FEA of the On-Off Mechanism Piston Movement Impact Riku Raatikainen 4.7.2011
Introduction Model Description Boundary Conditions Results Conclusion INDEX Introduction Model Description Boundary Conditions Results Conclusion
INTRODUCTION The On-Off mechanism is a component for reflecting or transmitting the high RF power within PETS Mechanism is driven by a linear actuator, which creates the movement of the piston between the two operation modes The actuation time for the mechanism is ≤ 18 ms in which time the piston (150 g) moves inside the choke chamber for 8 mm The aim of this analysis is to study the impulsive shock phenomenon caused by the piston movement impact. Since the mechanism is brazed on the PETS Compact Coupler, forces created by the mechanism are directly interacted with the assembly ON OFF Main components of the mechanism Illustration of the piston movement
MODEL DESCRIPTION At this stage, the impact of impulsive force to the choke chamber (Copper) was modelled in order to see the magnitude of the shock wave travelling through the structure As the piston is being moved, the structure exposes to impulse forces, which last very short period of time but causes forces of a high magnitude Ideal impulse excites all modes of the structure → the response of the structure should contain all mode frequencies However we cannot create an ideal impulse force numerically → force is applied over a discrete amount of time Δt acceleration deceleration (0.89 m/s) Illustration of an idealized impulse Velocity of the moving piston
BOUNDARY CONDITIONS Fixed (brazed to the compact coupler body) Force is applied on the contact area, where the choke chamber is connected to the vacuum flanges by brazing
Deceleration of 9 ms (optimal) RESULTS Shock wave travelling through the structure once the piston has moved inside the choke chamber in two scenarios with a structural damping corresponding to relative damping of 3 % for the first modes: Piston is decelerated in Δt = 9 ms Piston is decelerated in Δt = 4 ms Deceleration of 9 ms (optimal) Deceleration of 4ms
CONCLUSION According to the results, the current model indicates forces of a magnitude of ̴15 N due to the impulse (for comparison the PETS weight itself ̴ 60 kg) The response of the structure (choke chamber) is in the order of nanometers The effect of the impulse decays in approximately 10 ms As a next step, the response of the PETS will be studied more closely (the impulse could excite critical modes of the PETS and thus, create a response exceeding the high precision tolerances) A possible PETS movement in case the impulse excites one or more frequencies of resonance