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ABSTRACT
An identification algorithm for the estimation of residual unbalances is developed for a flexible rotor-bearing system integrated with an active magnetic bearing (AMB). The main advantage of the present methodology is that it can be applied in situ and also with safe traversal of resonances during run-up. The flexible rotor-AMB system is modelled by the finite element method, considering randomly distributed residual unbalances along with disc discrete residual unbalances. In order to obtain equivalent discrete unbalances at limited disc locations for the balancing of the flexible rotor system, a generalized influence coefficient method (GICM) is proposed. Equivalent unbalances obtained at discrete balancing planes are used to check the reduction in unbalance responses. The proposed algorithm is compared with the conventional influence coefficient method (CICM) without AMB to check the accuracy and consistency of the estimated values of residual unbalances. The values estimated by both methods are found to be consistent, while the GICM has an advantage of using AMB for the safe operation of the unbalanced rotor at high speeds during measurements. In order to have a suitable discrete position of AMB (for effective estimation of residual unbalances), various rotor system models are considered with different positions of the AMB.
Disclosure statement
No potential conflict of interest was reported by the authors.