초록 ▼

A beam guiding magnet includes a first and second coil system, which are designed such that the dipole moments of the first and second coil systems point in opposite directions. Since the dipole moments of the first and second coil systems point in opposite directions, the two dipole moments at leas

A beam guiding magnet includes a first and second coil system, which are designed such that the dipole moments of the first and second coil systems point in opposite directions. Since the dipole moments of the first and second coil systems point in opposite directions, the two dipole moments at least partially compensate for one another. The resultant dipole moment of the beam guiding magnet may be reduced. The beam guiding magnet may take into account that the remote field of a beam guiding magnet can be lowered by a reduction in the dipole moment of the beam guiding magnet. The dipole moment decreases with the cube of the distance from the beam guiding magnet. A quadruple moment, which on attenuation of the dipole moment represents the next strongest field component, decreases with the fifth power of that distance.

대표청구항 ▼

The invention claimed is: 1. A beam guiding magnet for deflecting a particle beam along a curved particle path, which defines a beam guidance plane, toward an isocenter, the beam guiding magnet comprising: a first coil system having curved individual coils, disposed along the particle path, which a

The invention claimed is: 1. A beam guiding magnet for deflecting a particle beam along a curved particle path, which defines a beam guidance plane, toward an isocenter, the beam guiding magnet comprising: a first coil system having curved individual coils, disposed along the particle path, which are arranged in pairs in mirror symmetry to the beam guidance plane, the first coil system including two saddle-shaped first primary coils with side parts elongated in a direction of the particle path and end parts bent upward on a face end, at least two secondary coils, which are curved and surround an inner region, and at least two correction coils, which are curved and are located in the respective inner region of the secondary coils, and a second coil system having two second primary coils, which extend laterally of the particle path and are curved and which are located between the first primary coils and include a first and a second elongated side part, the first elongated side part is located close to the particle path and the second elongated side part is remote from the particle path, wherein the first and second coil systems are operable to generate dipole moments that point in opposite directions. 2. The beam guiding magnet as defined by claim 1, the dipole moment generated by the first coil system and the dipole moment generated by the second coil system substantially cancel one another out in the outer region of the beam guiding magnet. 3. The beam guiding magnet as defined by claim 1, wherein the first and second coil systems are excited such that the sum of the magnetic fields to be generated by the first and second coil systems is minimized at the site of the isocenter. 4. The beam guiding magnet claim 2, wherein the individual coils of the first and second coil systems are connected electrically in series. 5. The beam guiding magnet as defined by claim 3, wherein the individual coils of the first and second coil systems are connected electrically in series. 6. The beam guiding magnet as defined by claim 2, wherein the number of windings of the individual coils is dimensioned such that in an outer region of the beam guiding magnet, the sum of the dipole moments of the first and second coil systems is minimized. 7. The beam guiding magnet as defined by claim 2, wherein the second primary coils in the beam guidance plane enclose an area dimensioned such that in an outer region of the beam guiding magnet, the sum of the dipole moments of the first and second coil systems is minimized. 8. The beam guiding magnet as defined by claim 1, wherein the secondary coils extend between the bent-upward end parts of their respective associated first primary coils. 9. The beam guiding magnet as defined by claim 1, wherein the beam guiding magnet is free of ferromagnetic material. 10. The beam guiding magnet as defined by claim 1, wherein the conductors of the individual coils include metal low-temperature superconductor material. 11. The beam guiding magnet as defined by claim 1, wherein the conductors of the individual coils include metal oxide high-temperature superconductor material. 12. The beam guiding magnet as defined by claim 11, wherein an operating temperature of the individual coils is between 10K and 40K, preferably between 20K and 30K. 13. An irradiation system comprising: a fixed particle source that generates a beam of electrically charged particles, and a gantry system, which is rotatable about an axis of rotation, the gantry system including a plurality of deflecting and/or focusing magnets for deflecting and/or focusing the particle beam into an isocenter, wherein at least one of the deflecting and/or focusing magnets is a beam guiding magnet as defined by claim 1. 14. The irradiation system as defined by claim 13, wherein the deflecting and/or focusing magnet that the particle beam interacts with last before reaching the isocenter is a beam guiding magnet. 15. The irradiation as defined by claim 14, wherein a magnetic field of the beam guiding magnet is minimized, at least in the patient's room, preferably at least at the site of the isocenter. 16. The irradiation system as defined by claim 13, wherein the particle beam comprises C6+ particles. 17. The beam guiding magnet as defined by claim 1, wherein the secondary coils and correction coils are substantially flat. 18. The beam guiding magnet as defined by claim 17, wherein the secondary coils and correction coils are curved in a banana-like shape. 19. The beam guiding magnet as defined by claim 1, wherein the two second primary coils are curved in a banana-like shape. 20. The beam guiding magnet as defined by claim 19, wherein the first and second elongated side parts are essentially flat.