JP6355938B2 - Stage device with bracket - Google Patents

Description

  The present invention is a stage device using a linear motor that realizes high speed and high response. For example, a fixing bracket is provided between an X-axis slide device and a Y-axis slide device arranged orthogonally thereon. The present invention relates to an intervening stage apparatus.

  In recent years, in an XYθ multi-axis stage and motion mechanism used in various technical fields, a stage device that moves a work, a tool, or an article or equipment at high speed and positions with high accuracy, and has a compact and lightweight structure. Is required. The stage device uses a linear motor capable of high thrust and high speed and high response. In the linear motor, the armature coil is arranged on the bed as the base member as a stator over the entire length in the longitudinal direction. And a movable magnet type linear motor in which a field magnet made of a permanent magnet is attached as a mover to a table slidable in the longitudinal direction with respect to the bed, or a field magnet is provided as a stator on the bed, and There is a moving coil type linear motor in which a plurality of armature coils sequentially arranged with a phase difference shifted by the electrical angle is provided on a table as a mover.

  2. Description of the Related Art As a slide device incorporating a moving coil type linear motor, there has been known a compact device that is configured by thinly and highly rigidly forming a magnet yoke that supports a field magnet. With respect to the slide device, the magnet yoke that supports the field magnet on the inner surface side is formed in a U-shaped cross section from a pair of opposing portions and a side connecting portion that integrally connects the opposing portions. The magnet yoke can increase the overall rigidity even if each portion is formed thin, as compared with the case where each opposing portion and side connecting portion are manufactured separately. A part of the bed can also be used as the opposite part and the side connecting part on the bed side. A table slidable on a bed via a linear motion guide unit has a movable coil assembly (see, for example, Patent Document 1).

JP 2000-333435 A

  By the way, with respect to the conventional slide device, when the slide device is assembled on the XY axes orthogonal to each other on the work stage of the semiconductor / liquid crystal related assembly / inspection device, the Y-axis slide device, which is the upper shaft, bends, and the movable table. There is a possibility that the running accuracy of will deteriorate. For this reason, there is known a device that employs measures such as providing a support slide device and supporting both ends of the upper shaft from the base. However, in the slide device as described above, the sliding resistance increases due to the influence of the support slide device, and the load on the X-axis slide device, which is the lower shaft, increases, and the motor needs to be large for high speed operation. Occurs. On the other hand, if the bracket that fixes the upper shaft and the lower shaft is made of solid solid material so that the Y-axis slide device of the upper shaft does not bend, the lower shaft is the same as when the support slide device is provided. As a result, there is a possibility that high-speed operation may not be possible. Also, if the upper Y-axis slide device bends on the work stage of an inspection device or measurement device equipped with a CCD camera, the focus of the target object will shift and accurate inspection and measurement will not be possible.

  A stage apparatus 51 having a basic structure will be described with reference to FIGS. The stage device 51 is a θ-axis stage of θ-axis which is a rotation direction to be an alignment stage device disposed on the lower-axis X-axis slide device 52, the upper-axis Y-axis slide device 55, and the Y-axis slide device 55. This is an XYθ stage apparatus composed of 58. The X-axis slide device 52 and the Y-axis slide device 55 have, for example, a built-in moving coil type linear motor (not shown). The stage device 51 includes a bed 53 and a movable table (not shown) provided movably with respect to the bed 53. The stage device 51 is disposed perpendicular to the movable table of the X-axis slide device 52. A Y-axis slide device 55 comprising a bed 56 and a movable table 57 provided so as to be movable with respect to the bed 56, and a bed 66 attached to the movable table 57 via a spacer 59 and rotatable on the bed 66. The θ-axis stage 58 is composed of a turntable 67 provided. The Y-axis slide device 55 is fixed to a support slide device 68 provided on the base 69 at both ends of the bed 56 via a spacer 62. Further, the stage device 51 is a basic structure product that mutually connects a bed 56 constituting a Y-axis slide device 55 arranged orthogonally on a movable table (not shown) constituting the X-axis slide device 52. A bracket 60 is provided. The lower surface of the bracket 60 is fixed to the upper surface of the movable table 54 of the X-axis slide device 52, and the upper surface side of the bracket 60 is fixed to the lower surface of the bed 56 of the Y-axis slide device 55. As shown in FIG. 8, the bracket 60 is formed on a rectangular flat plate 61 in which mounting holes 63 and 64 are formed.

  SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problems, and to achieve a reduction in weight of the bracket by interposing a bracket serving as a reinforcing member for maintaining rigidity between the X-axis slide device and the Y-axis slide device. The shape is optimized, and the Y-axis slide device's movable table's displacement is reduced by minimizing the bed deflection of the Y-axis slide device as much as possible without hindering the high-speed and high-acceleration operation of the stage device. Thus, it is to provide a stage apparatus having a bracket characterized in that high accuracy is achieved.

The present invention relates to an X-axis slide device comprising a first bed and a first movable table slidably provided with respect to the first bed by a first linear motor, and the first of the X-axis slide device. A Y-axis slide device comprising a second bed fixed orthogonally to the movable table and a second movable table slidably provided to the second bed by a second linear motor is provided. In the stage device,
The second bed is fixed to the first movable table by being respectively fixed to the first movable table constituting the X-axis slide device and the second bed constituting the Y-axis slide device. With brackets,
The bracket is formed of a substantially rectangular flat plate whose outer shape and cross section are formed so that the length in the moving direction is longer than the width.
The bracket is formed such that a length in the moving direction is shorter than the second bed and longer than the second movable table,
The width of the bracket is shorter than the length of the first movable table in the sliding direction and is substantially the same as the width of the second bed;
The bracket includes a pair of portions each formed by a cut V-shaped cutout portion whose width in the moving direction is reduced from both sides toward the center, and the brackets at the both ends. The present invention relates to a stage apparatus provided with a bracket, characterized in that it is formed from a main body part that forms an attachment surface for attaching the first movable table of the X-axis slide device between the parts.

  In this stage device, the lower surface of the bracket is fixed to the upper surface of the first movable table of the X-axis slide device, and the upper surface of the bracket is fixed to the lower surface of the second bed of the Y-axis slide device. It is what.

  Further, in this stage apparatus, the X-axis slide device includes a first track rail fixed to the first bed and a first slider fixed to the first movable table and reciprocatingly moving on the first track rail. A first linear guide unit is interposed, and the Y-axis slide device is fixed to the second track rail fixed to the second bed and the second movable table, and reciprocates between the second track rails. A second linear motion guide unit composed of a moving second slider is interposed.

Further, in this stage device, the V-shaped notch portions are formed symmetrically at the both end portions of the bracket and do not reach both end surfaces in the width direction of the first movable table of the X-axis slide device. Is.

  In this stage apparatus, the second movable table of the Y-axis slide device is provided with a θ-axis stage having a turntable that moves in the rotational direction with respect to the second movable table.

  In the stage device, a plurality of first mounting holes for mounting the second bed of the Y-axis slide device are formed on both side portions of the one portion and the main body portion of the bracket. A plurality of second mounting holes for mounting the first movable table of the X-axis slide device are formed in the bracket body in the width direction of the bracket. It is formed along.

The stage apparatus, the main body portion of the bracket, the bracket being at least one through hole is formed to the light, said through hole, said second attachment formed in the body portion are those formed between use hole.

  In addition, the bracket is formed such that the length in the moving direction of the one portion at both ends is substantially the same as the length in the moving direction of the main body portion. Furthermore, the overall length of the bracket is longer than the moving stroke of the second movable table of the Y-axis slide device. The bracket is made of an aluminum alloy and is covered with an alumite coating layer on the surface.

  As described above, the stage device including the bracket according to the present invention interposes a bracket serving as a reinforcing member for maintaining rigidity between the X-axis slide device and the Y-axis slide device, and achieves weight reduction of the bracket. Optimize the shape of the bracket, reduce the weight and suppress the high-speed high-acceleration operation of the stage device by the bracket, suppress the bed deflection of the Y-axis slide device arranged on the X-axis slide device, It is possible to reduce the amount of displacement of the movable table of the Y-axis slide device, thereby achieving high accuracy of the stage device. In addition, this stage device can be placed horizontally and the load acting on the lower shaft slide device can be reduced compared to the conventional structure in which a slide device for support is provided to support both ends of the upper shaft slide device. The maximum thrust required for the motor to accelerate and decelerate by driving the movable table can be reduced, and the stage device can be operated at higher speed and higher acceleration. In addition, by reducing the weight of the bracket, the inertia of the movable member mounted on the movable table of the X-axis slide device such as the Y-axis slide device or the θ-axis stage is reduced, and the maximum thrust required for acceleration / deceleration is reduced. The movable table can be operated at higher speed and higher acceleration, and the stage device can be positioned at higher speed and higher response. In addition, this stage device efficiently suppresses the deflection of the upper-axis slide device overhanging from the movable table of the lower-axis slide device, and suppresses the displacement of the movable table of the Y-axis slide device of the stage device. Accuracy can be achieved.

