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Kleffner, C. M.

Paper Title Page
TUPP131 Status of the Linac Components for the Italian Hadrontherapy Centre CNAO 1833
 
  • H. Vormann, C. M. Kleffner, A. Reiter, B. Schlitt
    GSI, Darmstadt
  • G. Clemente, U. Ratzinger
    IAP, Frankfurt am Main
 
  The IH-DTL for the Linac in the Italian National Center for Hadron Therapy in Oncology CNAO will accelerate different ion species (C4+, O6+,3He+, H2+) to an energy of 7 MeV/u. The combined rebunching and accelerating beam dynamic concept ("KONUS", "Kombinierte Null Grad Struktur", combined zero degree structure) requires a real voltage distribution in all 56 accelerator gaps (distributed in 4 sections) matching very close to the design voltage distribution. The tuning of the mechanically finished and copper plated cavity started in January 2007, based on the experience from the similar IH-DTL for the HIT linac ("Heidelberger Ionenstrahl-Therapiezentrum", the Heidelberg ion beam therapy center). Very small differences in mechanical measures caused modified starting conditions, resulting in varying number and shape of fixed tuners, but nevertheless accurate field distribution. The CNAO Linac is at presently under commissioning, all linac components except the IH-DTL have been delivered to the center in November 2007.  
TUPP134 Commissioning of the Carbon Beam Gantry at the Heidelberg Ion Therapy (HIT) Accelerator 1842
 
  • U. Weinrich, C. M. Kleffner
    GSI, Darmstadt
 
  The HIT facility comprises the only carbon ion gantry worldwide. This gantry is especially unique in offering fully flexible beam transport to the patient for carbon ions up to an energy of 430 MeV/u. It includes a full 3D-beam scanning system and full medical treatment environment. The gantry can be rotated by 360 degree so that the beam may be directed at the patient from arbitrary directions. Commissioning with beam of the gantry was successfully started in January 2008 when the first proton and carbons beams were transported into the gantry treatment room. Based on theoretical calculations for rotation independent settings of the beam optics, the beam commissioning aims for an efficient practical way to realize the full variety of required beam properties (2 ion types, 10 intensities, 255 energy steps, and four beam sizes) in the isocenter independent of the gantry angle. The presentation will report on the concept and progress of the beam commissioning process.