Patent Number: 
Section: claims

1. An optical module, comprising:an optical element;a supporting structure supporting the optical element, the supporting structure comprising:a positioning device configured to actively set a position and/or an orientation of the optical element in at least one degree of freedom; anda selectively activatable contacting device comprising a contacting unit having a first contact section,wherein:in an activated state of the contacting device, the first contact section contacts a second contact section of the optical element to exert a contact force on the optical element;in a deactivated state of the contacting device, the first contact section is not in contact with the second contact section;the first contact section has a first contact surface;the second contact section has a second contact surface;the first and second contact surfaces are configured so that, in at least one position and/or orientation set by the positioning device, the first and second contact surfaces define a frictionally locking connection in at least one frictionally locking direction in the activated state of the contacting device; andat least one of the first and second contact surfaces is curved in at least some sections. 2. The optical module of claim 1, wherein at least one of the following holds:a) the contacting device is configured so that, in the activated state of the contacting device, the contacting device exerts an actuation force on the optical element and/or the contacting unit so that the first and second contact sections contact each other;b) the contacting unit is a substantially stationary element so that, in the activated state of the contacting device, the optical element is moved by the actuation force; andc) the optical element is substantially stationary in terms of its position and/or orientation set by the positioning device, the contacting unit is moved by the actuation force when the contacting unit is in its activated state, and the contacting unit is a bistable unit that is in a stable state when the contacting unit is in its activated state or its inactivated state. 3. An optical module, comprising:an optical element;a supporting structure supporting the optical element, the supporting structure comprising:a positioning device configured to actively set a position and/or an orientation of the optical element in at least one degree of freedom; anda selectively activatable contacting device comprising a contacting unit having a first contact section,wherein:in an activated state of the contacting device, the first contact section contacts a second contact section of the optical element to exert a contact force on the optical element;in a deactivated state of the contacting device, the first contact section is not in contact with the second contact sectionthe first contact section has first and second surface;the first and second contact surfaces are structured complementarily so that in at least one position and/or orientation set by the positioning device, the first and second contact surfaces define a positively locking connection in at least one positively locking direction in the activated state of the contacting device; andat least one of the first and second contact surfaces has an at least section-wise polygonal sectional contour in a sectional plane containing a surface normal to the contact surface. 4. The optical module of claim 3, wherein in a plurality of discrete positions and/or orientations set by the positioning device, the first and second contact surfaces define a positively locking connection in at least one positively locking direction in the activated state of the contacting device. 5. The optical module of claim 3, wherein:at least one of the first and second contact sections is a structurable contact section at least in section-wise comprising a structurable material which is hardenable after structuring;the other of the first and second contact sections is a structuring contact section at least in section-wise has a stiffness sufficient for the defined structuring of the structurable contact section;the first and second contact sections are configured so that the structurable contact section is structured in its structurable state via the structuring contact section to produce the complementarily structured first and second contact surfaces and having been hardened after this structuring;the structurable and hardenable material having a gel-like or waxy consistency in its structurable state; andthe structurable and hardenable material in its structurable state has a dimensional stability which suffices to obtain, after an influence of an acceleration corresponding to at least 100% of the acceleration due to gravity and a dimensional fidelity with respect to the structuring contact section of at least 80%; andthe structurable and hardenable material comprise at least one material selected from the group consisting of a photoresist material, a multi-component adhesive, and a powder coating material. 6. The optical module of claim 5, wherein:the first contact section is a structurable contact section at least in section-wise comprising a structurable material which is hardenable after structuring; andthe second contact sectionsis a structuring contact section at least in section-wise having a stiffness sufficient for the defined structuring of the structurable contact section. 