A particle beam therapy apparatus 10 includes: a particle beam irradiator 16 outputting a particle beam B; a movable supporting structure 21 supporting the particle beam irradiator 16; movable plates 37 disposed on a displacement trajectory of the particle beam irradiator 16, forming a substantially horizontal enveloping surface below a table 18 for placing an irradiation object 13, and including first and second floor members in at least one of the movable plates 37, the second floor member being larger in X-ray transmittance than the first floor member; an X-ray generator 27a provided in a non-collision area 31 where the X-ray generator 27a does not collide with any of the particle beam irradiator 16, the supporting structure 21, and the movable plates 37; and an X-ray detector 27b installed at a position where the X-ray detector 27b faces the X-ray generator 27a.

An irradiation treatment system comprising: a synchrotron ring defining a border extending vertically from the synchrotron ring; a particle beam generator, an output of the particle beam generator coupled to an inlet of the synchrotron ring and arranged to inject charged particle beams into the synchrotron ring; a field control unit arranged to adjust an electric and magnetic field such that the injected charged particle beams are accelerated; a treatment irradiation source positioned within the defined border, the input of the irradiation source coupled to the outlet of the synchrotron ring and arranged to receive the accelerated particle beams from the synchrotron ring; and a patient support member positioned within the defined border and arranged to support a patient in a predetermined relationship with the output of the treatment irradiation source, the treatment irradiation source arranged to irradiate the supported patient with the accelerated particle beams.

The present disclosure provides a neutron capture therapy system, including a neutron generator to generate neutrons after irradiation by charged particles, and a beam shaping assembly includes a moderator and a reflector surrounding the moderator. A vacuum tube connected to the accelerator is provided at an accommodating portion. The vacuum tube transmits the charged particles accelerated by the accelerator to the neutron generator to generate neutrons. The neutron generator moves between a first position and a second position, at the first position, the neutron generator react with the charged particle beam to generate neutrons, at the second position, the neutron generator falls off the beam shaping assembly. The vacuum tube is detached to make the neutron generator fall off the beam shaping assembly, to reduce direct contact of a worker with the neutron generator after nuclear reactions, thereby reducing radioactive hazards for workers.

A proton therapy system based on a compact superconducting cyclotron, including: a superconducting cyclotron system, an energy selection system, a beam transport system, a fixed therapy room subsystem and a rotating frame therapy subsystem; a fixed-energy proton beam extracted from a superconducting cyclotron of the superconducting cyclotron system is adjusted into a continuous and adjustable proton beam of 70 MeV to 200 MeV by the energy selection system, thus realizing a longitudinal adjustment for a proton range during treating a tumor, and the continuous and adjustable proton beam is respectively transmitted to the fixed therapy room subsystem and the rotating frame therapy subsystem by the beam transport system. The cooperative control of the superconducting cyclotron system, the energy selection system, the beam transport system and the therapy head realizes the transverse expansion of proton beams, thus realizing intensity modulated radiation therapy for the tumor.

The present disclosure provides a neutron capture therapy system, including an accelerator for generating a charged particle beam, a neutron generator for generating a neutron beam having neutrons after irradiation by the charged particle beam, and a beam shaping assembly for shaping the neutron beam. The beam shaping assembly includes a moderator and a reflecting assembly surrounding the moderator. The neutron generator generates the neutrons after irradiation by the charged particle beam. The moderator moderates the neutrons generated by the neutron generator to a preset energy spectrum. The reflecting assembly includes a reflecting assembly to deflected neutrons back to the neutron beam and a supporting member to support the reflectors. A lead-antimony alloy is for the reflecting assembly to mitigate a creep effect that occurs when only a lead material is for the reflectors, thereby improving the structural strength of a beam shaping assembly.

An irradiation method and system for irradiating a target volume, the method comprising: providing thermal neutron absorbing nuclides (such as in the form of a high neutron cross-section agent) at the target volume; and producing neutrons by irradiating nuclei in or adjacent to the target volume with a beam of particles consisting of any one or more of protons, deuterons, tritons and heavy ions, thereby prompting production of the neutrons through non-elastic collisions between the atoms in the path of the beam (including the target) and the particles. The neutron absorbing nuclides absorb neutrons produced in the non-elastic collisions, thereby producing capture products or fragments that irradiate the target volume.

The present disclosures relates to an ion beam assembly where a relatively small deflection angle (approximately 15 from the center of the beam line) is used in conjunction with two beam dumps located on either side of the beam. In some embodiments, the combination of the two beam dumps and the magnet assembly can provide an ion beam filter. In some embodiments, the resulting system provides a smaller, safer and more reliable ion beam. In some embodiments, the ion beam can be a proton beam.

A neutron capture therapy system, including an accelerator for generating a charged particle beam, a transmission device for transmitting the charged particle beam, a neutron generation part for generating a neutron beam by reacting with the charged particle beam, a beam shaping body for performing spectrum adjustment on the neutron beam, and a guidance device. The transmission device at least includes a first transmission part and a second transmission part which is detachably connected to the first transmission part, the first transmission part includes a first position L1 and a second position L2, and the guidance device guides the first transmission part and the neutron generation part to move from the first position L1 which the neutron generation part is accommodated in the beam shaping body to the second position L2 which the neutron generation part is separated from the beam shaping body.

In order to improve flux and quality of neutron sources, the disclosure provides a beam shaping assembly for neutron capture therapy includes: a beam inlet; a target, wherein the target has nuclear reaction with an incident proton beam from the beam inlet to produce neutrons; a moderator adjoining to the target, wherein the neutrons are moderated by the moderator to epithermal neutron energies, the moderator includes a main body and a supplement section surrounding the main body, the main body and the supplement section form at least a tapered structure; a reflector surrounding the moderator; a thermal neutron absorber adjoining to the moderator; a radiation shield arranged inside the beam shaping assembly, wherein the radiation shield is used for shielding leaking neutrons and photons so as to reduce dose of the normal tissue not exposed to irradiation; and a beam outlet.

A particle irradiation system includes three or more scanning magnets that scan a beam in a vertical direction (first direction) or a horizontal direction (second direction) perpendicular to each other. The three or more scanning magnets are configured such that the scanning magnets and the scanning magnets for scanning in the same direction between the vertical direction or the horizontal direction, are disposed in series on a progressing direction axis of a beam, and a volume of a magnetic field feeding region decreases as the scanning magnet is installed at a position farther from an isocenter on the progressing direction axis.