Electromechanically actuatable brake and method for operating an electromechanically actuatable brake

The invention claimed is: 1. An electromechanically actuatable brake, comprising: an electrically actuatable actuator for applying the brake in an application direction, the actuator comprising: a spindle; and an application element comprising a piston, the application element coupled to the spindle; wherein the actuator converts a rotary motion of the spindle into a translational motion of the application element for applying the brake; an electric motor, wherein the spindle is driven by the electric motor; a bracing element operatively coupled to the spindle; a mechanical store in the form of a first spring element for storing energy by twisting the first spring element, the first spring element having a first end coupled to the spindle and a second end coupled to the bracing element such that the bracing element is coupled to the spindle via the store; wherein the store takes up energy during rotation of the spindle in the application direction, by which energy the spindle is rotatably biased against the application direction in a currentless state of the electric motor, whereby the brake is released in response to rotation of the spindle against the application direction; wherein the bracing element is mounted rotatably and can be fixed in a plurality of discretely or continuously arranged fixing positions; and a fixing mechanism which can be actuated by a triggering element connected to the spindle, actuation of which fixing mechanism leads to rotation of the bracing element in the application direction and to fixing thereof in an adjacent fixing position; wherein the actuation of the fixing mechanism rotates the bracing element in the application direction during the actuation of the fixing mechanism. 2. The brake as claimed in claim 1 , wherein the first spring element is in the form of a spiral spring. 3. The brake as claimed in claim 1 , wherein the bracing element is in the form of a disk. 4. The brake as claimed in claim 1 , wherein the store is coupled to the spindle by the triggering element. 5. The brake as claimed in claim 1 , wherein the fixing mechanism includes a latching element which is connected to the bracing element and has a catch, which latching element latches in an adjacent latching position of a latching contour when actuated by the catch. 6. The brake as claimed in claim 1 , wherein the fixing mechanism has a spring hook which is connected to the bracing element and engages in a latching contour. 7. The brake as claimed in claim 1 , wherein the fixing mechanism has a number of ball catches at least one of which at a time, in a fixing position, engages in a latching position of a latching contour connected to or integrated with the bracing element. 8. The brake as claimed in claim 1 , wherein the fixing mechanism has a second spring which presses itself into a surrounding fixing contour and has on its one end a loop for receiving the triggering element. 9. The brake as claimed in claim 8 , wherein the second spring element is in the form of a spiral spring or loop spring. 10. The brake as claimed in claim 8 , wherein a friction lining is provided between the second spring and the surrounding fixing contour. 11. The brake as claimed in claim 8 , wherein the spring element is in the form of a spiral spring and wherein the spiral spring and the second spring are produced as an integral component. 12. The brake as claimed in claim 1 , wherein the energy taken up by the store is approximately the same at at least two different fixing positions of the bracing element. 13. The brake as claimed in claim 1 , wherein the spindle can rotate to a position beyond a predefined application angle in order to apply the brake, and the energy taken up by the store is approximately the same at this position as the predefined application angle, such that the energy taken up by the store does not substantially increase when rotation beyond the predefined application angle is necessary to apply the brake. 14. An electromechanically actuatable brake, comprising: an electrically actuatable actuator for applying the brake in an application direction, the actuator comprising: a spindle; and an application element comprising a piston, the application element coupled to the spindle; wherein the actuator converts a rotary motion of the spindle into a translational motion of the application element for applying the brake; an electric motor, wherein the spindle is driven by the electric motor; a bracing element operatively coupled to the spindle; a mechanical store in the form of a first spring element for storing energy by twisting the first spring element, the first spring element having a first end coupled to the spindle and a second end coupled to the bracing element such that the bracing element is coupled to the spindle via the store; wherein the store takes up energy during rotation of the spindle in the application direction, by which energy the spindle is rotatably biased against the application direction in a currentless state of the electric motor, whereby the brake is released in response to rotation of the spindle against the application direction; wherein the bracing element is mounted rotatably and can be fixed in a plurality of discretely or continuously arranged fixing positions; and a fixing mechanism which can be actuated by a triggering element connected to the spindle, actuation of which fixing mechanism leads to rotation of the bracing element in the application direction and to fixing thereof in an adjacent fixing position; wherein the triggering element is in the form of a pin. 15. The brake as claimed in claim 14 , wherein the bracing element has a stop. 16. A method for operating an electromechanically actuatable brake, the method comprising: providing an electrically actuatable actuator for applying the brake, the actuator including a spindle operatively coupled to an application element comprising a piston; converting a rotary motion of the spindle into a translational motion of the application element; driving the spindle by an electric motor; rotating the spindle through a predefined readiness angle in an application direction by the electric motor in order to place the brake in a readiness state; and rotating the spindle further in the application direction through a predefined application angle in order to apply the brake; wherein the brake includes a triggering element connected to the spindle and a stop fastened to a bracing element, wherein, in order to exchange brake pads of the brake, the method further comprises rotating the spindle against the application direction, pressing the triggering element against the stop, and, rotating the spindle and the bracing element synchronously with one another; wherein the triggering element translates in a rotational direction relative to the stop. 17. The method as claimed in claim 16 , further comprising storing a predetermined energy amount in a spring in response to rotating the spindle through the predefined application angle. 18. The method as claimed in claim 17 , further comprising rotating the spindle further in the application direction beyond the predefined application angle in order to apply the brake, wherein the predetermined energy amount in the spring remains approximately the same in response to the further rotation.