In the dynamics of turbomachinery, the mechanical damping of the blading has been the focus of research for the last decades to improve the dynamic performance in terms of high cycle fatigue issues. In addition, an increased mechanical damping can produce a higher flutter safety margin such that stable operation conditions are achievable in a bigger range. Hence, novel damping techniques are considered besides the well known friction based damping devices. In this paper, an extended analysis of the eddy current based damping device for a last stage steam turbine blading presented in GT2009-59593 is conducted. A transient electromagnetic finite element analysis of the eddy current damper is performed, and the resulting damping forces are compared to their analytical solution. Parameter studies are carried out, and equivalent damping factors are calculated. Furthermore, for the validation of the finite element model, a test rig was built that allows for the direct measurement of damping forces when forcing a sinusoidal relative motion. Forced response measurements and simulations are used to demonstrate its dynamic performance and predictability.

Issue Section:
Gas Turbines: Structures and Dynamics
Keywords:
blades, damping, eddy currents, finite element analysis, turbines
Topics:
Dampers, Damping, Eddies (Fluid dynamics), Finite element analysis, Finite element model, Permanent magnets, Eddy currents (Electricity), Turbines, Copper, Blades, Magnets, Transients (Dynamics)

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