JP2008103497A - Assembly structure, and stage apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inexpensive assembly structure in which the distortion of a member composing the assembly structure does not develop even if a temperature in a stage changes. <P>SOLUTION: The assembly structure includes a first member 1 made of a nonmetalic material, a second member 2 made of a metallic material, and a fastening member 3 which fastens the first and second members 1 and 2 together. The fastening member 3 is so shaped as to have rigidity that is lower in one direction than in another direction. The fastening member 3 thus elastically deforms to absorb a difference in length between the first member and the second member that results from a difference in thermal expansion coefficients between the first member 1 and the second member 2. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an assembly structure for a stage apparatus, particularly an exposure apparatus or the like that requires high-precision positioning.

In recent years, semiconductor circuits have been increasingly refined. For example, in a semiconductor exposure apparatus equipped with a stage device, the stage device is required to be positioned with extremely high accuracy using a measuring device such as a laser interferometer. In order to achieve highly accurate positioning, the rigidity of the stage apparatus itself becomes important, so that the stage apparatus tends to be enlarged in order to increase the rigidity. The stage device is driven by using an actuator such as a linear motor. However, in order to minimize energy loss, the stage device is generally configured to receive a load using an air bearing. The air bearing portion has a very narrow gap between pads and is about several microns, and the material constituting the air bearing portion is required to have high thermal and mechanical stability. For this reason, generally non-metallic materials, such as ceramics, are used as a material which comprises an air bearing part.
In the large stage as described above, the heat generated by an actuator such as a linear motor is transferred to surrounding members to cause thermal expansion, but the thermal expansion coefficient between the ceramic material forming the air bearing portion and the material forming the periphery thereof is If they are different from each other, the amounts of thermal expansion are greatly different, so that a so-called bimetal phenomenon in which stress is generated and deformed at the fastening portion occurs, and the gap is distorted and the gap of the air bearing portion may be crushed.
For this reason, it is necessary to make the coefficient of thermal expansion equal to the material of the assembly structure material which comprises the air bearing part and its periphery (for example, refer patent document 1).

  FIG. 4 is a diagram showing a cross section of a fastening portion between the sample stage 43 and the movable mirror 44 according to Patent Document 1. The movable mirror 44 is fixed to the sample stage 13 with a screw 47 and a bush 49 screwed with the screw 47. ing. The sample stage 43 and the movable mirror 44 are made of the same ceramic material. The screw 47 is an alloy (Invar) screw having a very small thermal expansion coefficient of 1 to 2 ppm / K. Since the sample stage 43 is made of ceramics, it is difficult to form a female screw directly on the sample stage 43. Therefore, a metal bush 49 is embedded, and the female screw corresponding to the screw 47 is embedded in the bush 49. Is formed. This bush 49 is also made of the same alloy as the screw 47. Further, the spherical washer 41 interposed between the screw 47 and the movable mirror is also composed of the same invar.

  Thus, by configuring the sample stage 43 and the movable mirror 44 with the same ceramic material, even if the temperature around the sample stage 43 changes, the amount of thermal expansion and contraction of both is equal and deformation due to the bimetal phenomenon does not occur. Furthermore, by using an Invar screw 47, which is a low expansion alloy having substantially the same thermal expansion coefficient for fastening both, axial force change due to change in ambient temperature is reduced, and distortion of the sample stage 43 and the movable mirror 44 is suppressed. ing.

In addition, as an assembly structure composed of a metal member and a ceramic member, there are many damper layers made of a material having a gradually high thermal expansion coefficient from the ceramic member side having a low thermal expansion coefficient toward the metal member side having a high thermal expansion coefficient. There has also been proposed a method in which fixing is performed by brazing or vapor deposition in stages, and the difference in thermal expansion coefficient between the two is absorbed to prevent distortion and thermal stress. (For example, see Patent Document 2)
JP 2004-241670 A Japanese Patent Laid-Open No. 10-41377

