Patent Number: 041397770
Section: claims

1. A light, compact cyclotron suitable for use in neutron therapy, and capable of being moved to change the direction of an exiting neutron beam comprising: (a) a pair of opposed, spaced pole shoes having their adjacent inner surfaces defining an accelerator zone, the surfaces being adapted to constitute magnetic equipotential surfaces which establish a magnetic field configuration for the cyclotron during use,  (b) an electromagnetic coil system around the pole shoes and adapted for connection to an electrical power source for generating the cyclotron magnetic field between the pole shoe surfaces,  (c) a magnet yoke to provide a magnetic flux return path for the pole shoes, the magnet yoke together with the pole shoes providing a low magnetic resistance relatively to that of the accelerator zone, and the magnet yoke being shaped to substantially enclose the accelerator zone to constitute, together with the pole shoes, a neutron attenuation shield for neutrons produced in the cyclotron,  (d) at least one hollow accelerating dee electrode positioned in the accelerator zone, and having a radio frequency resonator associated therewith,  (e) a vacuum chamber enclosing the acclerator zone and each dee electrode,  (f) means for providing charged particles for acceleration within the accelerator zone,  (g) a target zone for a target device, and  (h) a neutron beam outlet in the magnet yoke for emission of a neutron beam produced in the cyclotron.  (a) a pair of opposed, spaced pole shoes having their adjacent inner surfaces defining an accelerator zone, the surfaces being adapted to constitute magnetic equipotential surfaces which establish a magnetic field configuration for the cyclotron during use,  (b) an electromagnetic coil system around the pole shoes and adapted for connection to an electrical power source for generating the cyclotron magnetic field between the pole shoe surfaces,  (c) a magnet yoke to provide a magnetic flux return path for the pole shoes, the magnet yoke together with the pole shoes providing a low magnetic resistance relatively to that of the accelerator zone, and the magnet yoke being shaped to substantially enclose the accelerator zone to constitute, together with the pole shoes, a neutron attentuation shield for neutrons produced in the cyclotron,  (d) at least one hollow accelerating dee electrode positioned in the accelerator zone, and having a radio frequency resonator associated therewith,  (e) a vacuum chamber enclosing the accelerator zone and each dee electrode,  (f) means for providing charged particles for acceleration within the accelerator zone,  (g) a target zone for a target device, and  (h) a neutron beam outlet in the magnet yoke for emission of a neutron beam produced in the cyclotron. 2. A cyclotron according to claim 1, in which the adjacent inner surfaces of the pole shoes are shaped to define at least three hills and valleys to establish an isochronous magnetic field configuration during use. 3. A cyclotron according to claim 2, in which the hills and valleys are radial. 4. A cyclotron according to claim 2, having a dee electrode positioned in each valley, with each dee electrode having a radio frequency resonator associated therewith. 5. A cyclotron according to claim 4, in which the dee electrodes are connected to each other at the centre of the accelerator zone. 6. A cyclotron according to claim 5, having a transmission bore extending along the polar axis of one of the pole shoes, having a radio-frequency transmission line located in the transmission bore and connected to the dee electrodes at the centre of the accelerator zone, and having coupling means for coupling the transmission line to a radio-frequency power source. 7. A cyclotron according to claim 1, having auxiliary neutron shield means in the forward neutron peak zone of a neutron beam produced in the cyclotron to attenuate neutron and gamma radiation in the forward peak zone to provide a combined neutron and gamma radiation dose rate of less than about 3% of that in a neutron beam emitted from the neutron beam outlet during use. 8. A cyclotron according to claim 7, in which the auxiliary neutron shield means comprises a neutron attenuation shield and a neutron moderating shield. 9. A cyclotron according to claim 8, in which the neutron attenuation shield is provided within the magnet yoke and the neutron moderating shield is provided in the magnet yoke. 10. A cyclotron according to claim 2, in which the neutron beam outlet is shaped to removably receive a collimator to control the radiation field size of a neutron beam emitted from the neutron beam outlet. 11. A cyclotron according to claim 2, in which the vacuum chamber is defined by the adjacent inner surfaces of the pole shoes and by an annular channel member surrounding the accelerator zone and having its free edges sealingly secured to the opposed pole shoes. 12. A cyclotron according to claim 2, in which the magnet yoke comprises a plurality of separate yoke sections which together constitute the magnet yoke. 13. A cyclotron according to claim 1, in which each radio-frequency resonator extends radially and is enclosed within the magnet yoke. 14. A cyclotron according to claim 13, in which each radio-frequency resonator comprises a flat, narrow inner conductor plate mounted on the dee, and two flat, wider outer conductor plates on opposed sides of and laterally spaced from the inner conductor plate, with the outer conductor plates connected to the inner conductor plate by means of short circuit plates. 