from the X and Y axis actuators and the Z axis direction, the positional relationship between the mover and the stator may be reversed.
Further, two X-axis displacement sensors 25 that measure displacement in the X-axis 27 direction and one Y-axis displacement sensor 26 that measures displacement in the Y-axis 28 direction are attached to the side surface of the movable stage 22. . The X-axis displacement sensor 25 is disposed so as to narrow the X-axis actuator 23. The Y-axis displacement sensor 26 is disposed near the center of the side so as to be sandwiched between the two Y-axis actuators 24. Here, as the types of the X-axis displacement sensor 25 and the Y-axis displacement sensor 26, a capacitance type, an eddy current type, a laser interferometer, or the like can be applied.
Further, as shown in FIG. 7, a hole corresponding to the hole of the movable base 2 for adjusting the shaft 13 described above is also provided in the movable stage 22.

The fine movement positioning stage configured as described above is provided by three elastic support mechanisms 3 by introducing a working fluid into the bellows 10 of the elastic support mechanism 3 and adjusting the pressure thereof, as described in the first embodiment. The movable stage 22 is supported at an arbitrary position and posture. In this state, when the positions of the displacement sensor 11 and the displacement sensor detector 12 inside the elastic support mechanism 3 are not appropriate, the shaft 13 is adjusted by rotating it through the hole.
Next, when the three actuators 4 built in the three precision fine positioning devices are driven by the same displacement amount in the same direction, the movable stage 22 can be moved and positioned in the translational direction of the Z axis 29.
For example, when the movable base of the first precision fine positioning device 40 is driven downward and the movable bases of the second and third precision fine positioning devices are driven upward, the movable stage 22 is moved around the Y axis 28. Can be rotated. FIG. 8 is a view showing a state where the movable stage 22 is rotated around the Y axis 28. In this way, the bellows 10 not only expands and contracts in the axial direction, that is, the Z-axis 29 direction, but can also be bent around an axis orthogonal to the bellows axis, so that the amount of movement of the three fine positioning devices can be adjusted. Thus, the movable stage 22 can be positioned in the rotational direction around the X axis 27 and the Y axis 28. In this case, the rotation angle of the movable stage 22 can be calculated from the measured values of the three displacement sensors 11 and the distance between the displacement sensors 11.
Similarly, the movable stage 22 can be moved in the X-axis 27 and Y-axis directions by the thrust of the X-axis actuator 23 and the Y-axis actuator 24 and rotated around the Z-axis 29.
FIG. 9 is a view showing a state in which the movable stage 22 is moved in the X-axis 27 direction by the X-axis actuator 23. When the movable stage 22 moves in the X-axis 27 direction by the thrust of the X-axis actuator 23, the bellows 10 bends in the X-axis 27 direction, and the height of the movable stage 22 changes or tilts, but the actuator 4 is operated. By controlling the position in the Z-axis 29 direction, the movable stage 22 is rotatably supported by the spherical support portion 18, so that the position can be kept constant and horizontal.

  Here, the effect of the presence of a gap between the stator and the mover of the actuator 4 in this embodiment will be described. As described above, when the movable stage 22 moves in a certain axial direction, the movable element of the actuator operated in the other two axial directions orthogonal to the moving direction is moved in the direction orthogonal to the thrust direction. End up. However, since the three precision fine positioning devices shown in this embodiment, the X-axis actuator 23 and the Y-axis actuator 24 both have a gap m between the mover and the stator, the mover and the stator interfere with each other. The problem of restricting the operation can be avoided. Since the required movement stroke in a finely positioning apparatus for finely positioning a reticle or mask of a semiconductor or liquid crystal exposure apparatus in which the fine movement positioning stage of this embodiment is used is generally several tens of μm or less, the operation of the actuator There is no risk of changes in characteristics.

Further, another example of the contact portion described in FIG. 4 will be described with reference to FIG.
FIG. 5 is a side view showing a contact portion between the precision fine movement positioning device and the movable stage, as in FIG. The contact portion shown in FIG. 5 is obtained by fixing a bending support portion 19 on the movable base 2 of the precision fine movement positioning device and attaching a pedestal 20 on the upper side of the bending support portion 19. The lower surface of the movable stage 22 is fixed to the upper surface of the pedestal 20. The bending support portion 19 is formed by reducing the diameter of a part of a metal round bar so that the thinned portion is bent and easily twisted.
With such a configuration, the pedestal 20 can move freely with respect to the movable base 2 by the deformation of the bending support portion 19. In the embodiment of the fine movement positioning stage, the example in which the fine movement positioning stage is configured using the contact portion described in FIG. 4 has been described. However, the same effect can be obtained by using the contact portion described in FIG.

