APPLICATION OF IMPOSED MOTION METHOD FOR MODEL FLUTTER TESTS IN HIGH-SPEED WIND TUNNELS

Boris D. Bryantsev

DOI Number: N/A

Conference number: IFASD-2015-138

A brief background on Frequency Response Functions (FRFs) measurement technology applied to mechanical systems on the basis of imposed motion method (kinematic excitation method) is presented herein. Shown is the possibility to use analysis to evaluate an effect of adding extra concentrated mass, stiffness and damping, in the points of application of driving forces, on the FRFs of a tested article with use of experimental FRFs of initial unmodified structure as a reference. The capabilities of the technology for flutter research are demonstrated by the example of GVT of a dynamically-scaled model of an all-movable stabilizer intended for flutter wind tunnel tests, with an electro hydraulic actuator used to impose model displacement in the driving point. The test techniques, as well as details of measuring FRFs under wind tunnel flow conditions with the use of specific multi-sine test signal for structure excitation are described. Presented are examples of measured in-flow model FRFs, and identified modal data as a function of flow parameters, including eigenfrequencies, eigendamping and eigenmodes recovered for unmodified model (free of the links imposed by the actuator) at flow speed beyond flutter boundary.

Read the full paper here

Aeroelasticity, flutter, frequency response functions, wind tunnel

In Categories: 2. IFASD 2015, Poster presentations

The paper above was part of proceedings of a CEAS event and as such the author has signed a publication agreement to have their paper published in the repository. In the case this paper is found somewhere else CEAS always links to the other source. CEAS takes great care in making the correct content available to the reader. If any mistakes are found in the listings please contact us directly at papers@aerospacerepository.org and we will correct the listing promptly. CEAS cannot be held liable either for mistakes in editorial or technical aspects, nor for omissions, nor for the correctness of the content. In particular, CEAS does not guarantee completeness or correctness of information contained in external websites which can be accessed via links from CEAS’s websites. Despite accurate research on the content of such linked external websites, CEAS cannot be held liable for their content. Only the content providers of such external sites are liable for their content. Should you notice any mistake in technical or editorial aspects of the CEAS site, please do not hesitate to inform us.