FIG. 5 is a cross-sectional view showing the structure of the electrostatic chuck device described in Patent Document 2. This electrostatic chuck device includes a base member 51 made of an aluminum alloy provided with a cooling water jacket 5a, and the base member 51. The first to third damper layers 52 to 54 provided on the upper surface and the electrostatic chuck 55 provided on the third damper layer 54 are provided. The electrostatic chuck 55 includes a lower insulating layer 56 made of ceramic, a metal electrode layer 57, and an upper insulating layer 58. The metal electrode layer 57 is selectively supplied with power from the outside. Since the entire surface of the base member 51 and the first damper layer 52 and the lower insulating layer 56 and the third damper layer 54 of the electrostatic chuck 55 are brazed, the base member Heat is efficiently transferred to 51. The first to third damper layers 52 to 54 are made of a composite material using aluminum as a matrix metal and ceramics such as alumina as an additive.
The ratio between the matrix metal and the additive is changed so that the coefficient of thermal expansion gradually decreases from the first damper layer 52 on the base member 51 side to the third damper layer 54 on the lower insulating layer 56 side. That is, by providing a plurality of damper layers 52 to 54 that gradually change in thermal expansion coefficient between the base member 51 having a high thermal expansion coefficient and the electrostatic chuck 52 having a low thermal expansion coefficient, the thermal stress is gradually relieved. Thus, an excessive stress is not applied to the relatively fragile electrostatic chuck 55.

However, the prior arts 1 and 2 have the following problems.
In a semiconductor exposure apparatus equipped with a stage member, it is necessary to increase the rigidity of the assembly structure, so that the apparatus itself tends to increase in size, leading to an increase in the amount of thermal expansion of components in proportion to the increase in size of the apparatus. End up. For this reason, as described in Reference 1, it is necessary to construct the assembly structure with a material having the same thermal expansion coefficient and to equalize the thermal expansion amount of each member to prevent mutual distortion and stress between the members. It is necessary to construct all parts other than members that require processing accuracy and low thermal expansion materials such as air bearing parts using non-metallic materials such as ceramics. There is a problem of becoming.
Further, as described in Reference 2, the thermal expansion coefficient gradually increases from the ceramic member side to the metal member side between the ceramic member having a low thermal expansion coefficient and the metal member having a high thermal expansion coefficient. When a damper layer is laminated on the surface by brazing or vapor deposition to prevent distortion and thermal stress from occurring due to differences in thermal expansion, the large assembly structure has a large thermal expansion that cannot be tolerated by the damper layer. Distortion due to the difference, generation of thermal stress, or breakage of the brazed portion may occur.

  The present invention has been made in view of the above problems, and provides an assembly structure that can be configured at low cost and that does not cause distortion in the components that are formed even if the temperature in the stage changes, and a stage apparatus using the assembly structure. The purpose is to do.

In order to achieve the above object, an invention according to claim 1 relates to an assembly structure, wherein a first member made of a non-metallic material, a second member made of a metal material, the first member, and the An assembly structure including a fastening member that fastens the second member is characterized in that the fastening member has a shape that is less rigid in only one direction than in the other direction.
According to a second aspect of the present invention, in the assembly structure according to the first aspect, the fastening member is provided with a through long hole extending in a direction perpendicular to the one direction.
According to a third aspect of the present invention, in the assembly structure according to the second aspect, a plurality of the through long holes are arranged in parallel to each other.
According to a fourth aspect of the present invention, in the assembly structure according to the first or second aspect, when the fastening member is interposed between the first member and the second member, the first member and the second member It is characterized in that the fastening member is attached in a direction that absorbs the displacement caused by the difference in the amount of thermal expansion with the direction of low rigidity of the fastening member.
According to a fifth aspect of the present invention, in the assembly structure, a first member made of a non-metallic material, a second member made of a metallic material, and a fastening member that fastens the first member and the second member In the assembly structure constituted by the above, an elastic body is interposed when the fastening member is fastened.
The invention according to claim 6 is the assembly structure according to claim 5, wherein the elastic body is an O-ring.
According to a seventh aspect of the present invention, in the assembly structure according to the sixth aspect, the first member is attached to the second member with gaps in all directions of X, Y and Z when the fastening member is fastened. The O-ring is sandwiched and crushed in a gap in the Z direction of the fastening member.
The invention according to an eighth aspect relates to an assembly structure, wherein the one direction is fastened by using the assembly structure according to any one of the first to fourth aspects, and the other direction is any one of the fifth to seventh aspects. The assembly structure according to item 1 is used for fastening.
A ninth aspect of the present invention relates to a stage apparatus, and includes the assembly structure according to any one of the first to seventh aspects.
A tenth aspect of the present invention relates to a stage apparatus, and includes the assembly structure according to the eighth aspect.