It is a perspective view which shows XY (theta) stage apparatus which is one Example of the stage apparatus provided with the bracket by this invention. It is a top view which shows the XY (theta) stage apparatus seen from the C direction of FIG. It is a top view which shows the XY (theta) stage apparatus seen from the D direction of FIG. It is sectional drawing which shows the linear motor located between a bed and a movable table in order to demonstrate the linear motor integrated in the X-axis slide apparatus or Y-axis slide apparatus in the XY (theta) stage apparatus of FIG. It is a perspective view which shows one Example of the bracket integrated in the stage apparatus provided with the bracket by this invention. It is a perspective view which shows another Example of the bracket integrated in the stage apparatus provided with the bracket by this invention. It is a top view which shows an example which incorporated the basic bracket in the multi-axis stage apparatus. It is a perspective view which shows the basic bracket integrated in the multi-axis stage apparatus of FIG. It is a perspective view which shows the model which interposed the bracket between the Y-axis slide apparatus for evaluating the deformation | transformation by the load of a bracket with a finite element method, and the movable table of an X-axis slide apparatus. It is a perspective view which shows the analysis result about the bending at the time of using a bracket using the model of FIG. It is a graph which shows the relationship between the length of a bracket, and the maximum displacement of the whole Y-axis slide apparatus used as an upper axis. It is a graph which shows the relationship between the bracket displacement and the maximum displacement on the movable table of the Y-axis slide device used as an upper axis. It is a graph which shows the relationship between the length of a bracket, and mass. It is a graph which confirms the efficiency which suppresses a displacement with a lighter bracket structure. The It is a diagram which shows the table driving | operation pattern which calculated the effect of weight reduction of a bracket.

  An embodiment of a stage apparatus having a bracket according to the present invention will be described below with reference to the drawings. As shown in FIGS. 1 to 3, the stage device including the bracket according to the present invention is a multi-axis stage device 1, and the multi-axis stage device 1 is an X axis that is a straight line serving as a lower axis. Axis slide device 2, a Y axis slide device 5 that is a Y axis that is a straight line that is an upper axis, and a θ axis stage 8 that is a rotation direction that is an alignment stage device disposed on the Y axis slide device 5 To XYθ stage apparatus. The X-axis slide device 2 and the Y-axis slide device 5 incorporate a moving coil linear motor. The multi-axis stage apparatus 1 in this embodiment includes a bed 3 (first bed) fixed to at least a base 18 (see FIGS. 2 and 3) such as a base and a machine base, and a linear motor 31 (first X-axis slide device 2 composed of a movable table 4 (first movable table) slidably provided by one linear motor) and a bed arranged orthogonal to the movable table 4 of the X-axis slide device 2 6 (second bed) and a Y-axis slide device 5 composed of a movable table 7 (second movable table) slidably provided with respect to the bed 6 by a linear motor 31 (second linear motor). ing. Further, in the X-axis slide device 2, a pair of track rails 41 are fixed to the bed 3 so as to extend in the moving direction, a plurality of sliders 42 are fixed to the movable table 4, and the movable table 4 is fixed to the bed 3. It is configured to be able to move back and forth. In the Y-axis slide device 5, a pair of track rails 39 is fixed to the bed 6 so as to extend in the moving direction, a slider 40 is disposed and fixed to the movable table 7, and the movable table 7 is fixed to the bed. 6 is configured to be able to reciprocate. In the θ-axis stage 8, a bed 16 is fixed on a movable table 7 via a spacer 9, and a turntable 17 is rotatably arranged on the bed 16 by a driving means such as a linear motor.