7. The optical module of claim 1, wherein:the contacting device is configured so that, in the activated state of the contacting device, in the frictionally locking direction, a settable frictional force acts as an adjusting resistance against a positioning force of the positioning device;the adjusting resistance is reduced in a setting state of the activated state of the contacting device so that that the positioning force of the positioning device suffices to set the optical element in the at least one degree of freedom with a frictional relative movement between the first and second contact surfaces against the adjusting resistance; andthe adjusting resistance is increased in a fixing state of the activated state of the contacting device relative to the setting state so that a maximum positioning force of the positioning device does not suffice to perform a setting of the optical element in the at least one degree of freedom against the adjusting resistance. 8. An optical module, comprising:an optical element;a supporting structure supporting the optical element, the supporting structure comprising:a positioning device configured to actively set a position and/or an orientation of the optical element in at least one degree of freedom; anda selectively activatable contacting device comprising a contacting unit having a first contact section,wherein:in an activated state of the contacting device, the first contact section contacts a second contact section of the optical element to exert a contact force on the optical element;in a deactivated state of the contacting device, the first contact section is not in contact with the second contact section; andat least one of the following holds:the optical element has a first resonant frequency of from one Hz to 2,000 Hz, and the contacting unit comprises a damping section which has a vibration-damping effect in the range of the first resonant frequency; andthe optical element is supported on the supporting structure via a supporting device, the supporting device has a second resonant frequency of from one Hz to 2,000 Hz, and the contacting unit comprises a damping section which has a vibration-damping effect in the range the second resonant frequency. 9. An optical module, comprising:an optical element;a supporting structure supporting the optical element, the supporting structure comprising:a positioning device configured to actively set a position and/or an orientation of the optical element in at least one degree of freedom; anda selectively activatable contacting device comprising a contacting unit having a first contact section,wherein:in an activated state of the contacting device, the first contact section contacts a second contact section of the optical element to exert a contact force on the optical element;in a deactivated state of the contacting device, the first contact section is not in contact with the second contact section;the optical element comprises an element body having a projection;the element body comprises an optically effective surface;the projection is arranged on a side of the element body facing away from the optically effective surface;the second contact section is arranged at an end of the projection which faces away from the element body;the contacting device comprises an actuation unit configured so that, in the activated state of the contacting device, the contacting device has an effect that an actuation force is exerted on the second contact section so that the first and second contact sections contact each other;the positioning device is configured to exert the positioning force on the second contact section; andthe positioning device is configured to operate according to an electrostatic principle of operation. 10. The optical module of claim 9, wherein the actuation unit is configured to operate according to an electrostatic principle of operation. 11. An optical module, comprising:an optical element;a supporting structure supporting the optical element, the supporting structure comprising:a positioning device configured to actively set a position and/or an orientation of the optical element in at least one degree of freedom; anda selectively activatable contacting device comprising a contacting unit having a first contact section,wherein:in an activated state of the contacting device, the first contact section contacts a second contact section of the optical element to exert a contact force on the optical element;in a deactivated state of the contacting device, the first contact section is not in contact with the second contact section;the optical module comprises an active release device configured to provide a release force to support release of the contact between the first and second contact sections after deactivation of the contacting device;the optical element is supported on the supporting structure via a supporting device which is elastically deformed in the activated state of the contacting device so that the supporting device exerts a second release force on the optical element which supports the release of the contact between the first and second contact sections;the contacting unit has a release section which, in the activated state of the contacting device, is elastically deformed so that the contacting unit exerts a third release force on the first contact section which supports the release of the contact between the first and second contact sections; andthe release device is configured to introduce vibrational energy into the optical element and/or the contacting unit. 12. An optical imaging device, comprising:an illumination device configured to illuminate a projection pattern of a mask; anda projection device configured to project the illuminated projection pattern of the mask onto a substrate,wherein:the illumination device and/or the projection device comprises an optical module according to claim 1; andthe optical imaging device is a microlithography optical imaging device. 