According to the above configuration, when the stage temperature is increased by fastening the first member made of the non-metallic material and the second member made of the metal material through the fastening member having low rigidity in one direction. In addition, distortion and internal stress generated due to the difference in thermal expansion between the non-metallic material and the metallic material can be relaxed by deformation of the fastening member, and the other directions can be fixed with high rigidity.
Moreover, when the stage temperature rises by fastening the first member formed of the non-metallic material and the second member formed of the metal material with the fastening member via the elastic body, the non-metallic material and Distortion and internal stress generated due to the difference in thermal expansion of the metal material can be relaxed by deformation of the fastening member, and the vibration damping rate can be increased.

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

FIG. 1 is a perspective view of a fastening member of the assembly structure according to the first embodiment.
In the figure, 1 is a first member, 2 is a second member, 3 is a fastening member, the first member 1 is formed of a non-metallic material typified by ceramics, and the second member 2 is formed of a metallic material. Yes. 1a is a fastening hole provided in the first member 1, and 3b is a fastening hole provided in the fastening member 3. The fastening hole 1a and the fastening hole 3b are aligned with the center line of the hole and tightened together through a bolt. Thus, the first member 1 and the fastening member 3 are fastened.
Further, 3a is a fastening hole provided in the fastening member 3, and 2b is a fastening hole provided in the second member 2 (not visible in the figure). The fastening hole 3a and the fastening hole 2b are arranged at the center line of the hole. The fastening member 3 and the second member 2 are fastened by aligning them and tightening them together through bolts.
<Shape of fastening member 3>
The fastening member 3 is a metal part having a shape with extremely low rigidity in the longitudinal direction of the assembly structure. As a shape for making the rigidity in the longitudinal direction extremely low, for example, as shown in the figure, a plurality of elongated through holes 3c extending in the direction (Y direction) crossing the longitudinal direction (X direction) are provided. do it.
In this way, when a force is applied in a direction extending from both sides in the X direction of the fastening member 3, the rigidity in the longitudinal direction is remarkably reduced because there are a plurality of elongated through holes 3 c, and the fastening member 3 is It is easily stretched to both sides in the X direction.
On the other hand, even if a force is applied in the direction extending from both sides in the Y direction of the fastening member 3, since there are three parallel metal columns without the through-holes, great rigidity is maintained. Is not stretched to both sides in the Y direction.
Similarly, even if a force is applied in the direction extending from both sides in the Z direction of the fastening member 3, there are many portions where no through-holes are interposed, and the fastening member 3 is not stretched to both sides in the Z direction. .
<How to use the fastening member 3>
Therefore, the fastening member 3 is placed in the recess of the second member 2, and a fastening bolt is screwed from the fastening hole 3 a of the fastening member 3 toward the fastening hole 2 b of the second member 2. Is concluded.
Next, the first member 1 is placed on the fastening member 3, and a fastening bolt is screwed from the fastening hole 1 a of the first member 1 toward the fastening hole 3 b of the fastening member 3. 3 is fastened, and the first member 1 and the second member 2 are fastened through the fastening member 3.
<Function of fastening member 3>
Thus, by fastening the first member 1 and the second member 2 via the fastening member 3 according to the first embodiment, the temperature of the stage rises due to heat generated by an actuator or the like that drives the stage, for example. When thermal expansion occurs in the first member 2 and the second member 2, distortion occurs in the longitudinal direction in which the difference between the thermal expansion amounts of the first member 1 and the second member 2 is the largest. The distortion direction is the X direction of the fastening member 3. Therefore, only the X direction both sides of the fastening member 3 are deformed, and the strain and internal stress in the X direction generated in the first member 1 and the second member 2 can be alleviated.

FIG. 2 is a side sectional view of a fastening member of the assembly structure according to the second embodiment.
In the figure, 11 is a first member, 12 is a second member, 13 is a fastening member, 14 is an elastic body, and 15 is a bolt. The elastic body 14 is an O-ring, for example.
The first member 11 is made of a nonmetallic material typified by ceramics, and the second member 12 is made of a metallic material. The fastening member 13 fixes the first member 11 to the second member 12 with gaps in all the X, Y, and Z directions when the bolt 15 is fastened. At this time, the elastic body 14 is sandwiched between gaps formed on both sides of the fastening member 13 in the Z direction + and −, and the O-ring is crushed to a design value calculated in advance.
As a result, the temperature of the stage rises, and even if a difference in thermal expansion occurs between the first member 11 and the second member 12, the elastic body 14 sandwiched between the fastening members 13 is deformed in the X and Y directions (but is elastic). Since the body 14 is crushed in the Z direction, it is rigid in the Z direction and does not deform.), Strain in the X and Y directions and internal stress generated in the first member 11 and the second member 12 can be relieved. .
Further, by sandwiching the elastic body 14, the vibration damping rate of the assembly structure is also increased.

