Model of the rotor temperature of turbo-molecular pumps in magnetic fields

Abstract

The KATRIN neutrino experiment operates about 20 turbo-molecular pumps (TMP) in the vicinity of super-conducting magnets, pumping out tritium gas from the electron beam-line of the experiment. In a dedicated test setup with Helmholtz coils systematic studies have been conducted, investigating the rotor temperature and stability of operation of TMPs at full speed as a function of gas load, magnetic field strength and direction of the field. The temperature of the magnetically levitated spinning rotor was measured in vacuum with an infra-red pyrometer. A simple model has been developed, which describes quantitatively the temporal progression of the rotor temperature as a function of gas flow and field strength of an external static magnetic field. The model requires 5 pump-specific parameters, characterising the heating effects of eddy currents and gas friction and cooling by radiation loss and convection. When designing a vacuum system with TMPs in a critical environment (e.g. magnetic beam-line, fusion reactor), the model can be used to predict the maximum temperature of the rotor, to ensure a safe operation of the pump.