  The X-axis slide device 2 and the Y-axis slide device 5 are each provided with a linear motor 31 as shown in FIG. 4, for example. The linear motor 31 is a movable coil type linear motor, and a magnet yoke 32 having a large number of magnets 33 attached to the beds 3 and 6 is disposed. An armature assembly 34 that is a coil module is disposed on the movable tables 4 and 7. Is attached. The linear encoder 35 includes a linear scale 36 and a linear encoder head 37. The beds 3 and 6 are provided with a linear scale 36 and an origin mark 38, and a linear encoder head 37 is attached to the movable tables 4 and 7. Further, the linear motor 31 is provided with an air cooling pipe 50 for cooling the heating state generated by the reciprocating movement of the armature assembly 34. The bed 3 has end plates 48 fixed to both ends, and stoppers 46 that restrict the movement of the movable table 4 in the longitudinal direction are attached to the end plates 48. The bed 6 has end plates 49 fixed to both ends, and a pair of stoppers 47 for restricting the movement of the movable table 7 in the longitudinal direction are attached to the end plates 49, respectively.

  In this multi-axis stage device 1, for example, the height of the device itself is about 70 mm, both bed widths are about 170 mm, the bed length is about 700 mm, the movable table stroke is 330 mm, and the total length of the movable table is 200 mm. . The θ axis is an alignment stage device incorporating a linear motor. The turntable 17 as a rotary table has a diameter of 200 mm, and the operating angle of the turntable is 280 degrees. The base 18 of the multi-axis stage device 1 is made of an aluminum alloy, the size of the base 18 is 760 mm × 700 mm, the height of the XYθ stage device is 183 mm, and the overall height of the device is about 350 mm, saving space. In the stage device for which the above is required, linear motor driving is preferable to ball screw driving.

  This stage device, that is, the multi-axis stage device 1, in particular, is a bracket 10 that connects the bed 6 that constitutes the Y-axis slide device 5 that is disposed orthogonally on the movable table 4 that constitutes the X-axis slide device 2. It has the characteristics in having. In other words, the bracket 10 functions as a reinforcing member for connecting and fixing the lower-axis X-axis slide device 2 and the upper-axis Y-axis slide device 5 and suppressing the deflection of the Y-axis slide device 5. is there. In this embodiment, the lower surface 26 side of the bracket 10 is fixed to the upper surface 28 of the movable table 4 of the X-axis slide device 2, and the upper surface 27 side of the bracket 10 is fixed to the lower surface 29 of the bed 6 of the Y-axis slide device 5. Yes. In a region where the movable table 7 of the Y-axis slide device 5 is overhanging the movable table 4 of the X-axis slide device 2, the base portion 11 is closer to the base than the tip 19 side of the one portion 12 of the bracket 10. A large moment load will act on the. The bracket 10 is made of an aluminum alloy, and an alumite coating layer 25 is applied to the surface of the bracket 10 by an alumite treatment.

  The bracket 10 incorporated in the multi-axis stage apparatus 1 is mainly formed based on the concept of equal strength beams so that the balance between the two can be balanced in order to achieve both weight reduction and increased rigidity. Here, the equal strength beam means a beam whose cross-sectional shape is changed in accordance with the bending moment so that a uniform bending stress is generated in any cross section of the beam. In this embodiment, the shape of the longitudinal end 30 side of the bracket 10 is formed in an optimal cross-sectional shape based on the concept of equal strength beams, and according to the concept of equal strength beams, the bracket 10 A method of changing the width dimension while keeping the plate thickness 10 constant is employed. In the embodiment, the bracket 10 is formed in a substantially rectangular thin plate whose outer shape and cross section are formed so that the length in the moving direction is longer than the width, and the length in the moving direction is shorter than the bed 6. The width of the bracket 10 is shorter than the length of the movable table 4 in the sliding direction, and is substantially the same as the width of the bed 6.

