Patent Number: 06188748&
Section: claims

1. A contour collimator for radiotherapy, comprising a plurality of plate-shaped diaphragm elements provided in a guiding block and movably arranged with respect to one another to form a contour diaphragm for a radiation beam emitted by a radiation source towards the collimator, and comprising at least one drive for moving the diaphragm elements, wherein a drive of its own is associated with each diaphragm element, the drives of a group of diaphragm elements are arranged substantially adjacent to one another, and a driving transmission of its own is provided between each drive and the associated diaphragm element, wherein the drives are arranged substantially in a semi-circle. 2. The contour collimator according to claim 1, wherein at least one displacement pickup for detecting the position of the corresponding diaphragm element is associated with each drive. 3. The contour collimator according to claim 1, wherein each driving transmission has a flexible but tension-resistant and pressure-resistant power-transmitting element one end of which is connected with the associated diaphragm element and the other end of which is connected with the associated drive and which is supported in a moving guide in translatorily movable fashion. 4. The contour collimator according to claim 3, wherein each power-transmitting element is detachably coupled to the associated diaphragm element via a coupling linkage. 5. The contour collimator according to claim 3, wherein each power-transmitting element is detachably coupled to the associated drive via a further coupling linkage. 6. The contour collimator according to claim 3, wherein each power-transmitting element has a spring band. 7. The contour collimator according to claim 1, wherein each drive comprises a linearly acting motor. 8. The contour collimator according to claim 7, wherein the motor is an electric linear motor. 9. The contour collimator according to claim 7, wherein the motor is an electric motor having a linearly acting gearing selected from the group consisting of a rack-and-pinion gear and a spindle gearing. 10. The contour collimator according to claim 1, wherein the guiding block has upper and lower guide plates which are each provided with a plurality of upper guide grooves and lower guide grooves, respectively, for the diaphragm elements. 11. The contour collimator according to claim 10, wherein the upper and lower guide plates are each provided with a rectangular opening which determine the maximum diaphragm opening and have a common middle plane extending substantially rectangularly with respect to the longitudinal direction of the guide grooves. 12. A contour collimator for radiotherapy, comprising a plurality of plate-shaped diaphragm elements provided in a guiding block and movably arranged with respect to one another to form a contour diaphragm for a radiation beam emitted by a radiation source towards the collimator, and comprising at least one drive for moving the diaphragm elements, wherein a drive of its own is associated with each diaphragm element, the drives of a group of diaphragm elements are arranged substantially adjacent to one another, and a driving transmission of its own is provided between each drive and the associated diaphragm element, wherein each driving transmission has a flexible but tension-resistant and pressure-resistant power-transmitting element one end of which is connected with the associated diaphragm element and the other end of which is connected with the associated drive and which is supported in a moving guide in translatorily movable fashion, and wherein the moving guides are arranged substantially side by side in a moving guide block and have moving guide gaps diverging in fan-shaped and bent fashion, in which one power-transmitting element is accommodated in translatorily movable fashion. 13. A contour collimator for radiotherapy, comprising a plurality of plate-shaped diaphragm elements provided in a guiding block and movably arranged with respect to one another to form a contour diaphragm for a radiation beam emitted by a radiation source towards the collimator, and comprising at least one drive for moving the diaphragm elements, wherein a drive of its own is associated with each diaphragm element, the drives of a group of diaphragm elements are arranged substantially adjacent to one another, and a driving transmission of its own is provided between each drive and the associated diaphragm element, wherein two superposed planes of drive arrangements are associated with each moving guide block, on power-transmitting element, accommodated in adjacent moving guides, being applied by two superposed drives each. 14. The contour collimator according claim 1, wherein two opposite groups of tanslatorily drivable diaphragm elements are provided in the guiding block, two opposite diaphragm elements each being guided in lower and upper common guide grooves. 15. The contour collimator according to claim 1, wherein each diaphragm element of a pair of opposite diaphragm elements is movable with its free edge facing away from the respective beyond the common middle plane of openings in upper and lower guide plates. 16. The contour collimator according to claim 12, wherein the displacement pickup comprises a potentiometer. 17. The contour collimator according to claim 2, wherein the displacement pickup comprising a moving potentiometer which can be actuated translatorily. 18. A contour collimator for radiotherapy, comprising a plurality of plate-shaped diaphragm elements provided in a guiding block and movably arranged with respect to one another to form a contour diaphragm for a radiation beam emitted by a radiation source towards the collimator, and comprising at least one drive for moving the diaphragm elements, wherein a drive of its own is associated with each diaphragm element, the drives of a group of diaphragm elements are arranged substantially adjacent to one another, and a driving transmission of its own is provided between each drive and the associated diaphragm element, wherein at least one of the diaphragm elements located in the region of the central middle ray of the radiation beam is provided with at least one thickening rib extending in the translational direction. 19. The contour collimator according to claim 18, wherein each thickening rib engages a corresponding groove in the adjacent diaphragm element.