15. A cyclotron according to claim 14, in which each outer conductor plate includes a flexible hinge, in which each short circuit plate is flexible, and in which frequency adjustment means extends from each outer conductor plate to allow for adjustment of the characteristic impedance of each radio frequency resonator. 16. A cyclotron according to claim 1, having pivot means for pivotally mounting the cyclotron to allow variation of the direction of a neutron beam emitted from the neutron beam outlet during use. 17. A cyclotron according to claim 16, in which the pivot means comprises pivot bores in opposed sides of the cyclotron, for receiving pivot shafts to pivotally support the cyclotron. 18. A cyclotron according to claim 16, in which the pivot means comprises two pivot shafts extending outwardly from opposed sides of the cyclotron, each pivot shaft having a support gear wheel mounted thereon for pivotally supporting the cyclotron on suitable support rails in the form of linear gear rails having teeth to mesh with the gear wheel teeth. 19. A cyclotron according to claim 16, in which the polar axis of the pivot means extends normally to the plane of the accelerator zone along the polar axis of the cyclotron. 20. A cyclotron according to claim 16, in which the pivot means comprises a pivot frame in which the cyclotron is mounted, the pivot frame having a pair of opposed supporting legs, with each supporting leg having a pivot bore for pivotally mounting the frame on a pair of support axles, and the pivot frame having a pivot beam mounted thereon, with the pivot beam having guide gear wheels mounted at its opposed ends to co-operate with a pair of curved, complementarily toothed guide rails positioned concentrically with the pivot bores to guide pivotal displacement of the cyclotron about the pivot bores, the pivot bores being positioned so that their axes will intersect the core of a neutron beam emitted from the neutron beam outlet during use, in the treatment zone of such a beam where the centre of an affected area of a patient to be treated would be positioned during treatment, thereby providing an isocentric therapy system. 21. A cyclotron according to claim 20, in which the cyclotron is pivotally mounted in the pivot frame. 22. A cyclotron according to claim 16, in which the pivot means comprises a turntable to support the cyclotron on a surface for pivotal displacement about a vertical axis. 23. A neutron therapy installation comprising biological shielding means to define the installation, and having a light, compact cyclotron for use in neutron therapy, mounted therein, and capable of being moved to change the direction of an exiting neutron beam,. the cyclotron comprising: 24. A neutron therapy installation according to claim 23, in which the cyclotron has pivot means for pivotally mounting the cyclotron to allow variation of the direction of a neutron beam emitted from the neutron beam outlet during use, and in which the installation has pivot support means for engaging with the pivot means. 25. A neutron therapy installation according to claim 24, in which the cyclotron has pivot means in the form of pivot bores in opposed sides thereof, and the pivot support means comprises opposed pivot shafts which extend into the pivot bores and have bearings mounted thereon which engage with the pivot bores. 26. A neutron therapy installation according to claim 24, in which the cyclotron has pivot means in the form of two pivot shafts extending outwardly from opposed sides thereof, with each pivot shaft having a support gear wheel mounted thereon, and the installation includes two linear gear support rails having teeth to mesh with the teeth of the gear wheels. 27. A neutron therapy installation according to claim 24, in which the pivot means comprises a pivot frame in which the cyclotron is mounted, the pivot frame having a pair of opposed supporting legs, with each supporting leg having a pivot bore, and the pivot frame having a pivot beam mounted thereon, with the pivot beam having guide gear wheels mounted at its opposed ends, and in which the pivot support means comprises two opposed support axles on which the pivot bores are mounted, and two opposed curved, toothed guide rails which are concentric with the support axles to co-operate with the guide gear wheels of the pivot beam and guide pivotal displacement of the cyclotron about the pivot bores, the pivot bores being positioned so that their axes will intersect the core of a neutron beam emitted from the neutron beam outlet during use, in the treatment zone of such a beam where the centre of an affected area of a patient to be treated would be positioned during treatment, thereby providing an isocentric therapy system. 28. A neutron therapy installation according to claim 23, in which the cyclotron has pivot means in the form of a turntable to support the cyclotron on the floor of the installation for pivotal displacement about a vertical axis, and in which the installation has a plurality of separate treatment rooms circumferentially spaced about the cyclotron, with each room having an access opening to register with the neutron beam outlet of the cyclotron.