  In this multi-axis stage apparatus 1, the bracket 10 has a V-shaped cut-out with a hollow portion in which both end portions 19 in the moving direction become narrower from both side portions 20 toward the center portion 21 as shown in FIG. It is formed from a pair of one part 12 formed with the notch part 15, and the main-body part 11 which forms the attachment surface 23 for attaching the movable table 4 of the X-axis slide apparatus 2 between the two parts 12. It is said. FIG. 5 is a perspective view of one embodiment of the bracket of the present invention (with a V-shaped notch). A substantially V-shaped notch 15 is formed at the longitudinal end 30 of the bracket 10. Instead of increasing the plate thickness, the bracket 10 has a shape in which the width in the vicinity of the base of the main body 11 is made thicker than the tip 19 of the one part 12. That is, the end portion 19 of the bracket 10 is notched in a V shape to form the notch portion 15, so that the total width of the pair of two portions 12 of the side portions 20 is larger than the width of the main body portion 11. The width is gradually increased from the 30 side toward the main body 11. In this embodiment, for example, the bracket 10 has a plate thickness of 30 mm, a length of 520 mm, a width of 170 mm, a width of the opening 44 of the substantially V-shaped notch 15 is 150 mm, and a substantially V-shaped notch. The radius dimension of the R shape of the tip 30 of the portion 15 is 40 mm, and the distance between the radius centers of both R shapes is 260 mm. Further, the bracket 10 is formed to have the same thickness as that of the main body portion 11 in which the thickness of the one portion 12 is the central portion.

  Further, the notches 15 are formed symmetrically at both end portions 19 of the bracket 10 and do not reach both end surfaces 22 in the width direction of the movable table 4 of the X-axis slide device 2. The movable table 7 of the Y-axis slide device 5 is provided with a θ-axis stage 8 that moves in the rotational direction with respect to the movable table 7.

  Furthermore. The multi-axis stage device 1 has a plurality of (four in FIG. 5) mounting holes for mounting the beds 6 of the Y-axis slide device 5 on both side portions 20 of the one portion 12 and the main body portion 11 of the bracket 10. 14 (first mounting holes) are formed in two rows along the moving direction of the bracket 10. The multi-axis stage device 1 has a plurality of (three in FIG. 5) mounting holes 13 (second mounting holes) for mounting the movable table 4 of the X-axis sliding device 2 on the main body 11 of the bracket 10. 2 holes are formed along the width direction of the bracket 10.

  In this stage apparatus, the bracket 10 is formed such that the length in the moving direction of the one portion 12 of the pair of both end portions 19 is substantially the same as the length in the moving direction of the main body portion 11.

  Further, the overall length of the bracket 10 is longer than the moving stroke of the movable table 7 of the Y-axis slide device 5. Furthermore, the bracket 10 is made of an aluminum alloy, and the surface is covered with an alumite coating layer 25.

  Next, with reference to FIG. 6, another embodiment of a stage apparatus having a bracket according to the present invention will be described. In the multi-axis stage device 1, at least one through hole 24 for reducing the weight of the bracket 10H is formed in the main body 11 of the bracket 10H. Furthermore, the through holes 24 formed in the main body portion 11 of the bracket 10H are formed between the mounting holes 14. In the embodiment, in order to reduce the weight of the body portion 11 at the center in the moving direction, which is the longitudinal direction of the bracket 10H, a circular through hole 24 for lightening is formed. The through hole 24 is located at the center of the main body 11 and is formed at a position where the stress generated by the bending moment acting on the bracket 10H hardly acts, and the bending moment acting on the bracket 10H is affected. It is formed in a region that does not need to consider the width of the bracket 10. Thereby, the bracket 10H can suppress an increase in displacement while reducing the mass by forming the through hole 24.

  Next, referring to FIGS. 9 and 10, the deformation of the bracket 10 when the bracket 10 is incorporated in the multi-axis stage device 1 of the XYθ stage device is evaluated by the finite element method. 9 and 10, the shape of the Y-axis slide device 5 is simplified. The bracket 10 shown in FIGS. 5 and 6 used here has a thickness of 30 mm, and is formed 10 mm to 15 mm thicker than the bracket 60 which is the basic structure shown in FIG. The bracket 60 has a flat plate shape, a thickness of 15 mm, and a length L of 520 mm. Here, the bracket 10 shown in FIG. 5 has a substantially V-shaped notch 15 formed, and when the bracket 60 has the same thickness as the flat plate shape of the bracket 10, the rigidity may be slightly inferior. Since it is clear, in consideration of this point, the thickness of the bracket 60 shown in FIG. 8 is 15 mm and 20 mm, and the thickness of the invention product is 30 mm, and the analysis results are compared. Further, the movable table 7 of the Y-axis slide device 5 is placed at a position in contact with a mechanical stopper 43 provided on the upper surface 45 of the bed 6 at the stroke end. The center position of the movable table 7 in contact with the mechanical stopper 43 is a position overhanging in the movement direction by 100 mm from the movable table 4 of the X-axis slide device 2. The displacement of the movable table 7 of the Y-axis slide device 5 is analyzed under the condition that the mass of 10 kg such as the θ-axis stage 8 (not shown in FIGS. 9 and 10) is evenly distributed. Further, as an analysis condition, it is assumed that the parts in contact with each other are completely fixed.

