Patent Number: 047541474
Section: claims

1. A collimator apparatus for producing a cross-sectionally shaped beam of radiation from a radiation source which comprises: (a) support plate means having a central opening around a beam axis through which the beam of radiation can pass;  (b) a bundle of nested rods mounted on the support plate means each rod being movable into the beam at an angle to the beam axis to interfere with the beam, the rods having first ends which together define a first surface for shaping the beam around the beam axis and opposite ends from the first ends of the rods wherein the rods are nested so that the beam can not pass between the rods;  (c) a holder means mounting the rods so that the first surface is defined and the beam is shaped by the first ends of the rods; and  (d) releasable clamping means mounted on the support plate means and engaging the rods between the first and second ends to secure the rods together in the shape defined by the first ends of the rods.  (a) support plate means having a central opening around a beam axis through which the beam of radiation can pass;  (b) a bundle of nested metal rods mounted on the support plate means each rod having a longitudinal axis perpendicular to the beam axis and having first ends which together define a first surface for shaping the beam around the beam axis and opposite ends from the first ends wherein the rods are nested so that the beam can not pass between the rods;  (c) a holder means mounting the rods including shaping means adjacent the opposite ends of the rods, wherein the rod shaping means has a second surface corresponding to the first surface which defines varying positions of the first ends of the rods so that the first surface is defined and the beam is shaped by the first ends of the rods; and  (d) clamping means mounted on the support plate means for securing the rods together in the shape defined by the shaping means.  (a) providing a collimator apparatus for producing a cross-sectionally shaped beam of radiation from a radiation source which comprises: support plate means having a central opening around a beam axis through which the beam of radiation can pass; a bundle of nested rods mounted on the support plate means each rod being movable into the beam at an angle to the beam axis to interfere with the beam, the rods having first ends which together define a first surface for shaping the beam around the beam axis and opposite ends from the first ends of the rods a holder means mounting the rods so that the first surface is defined and the beam is shaped by the first ends of the rods wherein the rods are nested so that the beam can not pass between the rods; and releasable clamping means mounted on the support plate means and engaging the rods between the first and second ends to secure the rods together in the shape defined by the first ends of the rods;  (b) moving the rods in the holder means to thereby define the first surface for shaping the beam in the collimator;  (c) clamping the rods with the clamping means; and  (d) irradiating the defined area of an object with the shaped beam defined by the rods.  (a) providing support plate means mounted on the radiation source having a central opening around a beam axis through which the beam of radiation can pass; a bundle of nested metal rods mounted on the support plate means each rod having a longitudinal axis perpendicular to the beam axis and having first ends which together define a first surface for shaping the beam around the beam axis and opposite ends from the first ends wherein the rods are nested so that the beam can not pass between the rods; a holder means mounting the rods including shaping means adjacent the opposite ends of the rods, wherein the rod shaping means has a second surface corresponding to the first surface which defines varying positions of the first ends of the rods so that the first surface is defined and the beam is shaped by the first ends of the rods; and clamping means mounted on the support plate means for securing the rods together in the shape defined by the shaping means;  (b) providng the rod shaping means by shaping a material to conform to an outline of an x-ray image of defined area to the body to be irradiated and thereby providing the second surface of the rod shaping means;  (c) mounting the rod shaping means in the holder means with the opposite ends of the rods engaging the rod shaping means second surface to thereby define the first surface for shaping the beam in the collimator corresponding to the x-ray image;  (d) clamping the rods with the clamping means; and  (e) irradiating the defined area of an object with the shaped beam defined by the rods. 2. The collimator apparatus of claim 1 wherein there are two opposed bundles of rods mounted on the support plate means with the first ends opposite each other. 3. The collimator apparatus of claim 1 wherein the rods are circular in cross-section and have a diameter of between about 1 mm and 3 mm. 4. The collimator apparatus of claim 1 wherein rods have a composition for interfering with a neutron beam. 5. The collimator apparatus of claim 1 wherein the rods have a composition for interference with a photon beam. 6. A collimator apparatus for producing a cross-sectionally shaped beam of radiation from a radiation source which comprises: 7. The collimator apparatus of claim 6 wherein there are two opposed bundles of rods mounted on the support plate means with the first ends opposite each other and with the opposed rods having parallel longitudinal axis. 8. The collimator apparatus of claim 6 wherein the rods are circular in cross-section and have a diameter of between about 1 mm and 3 mm. 9. The collimator apparatus of claim 6 wherein the metal composition of the rods is selected from the group consisting of tungsten and stainless steel. 10. The collimator apparatus of claim 6 wherein the rod shaping means is composed of polystyrene foam which is mounted on the holder. 11. The collimator apparatus of claim 6 wherein the rods have a composition for interference with a neutron or photon beam. 12. The collimator apparatus of claim 6 wherein the rods have a polygonal cross-section. 13. The collimator apparatus of claim 6 wherein the support plate means is rotatable around the beam axis by a drive means. 14. The collimator apparatus of claim 6 wherein the support plate means is circular and has a ring gear mounted around the central opening, wherein a worm gear driven by a drive means engages the ring gear to rotate the support plate means. 15. A method of producing a cross-sectionally shaped beam of radiation from a radiation source which comprises: 16. A method of producing a cross-sectionally shaped beam of radiation from a radiation source which comprises: 17. The method of claim 16 wherein there are two opposed bundles of rods mounted on the support plate means as mirror images of each other with the first ends opposite each other and with the rods in each bundle having parallel longitudinal axis and wherein each of the bundles of rods is mounted on one of two opposed second surfaces of two opposed rod shaping means. 18. The method of claim 16 wherein the rod shaping means is composed of polystyrene foam which is cut to the shape of the beam. 19. The method of claim 16 wherein the beam is a neutron beam and wherein the rods are made from the metal selected from tungsten and stainless steel. 20. The method of claim 16 wherein the support plate means is rotated around the beam axis by a drive means. 21. The method of claim 20 wherein the support plate means has a ring gear mounted around the central opening and wherein a drive means with a worm gear meshed to the ring gear rotates the worm gear, ring gear and support plate. 22. The method of claim 16 wherein a beam selected from neutrons and photons is produced by the radiation source. 23. The method of claim 22 wherein the beam is of neutrons produced from a target irradiated with an accelerated beam of charged particles which impinge upon the target releasing the neutrons which then pass through the opening in the support plate. 24. The method of claim 16 wherein the rods each have a circular cross-section and a diameter of between about 1 and 3 mm. 25. The method of claim 16 wherein the rods have a polygonal cross-section. 26. The method of claim 16 wherein a patient is irradiated.