Abstract
Verification of the behaviour of new designs of rotor seals is a crucial phase necessary for their use in rotary machines. Therefore, experimental equipment for the verification of properties that have an effect on rotor dynamics is being developed in the test laboratories of the manufacturers of these components all over the world. In order to be able to compare the analytically derived and experimentally identified values of the seal parameters, specific requirements for the rotor vibration pattern during experiments are usually set. The rotor vibration signal must contain the specified dominant components, while the others, usually caused by unbalance, must be attenuated. Technological advances have made it possible to use magnetic bearings in test equipment to support the rotor and as a rotor vibration exciter. Active magnetic bearings allow control of the vibrations of the rotor and generate the desired shape of the rotor orbit. This article presents a solution developed for a real test rig equipped with active magnetic bearings and rotor vibration sensors, which is to be used for testing a new design of rotor seals. Generating the exact shape of the orbit is challenging. The exact shape of the rotor orbit is necessary to compare the experimentally and numerically identified properties of the seal. The generalized notch filter method is used to compensate for the undesired harmonic vibrations. In addition, a novel modified generalized notch filter is introduced, which is used for harmonic vibration generation. The excitation of harmonic vibration of the rotor in an AMB system is generally done by injecting the harmonic current into the control loop of each AMB axis. The motion of the rotor in the AMB axis is coupled, therefore adjustment of the amplitudes and phases of the injected signals may be tedious. The novel general notch filter algorithm achieves the desired harmonic vibration of the rotor automatically. At first, the general notch filter algorithm is simulated and the functionality is confirmed. Finally, an experimental test device with an active magnetic bearing is used for verification of the algorithm. The measured data are presented to demonstrate that this approach can be used for precise rotor orbit shape generation by active magnetic bearings.
Highlights
Under certain circumstances, rotor vibrations in a steam turbine can cause rotor instability
The main idea of this paper is to show that the active vibration compensation algorithm for active magnetic bearing (AMB) rotor system based on a general notch filter can be successfully used for generating precise rotor orbit during rotordynamic experiments
A known general notch filter algorithm (GNF) algorithm was used for the unbalance compensation and simultaneously the novel modified GNF was introduced and used to generate the required rotor orbit
Summary
Rotor vibrations in a steam turbine can cause rotor instability. The advantage of active magnetic bearing (AMB) is the ability to control the vibrations of the rotor and to excite the desired shape of the rotor orbit (whirl). In [10], the general notch filter algorithm (GNF) is described and used to eliminate the synchronous magnetic force to prevent AMB amplifier dynamic saturation This unbalance compensation approach allows the rotor to spin around its inertia axis. The harmonic signals with proper amplitude and phase are injected into the control loop of each AMB axis in order to excite the required harmonic rotor vibration. The radial AMB can control the position of the rotor in the bearing plane in two orthogonal axes, x and y These axes are usually oriented at plus and minus 45 degrees from the vertical direction to distribute the gravitational force compensation uniformly between both differential drives. The unbalance signal is composed of one or more harmonic signals
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