FIG. 10 shows a state in which the lengths of the brackets 10, 10H, 60 of the XYθ stage device are changed, and the displacement amount of the entire Y-axis slide device 5 and the movable table 7 of the Y-axis slide device 5 is analyzed. It is shown. The displacement magnification shown in FIG. 10 is set to 5000 times. The analysis result is a reference value for determining whether weight reduction and rigidity maintenance are efficiently achieved when a bracket is provided.
The main analysis conditions are as follows.
The analytical mass of the Y-axis slide device 5 is 17.3 kg.
The mass of the movable table 7 of the Y-axis slide device 5 is 4 kg.
The total mass of the θ-axis stage 8 is 6 kg.
The maximum displacement amount δ ₁ at the position A of the entire maximum displacement of the Y-axis slide device 5 is, for example, 5.3 μm when the thickness of the bracket 60 is 15 mm. The maximum displacement amount δ ₂ at the maximum displacement position B is, for example, 4.1 μm. About these results, the results obtained according to the respective conditions are shown in FIGS.

FIG. 11 is a graph showing the relationship between the length L (mm) of the brackets 10, 10 H, 60 and the maximum displacement δ ₁ of the entire Y-axis slide device 5. The maximum displacement δ ₁ of the bed 6 of the Y-axis slide device 5 is, for example, 5.3 μm for the mark ◆. In the graph of FIG. 11, the mark ◆ is the flat bracket 60 shown in FIG. 8 with a plate thickness of 15 mm, and the mark ■ is the flat bracket 60 shown in FIG. 8 with a plate thickness of 20 mm. 5 is a bracket 10 having a notch 15 formed at both ends 19 shown in FIG. 5 and has a plate thickness of 30 mm, and * is a notch 15 and a through-hole at both ends 19 shown in FIG. 24 is a bracket 10H having a thickness of 30 mm. The brackets 10 and 10H of the present invention are substantially equivalent to the flat plate bracket 10 although the displacement δ ₁ of the bed 6 is slightly reduced, and has sufficient rigidity. 15 or the mass of the notch 15 and the through hole 24 contributes to weight reduction.

FIG. 12 is a graph showing the relationship between the lengths of the brackets 10, 10 </ b> H, 60 and the maximum displacement of the movable table 7 of the Y-axis slide device 5. The maximum displacement δ ₂ of the movable table 7 of the Y-axis slide device 5 is, for example, 4.1 μm for the mark ◆. The maximum displacement amount δ ₂ of the movable table 7 hardly changes when the bracket length L is 520 mm or more. When the bracket length L is shortened, an increase in displacement is suppressed as long as it is up to 400 mm. In the graph of FIG. 12, the mark ◆, the mark ■, the mark X, and the mark * are the same as those shown in the graph of FIG.

  FIG. 13 is a graph showing the relationship between the length L of the brackets 10, 10H, 60 and the mass. When the bracket length L is 400 mm, the plate-shaped bracket having a plate thickness of 15 mm is lighter, but when the length is longer than about 440 mm, the brackets 10 and 10H according to the present invention shown in FIGS. 5 and 6 are reversed. Becomes lighter. When the overall length of the bracket is 520 mm, the flat bracket 60 shown in FIG. 7 has a mass of 3.55 kg when the plate thickness is 15 mm, and a mass of 4.74 kg when the plate thickness is 20 mm. 5 and 6 with the substantially V-shaped notch + through hole, the mass is 3.36kg, and the weight can be reduced to 71% of the basic structure product (conventional product) with a plate thickness of 20mm. Yes. In the graph of FIG. 13, the mark ◆, the mark ■, the mark X, and the mark * are equivalent to those shown in the graphs of FIGS.