FIG. 3 is a perspective view of an assembly structure that can relax strain and internal stress in all directions of X, Y, and Z by skillfully using the first and second embodiments.
In the figure, 21 is an air slider guide, 22 is a stainless steel member, 23 is a fastening member according to Embodiment 1 (FIG. 1), 24 is a fastening member according to Embodiment 2 (FIG. 2), and 25 is an air slider guide fixing plate. is there.
The air slider guide 21 and the air slider guide fixing plate 25 are made of ceramics, and two air sliders (not shown) arranged on the left and right are fixed in parallel. An air slider pad (not shown) configured to surround the four surfaces of the air slider guide 21 is driven by an actuator (not shown) along the air slider guide 21. At this time, the gap of the air slider is very narrow, about several microns, and there is a possibility that the slider comes into contact due to distortion caused by the difference in coefficient of thermal expansion between the members. Here, when the present invention is applied to a large assembly structure in the X and Y directions as in the stage device, the difference in thermal expansion amount in either the Y direction or the X direction is determined by the fastening member of the first embodiment. The fastening is performed to allow, and the fastening member of Example 2 is used to fasten the remaining amount of thermal expansion in the other direction.
As a result, the mutual distortion and internal stress caused by the difference in thermal expansion caused by the heat generated by the actuators of the air slider guide 21 and the stainless steel member 22 can be alleviated. It is possible to construct an assembly structure using ceramics for necessary parts and using inexpensive materials such as stainless steel for other parts.

  The present invention is not limited to non-metallic materials and metallic materials, and it is possible to relieve strain and internal stress when an assembly structure is configured by fastening parts having different thermal expansion coefficients.

3 is a perspective view of a fastening member of the assembly structure according to Embodiment 1. FIG. It is a sectional side view of the fastening member of the assembly structure which concerns on Example 2. FIG. It is a perspective view of the assembly structure using Example 1 and Example 2. FIG. It is sectional drawing of the fastening part which concerns on patent document 1. FIG. It is sectional drawing which shows the structure of the electrostatic chuck apparatus based on patent document 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 1st member 1a Fastening hole 2 2nd member 2b Fastening hole 3 Fastening member 3a Fastening hole 3b Fastening hole 3c Through-hole 11 First member 12 Second member 13 Fastening member 14 Elastic body 15 Bolt 21 Air slider guide 22 Stainless steel member 23 Example 1
24 Fastening member 25 of Example 2 Air slider guide

Claims (10)

  In an assembly structure including a first member formed of a non-metallic material, a second member formed of a metal material, and a fastening member that fastens the first member and the second member, the fastening member is An assembly structure characterized by having a shape having low rigidity compared to other directions in only one direction.   The assembly structure according to claim 1, wherein the fastening member includes a through long hole extending in a direction perpendicular to the one direction.   The assembly structure according to claim 2, wherein a plurality of the through-holes are arranged in parallel to each other.   When the fastening member is interposed between the first member and the second member, the low rigidity of the fastening member in a direction to absorb a displacement caused by a difference in thermal expansion between the first member and the second member. The assembly structure according to claim 1 or 2, wherein the assembly structure is attached in the same direction.   An assembly structure including a first member formed of a non-metallic material, a second member formed of a metal material, and a fastening member that fastens the first member and the second member. An assembly structure characterized in that an elastic body is interposed when fastening.   6. The assembly structure according to claim 5, wherein the elastic body is an O-ring.   When the fastening member is fastened, the first member is fixed to the second member with gaps in all directions of X, Y, and Z, and the O-ring is sandwiched between the Z-direction gaps of the fastening member. 7. The assembly structure according to claim 6, wherein the assembly structure is crushed.   The said one direction is fastened using the assembly structure of any one of Claims 1-4, and the other direction is fastened using the assembly structure of any one of Claims 5-7. An assembly structure characterized by.   A stage apparatus comprising the assembly structure according to any one of claims 1 to 7.   A stage apparatus comprising the assembly structure according to claim 8.

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