13. A method of using a microlithography optical imaging device comprising an illumination device and a projection device, the method comprising:using the illumination device to illuminate a projection pattern of a mask; andusing a projection device to project the illuminated projection pattern of the mask onto a substrate,wherein the illumination device and/or the projection device comprises an optical module according to claim 1. 14. A method, comprising:providing an optical module according to claim 5;structuring the structurable contact section via the structuring contact section to produce the complementarily structured first and second contact surfaces; andafter structuring the structurable contact section, hardening the structurable contact section. 15. The method of claim 14, wherein:the first contact section is a structurable contact section at least in section-wise comprising a structurable material which is hardenable after structuring; andthe second contact sections is a structuring contact section at least in section-wise having a stiffness sufficient for the defined structuring of the structurable contact section. 16. The method of claim 14, wherein at least one of the following holds:the structurable and hardenable material having a gel-like or waxy consistency in its structurable state; andthe structurable and hardenable material in its structurable state has a dimensional stability which suffices to obtain, after an influence of an acceleration corresponding to at least 100% of the acceleration due to gravity and a dimensional fidelity with respect to the structuring contact section of at least 80%; andthe structurable and hardenable material comprise at least one material selected from the group consisting of a photoresist material, a multi-component adhesive, and a powder coating material. 17. The optical module of claim 1, wherein at least one of the first and second contact surfaces is planar in at least some sections. 18. A mirror, comprising:an optical module according to claim 1,wherein the mirror is a facet mirror. 19. The mirror of claim 18, wherein at least one of the following holds:the facet mirror comprises a facet element with an optically effective surface with an area 0.05 mm2 to 2.0 mm2; andthe facet mirror comprises 10,000 to 1,000,000 facet elements. 20. A mirror, comprising:an optical module according to claim 3,wherein the mirror is a facet mirror. 21. The mirror of claim 20, wherein at least one of the following holds:the facet mirror comprises a facet element with an optically effective surface with an area 0.05 mm2 to 2.0 mm2; andthe facet mirror comprises 10,000 to 1,000,000 facet elements. 22. A mirror, comprising:an optical module according to claim 8,wherein the mirror is a facet mirror. 23. The mirror of claim 22, wherein at least one of the following holds:the facet mirror comprises a facet element with an optically effective surface with an area 0.05 mm2 to 2.0 mm2; andthe facet mirror comprises 10,000 to 1,000,000 facet elements. 24. A mirror, comprising:an optical module according to claim 9,wherein the mirror is a facet mirror. 25. The mirror of claim 24, wherein at least one of the following holds:the facet mirror comprises a facet element with an optically effective surface with an area 0.05 mm2 to 2.0 mm2; andthe facet mirror comprises 10,000 to 1,000,000 facet elements. 26. A mirror, comprising:an optical module according to claim 11,wherein the mirror is a facet mirror. 27. The mirror of claim 26, wherein at least one of the following holds:the facet mirror comprises a facet element with an optically effective surface with an area 0.05 mm2 to 2.0 mm2; andthe facet mirror comprises 10,000 to 1,000,000 facet elements. 28. An optical module, comprising:an optical element;a supporting structure supporting the optical element, the supporting structure comprising:a positioning device configured to actively set a position and/or an orientation of the optical element in at least one degree of freedom; anda selectively activatable contacting device comprising a contacting unit having a first contact section,wherein:in an activated state of the contacting device, the first contact section contacts a second contact section of the optical element to exert a contact force on the optical element;in a deactivated state of the contacting device, the first contact section is not in contact with the second contact section;the optical element is substantially stationary in terms of its position and/or orientation as set by the positioning device; andthe contacting unit is moved by the actuation force when the contacting unit is in its activated state. 29. The optical module of claim 28, wherein the contacting unit is a bistable unit that is in a stable state when the contacting unit is in its activated state or its inactivated state. 30. A mirror, comprising:an optical module according to claim 28,wherein the mirror is a facet mirror. 31. The mirror of claim 30, wherein at least one of the following holds:the facet mirror comprises a facet element with an optically effective surface with an area 0.05 mm2 to 2.0 mm2; andthe facet mirror comprises 10,000 to 1,000,000 facet elements.