  FIG. 14 is a graph for confirming the efficiency of suppressing the displacement with a lighter structure of the brackets 10, 10H, and 60. That is, the relationship of “the value of the maximum displacement on the movable table 7 of the Y-axis slide device 5” × “the value of the mass of the bracket” with respect to “the length of the bracket” is shown. In the graph of FIG. 14, the mark ◆, the mark ■, the mark X, and the mark * are the same as those shown in the graphs of FIGS. In FIG. 14, the smaller the value is, the lower the brackets 10, 10H, 60 are lighter and the more efficiently the displacement amount of the movable table 7 is suppressed.

Next, the brackets 10, 10H, 60 in the case where the overall length of the bracket is 520 mm are compared.
The bracket 60 is a flat plate-shaped bracket having a plate thickness of 20 mm.
The bracket 10H is a bracket having a plate thickness of 30 mm, substantially V-shaped notches 15 formed at both ends 19, and a through hole 24 formed in the main body 11.
When the bracket 10H and the bracket 60 were compared, the bracket 60 had a mass of 4.74 kg and a displacement of 4.3 μm. On the other hand, the bracket 10H had a mass of the bracket 10H of 3.36 kg and a displacement of 4.0 μm.
Here, assuming that the bracket 60 is 100%, the bracket 10H has a mass of 71% and a displacement of 93%, which clearly shows that both weight reduction and rigidity can be achieved.
Further, when the bracket 10H and the bracket 60 are compared by the value of “the maximum displacement value on the movable table of the Y-axis slide device” × “the mass of the bracket”, the bracket 10H is 66%. It is clear that the bracket 10H is light and can efficiently suppress the displacement of the movable table 7.

  Next, Table 1 shows the conditions and results of trial calculation showing the effect of reducing the weight of the bracket.

In Table 1, a trial calculation for the bracket uses a bracket 10H in which a substantially V-shaped notch 15 and a through hole 24 are formed as a product of the present invention, and uses a flat plate-shaped bracket 60 as a basic structure product. The time difference required to move a table incorporating these brackets 10H, 60 by a specified number of operation patterns by a linear motor is obtained.
When driving the table, a large thrust is required during acceleration and deceleration, and the linear motor that operates to obtain a large thrust on the table generates heat. If the rated thrust of the linear motor is greater than the effective thrust, heat generation of the linear motor can be suppressed and continuous operation can be achieved. Here, the rated thrust of a linear motor is the limit of use at which the linear motor can continuously perform without causing overheating or seizure. The effective thrust is the average of the required thrust within a certain operating pattern cycle. When examining the operation pattern, the limit acceleration time is obtained from the thrust Fp required to accelerate the table, and the acceleration / deceleration times ta and tb are obtained so that the effective thrust Frms does not become larger than the rated thrust.
The estimated operation pattern is a positioning operation in which one cycle is acceleration, deceleration, and stop, and there is no constant speed range.
FIG. 15 is a diagram showing an operation pattern of the table under the conditions of Table 1, and one cycle is indicated by a symbol t.
Assuming an average stage device operating time, the daily operating time is assumed to be about 10 hours, and this operation pattern is assumed to move 15000 cycles.
Since the basic structure product has a larger loading mass m than the product of the present invention, more heat is generated when the linear motor is driven.
In the trial calculation shown in Table 1, the acceleration / deceleration times ta and tb and the stop time td are adjusted so that the effective thrust Frms of the operation pattern of the product of the present invention and the basic structure product is the same 100N.
Both the brackets 10H and 60 have a total length of 520 mm, the bracket 10H has a plate thickness of 30 mm, and the bracket 60 has a plate thickness of 22.5 mm. The maximum displacement on the movable table is 3 μm, for example.

Here, as a condition for the trial calculation, the X-axis slide device 2 which is the lower axis of the XYθ stage device is driven, and the mass mounted on the movable table 4 of the X-axis slide device 2 at that time is the bracket 10H of the present invention product. incorporating the table is 27.7Kg, incorporating a bracket 60 of the basic structure article table is 2 9.6 kg.
As shown in Table 1, the table incorporating the bracket 10H of the present invention has a higher maximum speed Vmax than the table incorporating the bracket 60 of the basic structure, and the acceleration / deceleration times ta and tb and the stop time td Compared to the bracket 60 of the basic structure product, the time T required for the operation operation of moving the operation pattern of Table 1 and FIG. 15 for 15000 cycles could be shortened by 18 minutes. Therefore, if the bracket 10H of the present invention is applied to an assembly apparatus such as an XYθ stage apparatus, the acceleration / deceleration can be further increased and operation can be performed with high tact time. That is, it can be said that the bracket 10H of the present invention exhibits the characteristics of weight reduction.

