This paper describes the design of an X-Band Magnetron to Linear Accelerator (LINAC) High Power Transfer System consisting in an 8 resonant cavities Magnetron connected to a dedicated vacuum Dielectric Window (DW). A main analytical design of devices is shown with compact formulas and is followed by numerical optimization. Electromagnetic and Thermomechanical coupling between these devices is described, particular attention has been given to the Magnetron power coupling and DW matching. A Multiphysics modeling is proposed to consider thermal-structural effects due to the cathode heating for the Magnetron and the Joule effect for the DW. Thermal induced degradation of the device performances are estimated and proper materials and shapes are chosen in order to ensure the desired behavior of the system in operative conditions. The proposed study provided the evaluation of the Magnetron Working Points and DW Scattering parameters in Thermo-mechanical operative conditions. Technological strategies for device coupling are shown.

Leggieri, A., Passi, D., Felici, G., De Stefano, S., DI PAOLO, F. (2016). Magnetron High Power System Design. INTERNATIONAL JOURNAL OF SIMULATION: SYSTEMS, SCIENCE & TECHNOLOGY, 16(1), 1-13 [10.5013/IJSSST.a.16.01.03].

Magnetron High Power System Design

DI PAOLO, FRANCO
2016-01-01

Abstract

This paper describes the design of an X-Band Magnetron to Linear Accelerator (LINAC) High Power Transfer System consisting in an 8 resonant cavities Magnetron connected to a dedicated vacuum Dielectric Window (DW). A main analytical design of devices is shown with compact formulas and is followed by numerical optimization. Electromagnetic and Thermomechanical coupling between these devices is described, particular attention has been given to the Magnetron power coupling and DW matching. A Multiphysics modeling is proposed to consider thermal-structural effects due to the cathode heating for the Magnetron and the Joule effect for the DW. Thermal induced degradation of the device performances are estimated and proper materials and shapes are chosen in order to ensure the desired behavior of the system in operative conditions. The proposed study provided the evaluation of the Magnetron Working Points and DW Scattering parameters in Thermo-mechanical operative conditions. Technological strategies for device coupling are shown.
gen-2016
Pubblicato
Rilevanza internazionale
Articolo
Esperti anonimi
Settore ING-INF/01 - ELETTRONICA
English
Computational Electromagnetics; Dielectric Windows; Electron Linear Accelerators; FEM methods; High Power Microwave Systems; Magnetron; Multi-physics modeling
http://ijssst.info/Vol-16/No-1/paper3.pdf
Leggieri, A., Passi, D., Felici, G., De Stefano, S., DI PAOLO, F. (2016). Magnetron High Power System Design. INTERNATIONAL JOURNAL OF SIMULATION: SYSTEMS, SCIENCE & TECHNOLOGY, 16(1), 1-13 [10.5013/IJSSST.a.16.01.03].
Leggieri, A; Passi, D; Felici, G; De Stefano, S; DI PAOLO, F
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2108/143207
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