Claims
- 1. A method of calibrating a wafer chucking surface, comprising:
providing a calibration jig having a rough calibration surface with a first pin extending therefrom, and a fine calibration surface with a second pin extending therefrom, the first and second surfaces being coplanar; providing a wafer chucking surface having one or more openings adapted to receive the first and second pins, wherein the first pin is received with a looser tolerance than the second pin; mounting the wafer chucking surface via a mounting assembly having at least one fixable rotary joint and at least one fixable planar joint; placing the calibration jig on a wafer exchange surface with the rough calibration surface facing the wafer chucking surface; bringing the wafer chucking surface into flat contact with the calibration jig placed on the wafer exchange surface, such that the wafer chucking surface and the wafer exchange surface are leveled relative to each other, and such that the first pin is received by one of the one or more openings on the wafer chucking surface; fixing a rotary joint of the wafer chucking surface; removing the contact between the wafer chucking surface and the calibration jig; placing the calibration jig on the wafer exchange surface with the fine calibration surface facing the wafer chucking surface; bringing the wafer chucking surface into flat contact with the calibration jig placed on the wafer exchange surface, such that the second pin is received by one of the one or more openings on the wafer chucking surface; and fixing a planar joint of the wafer chucking surface.
- 2. The method of claim 1 wherein placing the calibration jig on the wafer exchange surface comprises coupling the jig to the wafer exchange surface such that it is centered thereon.
- 3. The method of claim 1 wherein bringing the wafer chucking surface into flat contact with the calibration jig such that the first pin is received by one of the one or more openings on the wafer chucking surface comprises allowing the wafer chucking surface to rotate via the rotary joint.
- 4. The method of claim 1 wherein bringing the wafer chucking surface into flat contact with the calibration jig such that the second pin is received by one of the one or more openings on the wafer chucking surface comprises allowing the wafer chucking surface to translate via the planar joint.
- 5. The method of claim 1 wherein the rough calibration pin and the fine calibration pin extend into the same opening.
- 6. A method of calibrating a wafer chucking surface relative to a wafer exchange surface, comprising:
providing a wafer chucking surface; providing a wafer exchange surface opposite the wafer chucking surface; mounting at least one of the wafer chucking surface and the wafer exchange surface via a fixable rotary joint; mounting at least one of the wafer chucking surface and the wafer exchange surface via a fixable planar joint; coupling a calibration jig to a first one of the wafer chucking surface and the wafer exchange surface; bringing the wafer chucking surface and the wafer exchange surface into flat contact with opposite faces of the calibration jig such that the wafer chucking surface and wafer exchange surface are leveled relative to each other, wherein the rough calibration pin extends from the calibration jig into a corresponding opening on a second one of the wafer chucking surface or the wafer exchange surface and wherein the calibration jig and the second one of the wafer chucking surface and the wafer exchange surface are adapted so as to be roughly concentric when the rough calibration pin extends into the opening; fixing the rotary movement of the wafer chucking surface and/or the wafer exchange surface such that the wafer chucking surface and the wafer exchange surface are leveled relative to a each other; reversing the position of the calibration jig; bringing the wafer chucking surface and the wafer exchange surface into flat contact with opposite faces of the reversed calibration jig, wherein the fine calibration pin extends from the calibration jig into a corresponding opening on the second one of the wafer chucking surface or the wafer exchange surface and wherein the calibration jig and the second one of the wafer chucking surface and the wafer exchange surface are adapted so as to be finely concentric when the fine calibration pin extends into the opening.
- 7. The method of claim 6 wherein coupling the calibration jig to a first one of the wafer chucking surface and the wafer exchange surface comprises coupling the jig to the wafer exchange surface or the wafer chucking surface such that the jig is centered thereon.
- 8. The method of claim 6 wherein the rough calibration pin and the fine calibration pin extend into the same opening.
- 9. The method of claim 6 wherein bringing the wafer chucking surface and the wafer exchange surface into flat contact with the calibration jig such that the rough calibration pin is received by one of the one or more openings on the wafer chucking surface or the wafer exchange surface comprises allowing the wafer chucking surface to rotate via the rotary joint.
- 10. The method of claim 6 wherein bringing the wafer chucking surface and the wafer exchange surface into flat contact with the calibration jig such that the fine calibration pin is received by one of the one or more openings on the wafer chucking surface or the wafer exchange surface comprises allowing the wafer chucking surface to translate via the planar joint.
