Title :
APT CCDTL and CCL thermal/mechanical analysis
Author :
Christiansen, D. ; Smith, P. ; Spalek, George
Author_Institution :
Gen. Atomics, San Diego, CA, USA
fDate :
6/23/1905 12:00:00 AM
Abstract :
Design automation techniques are being, developed to facilitate the design of the normal conducting Coupled-Cavity Drift Tube LINAC (CCDTL) and Coupled-Cavity LINAC (CCL) for the Accelerator Production of Tritium (APT). The cavity geometry is generated from automated RF design codes and fed directly into a 3-D multiphysics code which calculates the RF heat loads and cavity distortions due to the heat loads. The resulting frequency change in the cavity is determined by the Slater perturbation formulation. Cooling is located to minimize these distortions. The application and their status as applied to the APT CCL will be discussed. In particular, the use of specific codes to reduce the peak thermal stress around the coupling slots in these cw (continuous wave) RF cavities will be presented
Keywords :
accelerator RF systems; accelerator cavities; accelerator-based transmutation; cooling; geometry; high energy physics instrumentation computing; linear accelerators; thermal stress cracking; tritium; 3D multiphysics code; APT CCDTL thermomechanical analysis; APT CCL thermomechanical analysis; RF heat loads; Slater perturbation formulation; T; accelerator production of tritium; automated radiofrequency design codes; cavity distortions; cavity geometry; continuous wave RF cavities; cooling; coupled-cavity linac; coupling slots; design automation techniques; normal conducting coupled-cavity drift tube linear accelerator; peak thermal stress; Acceleration; Electromagnetic coupling; Equations; Frequency estimation; Geometry; Linear particle accelerator; Performance analysis; Radio frequency; Solids; Thermal stresses;
Conference_Titel :
Particle Accelerator Conference, 2001. PAC 2001. Proceedings of the 2001
Print_ISBN :
0-7803-7191-7
DOI :
10.1109/PAC.2001.986701
