Method for controlling a lifting device

What is claimed: 1. A method for controlling a lifting device for moving a load along a trajectory from a start point to an end point, moving the load along a first motion axis and along a second motion axis, wherein the start point and the end point of the trajectory and prohibited zones, which are avoided during motion of the load, are established, calculating a geometrical path or rounded geometrical path or smooth geometrical path, wherein kinematic and geometric limit values of the lifting device are predetermined, calculating, based on the geometric path or rounded geometric path or smooth geometric path, a dynamic path or rounded dynamic path or smooth dynamic path, which provides time information of motion of the load along the geometric path or rounded geometric path or smooth geometric path, and combining the geometric path or rounded geometric path or smooth geometric path and the dynamic path or rounded dynamic path or smooth dynamic path for producing the trajectory. 2. The method according to claim 1 , wherein a maximal speed and a maximal acceleration of a bearing structure of the lifting device, a maximal speed and a maximal acceleration of a travelling element of the lifting device and a maximal speed and a maximal acceleration of a lift drive of the lifting device are established as the kinematic limit values of the lifting device, and a maximal angle of deflection of the load receiver element is established as the geometric limit value. 3. The method according to claim 1 , wherein for producing the rounded dynamic path, the dynamic path is rounded by a forward-backward filtering method. 4. The method according to claim 1 , wherein the load is moved along a third motion axis of the lifting device, wherein the start point and the end point of the trajectory are established in a motion space spanned by the first, second and third motion axes of the lifting device, wherein the prohibited zones are established in the motion space, wherein the geometric path is calculated in the motion space, wherein based on the geometric path, the dynamic path is calculated, and wherein the geometric path and the dynamic path for producing the trajectory in the motion space are combined. 5. The method according to claim 4 , wherein motion space spanned by the first, second and third motion axes is a second plane in which the start point and the end point are established, wherein the prohibited zones are established in the second plane, wherein the geometric path is calculated in the second plane, wherein based on the geometric path, the dynamic path is calculated, and wherein the geometric path and the dynamic path for producing the trajectory in the motion space are combined in the second plane. 6. The method according to claim 1 , wherein for producing the geometric path, the start point is connected to the end point by straight lines via supporting points, wherein the supporting points are derived from the prohibited zones. 7. The method according to claim 6 , wherein for producing the rounded geometric path, the geometric path at the supporting points is rounded by circular segments or clothoids or Bezier curves. 8. The method according to claim 7 , wherein for producing the smooth dynamic path, the rounded dynamic path and/or for producing the smooth geometric path, the rounded geometric path is smoothed by B-splines. 9. The method according to claim 1 , wherein the start point and the end point of the trajectory are established in a first plane, which is spanned by the first motion axis and the second motion axis, wherein the prohibited zones are established in the first plane, wherein the geometric path is calculated in the first plane, wherein, based on the geometric path, the dynamic path is calculated, and wherein the geometric path and the dynamic path are combined for producing the trajectory in the first plane. 10. The method according to claim 9 , wherein a working region of the lifting device in the first plane is established, and testing whether the start point, the end point, and the prohibited zones lie within the working region and whether a trajectory is producible between the start point and end point. 11. The method according to claim 9 , wherein a working region of the lifting device in the second plane is established, and testing whether the start point, the end point, and the prohibited zones lie within the working region and whether a trajectory is producible between the start point and end point. 12. The method according to claim 9 , wherein a working region of the lifting device in the motion space is established, and testing whether the start point, the end point, and the prohibited zones lie within the working region and whether a trajectory is producible between the start point and end point. 13. A lifting device having at least two motion axes for moving a load along a trajectory from a start point to an end point with a travelling element, comprising: a load receiver element, which is configured for receiving the load, is connected by at least one retaining element to the travelling element; a lift drive for lifting the load receiver element, wherein the travelling element is movable along a first motion axis and the load receiver element is movable by the lift drive along a second motion axis; and a computing unit is configured to calculate the trajectory between the start point and the end point and defined prohibited zones to be avoided by the load during motion of the load, wherein the computing unit is further configured to: calculate a geometric path or rounded geometric path or smooth geometric path between the start point and the end point, calculate, based on the geometric path or rounded geometric path or smooth geometric path with reference to predetermined kinematic and geometric limit values of the lifting device, a dynamic path or rounded dynamic path or smooth dynamic path, and combine the geometric path or rounded geometric path or smooth geometric path and the dynamic path or rounded dynamic path or smooth dynamic path into the trajectory. 14. The lifting device according to claim 13 , wherein a maximal speed and a maximal acceleration of the bearing structure, a maximal speed and a maximal acceleration of the travelling element, a maximal speed and a maximal acceleration of the lift drive are established as the kinematic limit values of the lifting device, and a maximal angle of deflection of the load receiver element is established as the geometric limit value. 15. The lifting device according to claim 13 , wherein the lifting device has a third motion axis, wherein the load is movable by a bearing structure along the third motion axis, wherein the start point and the end point are established in a motion space spanned by the first, second and third motion axes of the lifting device; wherein the prohibited zones are established in the motion space, and wherein the calculation of the trajectory is carried out in the motion space. 16. The lifting device according to claim 15 , wherein motion space spanned by the first, second and third motion axes is a second plane in which the start point and end point are established; wherein the prohibited zones are established in the second plane, and wherein the calculation of the trajectory is carried out in the second plane. 17. The lifting device according to claim 13 , wherein the computing unit is configured to produce the geometric path to connect the start point to the end point by straight lines via supporting points derived from the pr