- 11. A method of calibrating a wafer chucking surface relative to a wafer exchange surface, comprising:
providing a wafer chucking surface; providing a wafer exchange surface opposite the wafer chucking surface; mounting at least one of the wafer chucking surface and the wafer exchange surface via a fixable rotary joint; mounting at least one of the wafer chucking surface and the wafer exchange surface via a fixable planar joint; coupling a first calibration jig to a first one of the wafer chucking surface and the wafer exchange surface; bringing the wafer chucking surface and the wafer exchange surface/into flat contact with opposite faces of the first calibration jig such that the wafer chucking surface and wafer exchange surface are leveled relative to each other, wherein a rough calibration pin extends from the first calibration jig into a corresponding opening on a second one of the wafer chucking surface or the wafer exchange surface and wherein the first calibration jig and the second one of the wafer chucking surface and the wafer exchange surface are adapted so as to be roughly concentric when the rough calibration pin extends into the opening; fixing the rotary movement of the wafer chucking surface and/or the wafer exchange surface such that the wafer chucking surface and the wafer exchange surface are leveled relative to a each other; placing a second calibration jig between the wafer chucking surface and the wafer exchange surface, wherein the second calibration jig couples to a first one of wafer chucking surface or the wafer exchange surface so as to be concentric therewith; bringing the wafer chucking surface and the wafer exchange surface into flat contact with opposite faces of the second calibration jig, wherein a fine calibration pin extends from the second calibration jig into a corresponding opening on the second one of the wafer chucking surface or the wafer exchange surface and wherein the second calibration jig and the second one of the wafer chucking surface and the wafer exchange surface are adapted so as to be finely concentric when the fine calibration pin extends into the opening.
- 12. The method of claim 11 wherein coupling the calibration jig to a first one of the wafer chucking surface and the wafer exchange surface comprises coupling the jig to the wafer exchange surface or the wafer chucking surface such that the jig is centered thereon.
- 13. The method of claim 11 wherein the rough calibration pin and the fine calibration pin extend into the same opening.
- 14. The method of claim 11 wherein bringing the wafer chucking surface into flat contact with the first calibration jig such that the rough calibration pin is received by one of the one or more openings on the wafer chucking surface comprises allowing the wafer chucking surface to rotate via the rotary joint.
- 15. The method of claim 11 wherein bringing the wafer chucking surface into flat contact with the second calibration jig such that the fine calibration pin is received by one of the one or more openings on the wafer chucking surface comprises allowing the wafer chucking surface to translate via the planar joint.
- 16. A wafer chuck comprising:
a wafer chucking surface; at least one fixable rotary joint coupled to the wafer chucking surface so as to allow the wafer chucking surface to rotate so as to selectively adjust and fix the pitch of the wafer chucking surface; and at least one planar joint coupled to the wafer chucking surface so as to selectively allow the wafer chucking surface to translate and to fix the position of the wafer chucking surface so as to center the wafer chucking surface with respect to another surface.
- 17. An assembly comprising a chamber having:
a wafer chucking surface; a wafer exchange surface, opposite the wafer chucking surface; at least one fixable rotary joint coupled to the wafer chucking surface so as to allow the wafer chucking surface to rotate so as to selectively adjust and fix the pitch of the wafer chucking surface so as to level the wafer chucking surface with respect to the wafer exchange surface; and at least one planar joint coupled to the wafer chucking surface so as to selectively allow the wafer chucking surface to translate and to fix the position of the wafer chucking surface so as to center the wafer chucking surface with respect to the wafer exchange surface.
- 18. The apparatus of claim 17 further comprising:
a plate adapted to couple to a first one of the wafer exchange surface or the wafer chucking surface, the plate having a first planar surface and a second planar surface, a first calibration pin extending from the first planar surface, and a second calibration pin extending from the second planar surface, wherein a second one of the wafer exchange surface and the wafer chucking surface has an opening adapted to receive the first pin and the second pin, wherein the wafer chucking surface, the wafer exchange surface and the calibration jig are adapted such that the wafer exchange surface and the wafer chucking surface are roughly concentric when the first pin extends into the opening and such that the wafer chucking surface and the wafer exchange surface are finely concentric when the second calibration pin extends into the opening.