  The stage device provided with the bracket according to the present invention is incorporated into various devices such as semiconductor manufacturing devices, precision machines, measuring / inspection devices, medical equipment, various robots, various assembling devices, transfer machines, machine tools, and micromachines. It is preferable.

1 Multi-axis stage device 2 X-axis slide device 3 Bed (first bed)
4 Movable table (first movable table)
5 Y-axis slide device 6 Bed (second bed)
7 Movable table (second movable table)
8 θ-axis stage 10 Bracket 11 Body portion 12 Parts 13 and 14 Mounting hole 15 Notch portion 17 Turntable 19 End portion 20 Side portion 21 Center portion 22 End surface 23 Mounting surface 24 Through hole 25 Anodized coating layers 26 and 29 Lower surface 27, 28 Upper surface 31 Linear motor 39, 41 Track rail 40, 42 Slider L Length of bracket

Claims (11)

An X-axis slide device comprising a first bed and a first movable table slidably provided by a first linear motor relative to the first bed, and the first movable table of the X-axis slide device A stage device comprising a Y-axis slide device composed of a second bed fixed orthogonally and a second movable table slidably provided to the second bed by a second linear motor;
A bracket that is fixed to the first movable table constituting the X-axis slide device and the second bed constituting the Y-axis slide device, and the second bed is fixed to the first movable table. With
The bracket is formed of a substantially rectangular flat plate whose outer shape and cross section are formed so that the length in the moving direction is longer than the width.
The bracket is formed such that a length in the moving direction is shorter than the second bed and longer than the second movable table,
The width of the bracket is shorter than the length of the first movable table in the sliding direction and is substantially the same as the width of the second bed;
The bracket includes a pair of portions each formed by a cut V-shaped cutout portion whose width in the moving direction is reduced from both sides toward the center, and the brackets at the both ends. A stage device comprising a bracket, wherein the stage device is formed from a main body portion that forms an attachment surface for attaching the first movable table of the X-axis slide device between the portions.   The lower surface of the bracket is fixed to the upper surface of the first movable table of the X-axis slide device, and the upper surface of the bracket is fixed to the lower surface of the second bed of the Y-axis slide device. A stage apparatus comprising the bracket according to claim 1.   The X-axis slide device includes a first linear motion guide unit including a first track rail fixed to the first bed and a first slider fixed to the first movable table and reciprocatingly moving on the first track rail. The Y-axis slide device includes a second track rail fixed to the second bed and a second slider fixed to the second movable table and reciprocatingly moving on the second track rail. The stage device having a bracket according to claim 1 or 2, wherein a second linear motion guide unit is interposed. The V-shaped notch is formed symmetrically at the both end portions of the bracket and does not reach both end surfaces in the width direction of the first movable table of the X-axis slide device. A stage apparatus comprising the bracket according to any one of 1 to 3.   The θ-axis stage having a turntable that moves in a rotational direction with respect to the second movable table is disposed on the second movable table of the Y-axis slide device. A stage apparatus comprising the bracket according to claim 4.   A plurality of first mounting holes for mounting the second bed of the Y-axis slide device are provided along the moving direction of the bracket on both side portions of the one portion and the main body portion of the bracket. A stage device provided with the bracket according to claim 1, wherein the stage device is formed.   A plurality of second mounting holes for mounting the first movable table of the X-axis slide device are formed in the main body of the bracket along the width direction of the bracket. The stage apparatus provided with the bracket of any one of Claims 1-6. The main body portion of the bracket has at least one through hole for reducing the weight of the bracket, and the through hole is formed between the second mounting holes formed in the main body portion. stage apparatus provided with a bracket according to claim 7, characterized in that it is. 2. The bracket is formed so that a length in the moving direction of the one portion at the both end portions is substantially the same as a length in the moving direction of the main body portion. A stage apparatus comprising the bracket according to any one of 8 to 8 . Entire length of the bracket, a stage apparatus provided with a bracket according to any one of claims 1 to 9, characterized in that it is moving stroke longer than the formation of the second movable table of said Y-axis slide unit . The stage device provided with the bracket according to any one of claims 1 to 10 , wherein the bracket is made of an aluminum alloy and has a surface covered with an alumite coating layer.

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