Front view of precision fine positioning device of the present invention Side view of precision fine positioning device of the present invention 1 is an enlarged cross-sectional view of the elastic support mechanism of FIG. Side view showing contact portion between precision fine positioning device and movable table Side view showing another example of contact portion between precision fine positioning device and movable table Top view of fine movement positioning stage using precision fine movement positioning device of the present invention Side view of FIG. Part of a side view showing a state in which the movable stage of the fine positioning stage in FIG. 6 is rotated about the Y axis FIG. 6 is a side view showing a state in which the movable stage of the fine positioning stage in FIG. 6 has moved in the X-axis direction. The top view which shows the apparatus of patent document 1 as a prior art example Side sectional view showing the device of Patent Document 1 as a conventional example Side sectional view showing the device of Patent Document 2 as a conventional example

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fixed base 2 Movable base 3 Elastic support mechanism 4 Actuator 5 Stator 5a Yoke 5b Magnet 6 Movable element 6a Coil base 6b Coil 7 Gap m
8 Lower fixing flange 9 Upper fixing flange 10 Bellows 11 Displacement sensor 12 Displacement sensor detector 13 Shaft 13a Position adjusting screw 13b Guide portion 14 Lock nut 15 O-ring 16 Joint 17 Gap s
18 Spherical support portion 19 Deflection support portion 20 Pedestal 21 Stage base 22 Movable stage 23 X-axis actuator 24 Y-axis actuator 25 X-axis displacement sensor 26 Y-axis displacement sensor 27 X-axis 28 Y-axis 29 Z-axis 30 Support member (elastic body)
31 Piezoelectric Element 32 Lower Plate 33 Upper Plate 34 Electrode 40 First Precision Fine Positioning Device 41 Second Precision Fine Positioning Device 42 Third Precision Fine Positioning Device

Claims (7)

A fixed base;
An electromagnetic comprising: a pair of stators erected on the fixed base; and a mover that is opposed to the pair of stators through a predetermined gap and is movable up and down with respect to the stator. An actuator,
An elastic support comprising a bellows, an upper end and a lower end flange for sealing the upper end and the lower end of the bellows, respectively, and a working fluid having a predetermined pressure filled in the bellows, and the lower end flange is attached to the fixed base Mechanism,
A movable base supported by the movable element and the upper end flange;
In the precision fine positioning device with
The elastic support mechanism is
A displacement sensor provided on the lower flange so as to be accommodated in the bellows;
A screw hole provided in the upper end flange and penetrating into the bellows;
A shaft inserted into the screw hole;
A displacement sensor detection body provided on the shaft so that the displacement sensor can be detected;
Sealing means for closing a gap between the screw hole and the shaft;
With
In the movable base,
A through hole was provided at a position corresponding to the shaft;
Precision fine positioning device characterized by. A lock nut is provided on the shaft, and the shaft is fixed to the upper end flange by the lock nut;
The precision fine movement positioning device according to claim 1. The positional relationship between the mover and the stator in the electromagnetic actuator is reversed,
The fine fine positioning device according to claim 1 or 2, wherein At least three precision fine-movement positioning devices according to claim 1, 2 or 3,
A stage base that supports the fixed base of each of the at least three precision fine positioning devices;
A movable stage supported by the movable base of each of the at least three precision fine positioning devices;
With
In the movable stage,
A through hole was further provided at a position corresponding to the through hole provided at a position corresponding to the shaft of each of the at least three precision fine positioning devices;
Fine movement positioning stage characterized by The movable base of each of the at least three precision fine positioning devices;
A plate-like base having a step in the vertical direction, wherein the upper end flange of the elastic support mechanism is fixed to the lower surface of the lower step of the step, the mover is fixed to the lower surface of the upper step of the step, and the lower step of the step The movable stage is supported on the upper surface of
The fine movement positioning stage according to claim 4. A spherical support is provided between the movable base of each of the at least three precision fine positioning devices and the movable stage;
6. The fine movement positioning stage according to claim 4 or 5, wherein: Between the movable base of each of the at least three precision fine-movement positioning devices and the movable stage, a bending support portion formed of a rod-like member having a part of the diameter of a metal round bar is provided. thing,
6. The fine movement positioning stage according to claim 4 or 5, wherein:

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