- 19. The apparatus of claim 17 further comprising:
a plate adapted to couple to a first one of the wafer chucking surface and the wafer exchange surface, the plate having a first planar surface and a first calibration pin extending from the first planar surface, wherein a second one of the wafer exchange surface and the wafer chucking surface has an opening adapted to receive the first pin, and wherein the wafer chucking surface, the wafer exchange surface and the calibration jig are adapted such that the wafer exchange surface and the wafer chucking surface are at least roughly concentric when the first pin extends into the opening of the wafer chucking surface.
- 20. The apparatus of claim 17 further comprising:
a plate adapted to couple concentrically to the water exchange surface, the plate having a first planar surface and a second planar surface, a first calibration pin extending from the first planar surface, and a second calibration pin extending from the second planar surface, wherein the wafer chucking surface has a first opening adapted to receive the first pin and a second opening adapted to receive the second pin, wherein the wafer chucking surface and the calibration jig are adapted such that the wafer exchange surface and the wafer chucking surface are roughly concentric when the first pin extends into the first opening of the wafer chucking surface and such that the wafer chucking surface and the wafer exchange surface are finely concentric when the second calibration pin extends into the second opening of the wafer chucking surface.
- 21. The apparatus of claim 17 wherein the first and second calibration pins extend perpendicularly from the respective planar surface.
- 22. An assembly comprising:
a wafer chucking surface; a wafer exchange surface, opposite the wafer chucking surface; at least one fixable rotary joint coupled to the wafer exchange surface so as to allow the wafer exchange surface to rotate so as to selectively adjust and fix the pitch of the wafer exchange surface so as to level the wafer exchange surface with respect to the wafer chucking surface; at least one planar joint coupled to the wafer exchange surface so as to selectively allow the wafer exchange surface to translate and to fix the position of the wafer exchange surface so as to center the wafer exchange surface with respect to the wafer chucking surface.
- 23. The assembly of claim 22 further comprising:
a plate adapted to couple to a first one of the wafer exchange surface or the wafer chucking surface, the plate having a first planar surface and a second planar surface, a first calibration pin extending from the first planar surface, and a second calibration pin extending from the second planar surface, wherein a second one of the wafer exchange surface and the wafer chucking surface has an opening adapted to receive the first pin and the second pin, wherein the wafer chucking surface, the wafer exchange surface and the calibration jig are adapted such that the wafer exchange surface and the wafer chucking surface are roughly concentric when the first pin extends into the opening and such that the wafer chucking surface and the wafer exchange surface are finely concentric when the second calibration pin extends into the opening.
- 24. The apparatus of claim 22 further comprising:
a plate adapted to couple to a first one of the wafer chucking surface and the wafer exchange surface, the plate having a first planar surface and a first calibration pin extending from the first planar surface, wherein a second one of the wafer exchange surface and the wafer chucking surface has an opening adapted to receive the first pin, and wherein the wafer chucking surface, the wafer exchange surface and the calibration jig are adapted such that the wafer exchange surface and the wafer chucking surface are at least roughly concentric when the first pin extends into the opening of the wafer chucking surface.
- 25. The apparatus of claim 22 further comprising:
a plate adapted to couple concentrically to the wafer exchange surface, the plate having a first planar surface and a second planar surface, a first calibration pin extending from the first planar surface, and a second calibration pin extending from the second planar surface, wherein the wafer chucking surface has a first opening adapted to receive the first pin and a second opening adapted to receive the second pin, wherein the wafer chucking surface and the calibration jig are adapted such that the wafer exchange surface and the wafer chucking surface are roughly concentric when the first pin extends into the first opening of the wafer chucking surface and such that the wafer chucking surface and the wafer exchange surface are finely concentric when the second calibration pin extends into the second opening of the wafer chucking surface.
- 26. The apparatus of claim 22 wherein the first and second calibration pins extend perpendicularly from the respective planar surface.
Parent Case Info
[0001] This application claims priority from U.S. Provisional Patent Application Serial No. 60/312,338, filed Aug. 14, 2001, which is hereby incorporated by reference herein in its entirety.
Provisional Applications (1)
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Number |
Date |
Country |
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60312338 |
Aug 2001 |
US |