Abstract
Due to trends in aero-design, aeroelasticity becomes increasingly important in modern turbomachines. Design requirements of turbomachines lead to the development of high aspect ratio blades and blade integral disc designs (blisks), which are especially prone to complex modes of vibration. Therefore, experimental investigations yielding high quality data are required for improving the understanding of aeroelastic effects in turbomachines. One possibility to achieve high quality data is to excite and measure blade vibrations in turbomachines. The major requirement for blade excitation and blade vibration measurements is to minimize interference with the aeroelastic effects to be investigated. Thus in this paper, a non-contact—and thus low interference—experimental set-up for exciting and measuring blade vibrations is proposed and shown to work. A novel acoustic system excites rotor blade vibrations, which are measured with an optical tip-timing system. By performing measurements in an axial compressor, the potential of the acoustic excitation method for investigating aeroelastic effects is explored. The basic principle of this method is described and proven through the analysis of blade responses at different acoustic excitation frequencies and at different rotational speeds. To verify the accuracy of the tip-timing system, amplitudes measured by tip-timing are compared with strain gage measurements. They are found to agree well. Two approaches to vary the nodal diameter (ND) of the excited vibration mode by controlling the acoustic excitation are presented. By combining the different excitable acoustic modes with a phase-lag control, each ND of the investigated 30 blade rotor can be excited individually. This feature of the present acoustic excitation system is of great benefit to aeroelastic investigations and represents one of the main advantages over other excitation methods proposed in the past. In future studies, the acoustic excitation method will be used to investigate aeroelastic effects in high-speed turbomachines in detail. The results of these investigations are to be used to improve the aeroelastic design of modern turbomachines.
Highlights
The first time engineers encountered serious problems caused by aeroelasticity in the field of manned aviation was when phenomena like divergence and flutter resulted in rapid structural failure of the wing
All results presented below are based on the excitation and analysis of the first bending mode of the low-speed axial compressor (LSAC) rotor blades
The results presented in table 5 are based on the excitation of the acoustic modes characterized by m = 8 and m = 16
Summary
The first time engineers encountered serious problems caused by aeroelasticity in the field of manned aviation was when phenomena like divergence and flutter resulted in rapid structural failure of the wing. Since those days, great effort has been made to predict and reduce the risk of failure caused by aeroelastic effects in manned aviation and other applications of turbomachinery. The most dominant driver of these developments is the ambition to achieve power density For jet engines, this leads to higher aerodynamic loading due to the effort to reduce weight by decreasing the number of stages. Transonic flow makes modern turbomachines compact and prone to shocks and flow separation, increasing the risk of blade failure by flutter
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