Tensioner and method for preloading a bearing

What is claimed is: 1. A tensioner for preloading a bearing, the bearing including a first bearing ring and a second bearing ring and being configured to transmit a preload force in a radial direction and/or in an axial direction between the first bearing ring and the second bearing ring, the tensioner comprising: a component coupled to the first bearing ring; a support element for supporting the component relative to the second bearing ring such that a closed force flow arises from the first bearing ring via the component and the support element to the second bearing ring; and a sleeve disposed in an axially displaceable manner between the first bearing ring and the component, the sleeve being configured to change the preload force in response to an axial displacement of the sleeve with respect to the component; and wherein the sleeve includes a radially extending collar in contact with an axial face of the first bearing ring, and wherein the sleeve includes an axial gradation configured to at least partially define, with the component, a volume such that a buildup of a pressure by a fluid in the volume displaces the sleeve and the first bearing ring in the axial direction relative to the component. 2. The tensioner according to claim 1 , wherein the first bearing ring is an outer ring and the second bearing ring is an inner ring, and wherein the component comprises a stationary housing. 3. The tensioner according to claim 1 , wherein the sleeve abuts on the first bearing ring with a contact surface substantially parallel to the axial direction, and the sleeve further includes a conical surface facing away from the contact surface, the conical surface abutting on a countersurface of the component. 4. The tensioner according to claim 1 , wherein the sleeve and the component delimit an intermediate space for receiving an adjusting element, and wherein the adjusting element is introduced in the intermediate space and is configured to fix an axial position of the sleeve with respect to the component. 5. The tensioner according to claim 4 , wherein the intermediate space is a bore extending parallel to the axial direction, the bore completely penetrating the sleeve and being aligned with a bore in the component, and wherein the adjusting element is a screw. 6. The tensioner according to claim 1 , wherein the bearing has an outer diameter of at least 1500 millimeters. 7. The tensioner according to claim 1 , further comprising: a second bearing including an inner ring and an outer ring; and a common shaft on which the bearing and the second bearing are disposed, wherein a force direction of the preload force of the first bearing ring on the second bearing ring and a further force direction of a preload force of the outer ring on the inner ring extend away from each other and towards the common shaft. 8. A wind turbine including a tensioner according to claim 1 . 9. A tensioner for preloading a bearing, the bearing including a first bearing ring and a second bearing ring and being configured to transmit a preload force in a radial direction and/or in an axial direction between the first bearing ring and the second bearing ring, the tensioner comprising: a component coupled to the first bearing ring; a support element for supporting the component relative to the second bearing ring such that a closed force flow arises from the first bearing ring via the component and the support element to the second bearing ring; and a sleeve disposed in an axially displaceable manner between the first bearing ring and the component, the sleeve being configured to change the preload force in response to an axial displacement of the sleeve with respect to the component; and wherein the first bearing ring is an outer ring and the second bearing ring is an inner ring, and wherein the component comprises a stationary housing, wherein the sleeve includes a radially extending collar in contact with an axial face of the first bearing ring, and wherein the sleeve includes an axial gradation configured to at least partially define, with the component, a volume such that a buildup of a pressure by a fluid in the volume displaces the sleeve and the first bearing ring in the axial direction relative to the component, wherein the sleeve and the component delimit an intermediate space for receiving an adjusting element, and wherein the adjusting element is introduced in the intermediate space and is configured to fix an axial position of the sleeve with respect to the component, wherein the intermediate space is a bore extending parallel to the axial direction, the bore completely penetrating the sleeve and being aligned with a bore in the component, and wherein the adjusting element is a screw, and wherein the bearing has an outer diameter of at least 1500 millimeters. 10. A tensioner for preloading a bearing, the bearing including an outer bearing ring and an inner bearing ring and being configured to transmit a preload force in a radial direction and in an axial direction between the outer bearing ring and the inner bearing ring, the tensioner comprising: a component coupled to the first bearing ring; a support element for supporting the component relative to the second bearing ring; axially displaceable means for changing the preload force; wherein the axially displaceable means comprises a sleeve mounted on the outer bearing ring; and wherein the sleeve includes a radially extending collar in contact with an axial face of the first bearing ring, and an axial gradation configured to at least partially define, with the component, a volume such that a buildup of a pressure by a fluid in the volume displaces the sleeve and the first bearing ring in the axial direction relative to the component. 11. The tensioner according to claim 10 , including a fixing means for fixing the sleeve relative to the component. 12. The tensioner according to claim 10 , wherein the sleeve abuts on the first bearing ring with a contact surface substantially parallel to the axial direction, and the sleeve further includes a conical surface facing away from the contact surface, the conical surface abutting on the component. 13. The tensioner according to claim 10 , wherein the bearing has an outer diameter of at least 1500 millimeters.