- Docente: Mario Rosario Chiarelli
- Credits: 6
- SSD: ING-IND/04
- Language: Italian
- Teaching Mode: Traditional lectures
- Campus: Forli
- Corso: Second cycle degree programme (LS) in Aerospace Engineering (cod. 0229)
Learning outcomes
Construction and resolution capability of simplified analytical
model adopted to describe the dynamic behaviour of continuos
three-dimensional structures.
Critical analysis of geometrical and physical parameters effects on
the dynamics of mechanical systems.
Construction of simplified analytical models adopted to
investigate, in a preliminary way, static and dynamic aeroelastic
response of aerospace structures.
Course contents
Part I: Lectures and exercise
1. Engineering scheme of dynamic systems.
2. Dynamic degrees of freedom of continuous and/or discrete
structures.
3. Discussion of analytical solutions of one degree of freedom
oscillator.
4. The virtual work and the Lagrange theorems applied to
describe the equations of motion of elastic systems.
5. Preliminary explanation of the Rayleigh method.
6. Discrete systems with "n" degrees of freedom: equations of
motion, characteristic equation. Modal analysis of discrete
systems.
7. Continuos systems: string dynamics, membrane dynamics, beam
dynamics, plate dynamics.
8. Modal analysis of continuous systems: integral formulation
of the eigenvalues problem (assumed functions method).
9. Energetic approaches to dynamic problems: the Rayleigh-Ritz
method, the Faedo-Galerkin-Kantorovich method.
Part II: Lectures and exercise
1. Preliminary description of aeroelastic phenomena: static
divergence, loads redistribution, static aileron efficiency,
buffeting, flutter.
2. Torsional divergence of high aspect ratio unswept wings:
closed form solution of the problem.
3. Energetic approaches to the torsional divergence of high
aspect ratio unswept wings.
4. Aeroelastic effects on the symmetrical and unsymmetrical
lifting distribution for high aspect ratio unswept wings.
5. High aspect ratio swept wings: torsional and flexural
combined behaviour.
6. Static aeroelastic stability conditions for high aspect
ratio swept wings.
7. Detailed description and physical interpretation of lifting
surfaces flutter.
8. Calculation of aerodynamic loads in the case of two
dimensional unsteady motion: the delay Wagner function
method.
9. The Theodorsen method to determine the flutter condition of
a two dimensional rigid wing section: the case of two elastic
degrees of freedom.
10. Flutter analysis by means of the assumed functions method:
examinations of typical cases valid for traditional aircraft
configurations.
11. Numerical flutter analysis: flutter equation obtained
assuming as unknown the generalised co-ordinates.
12. Solution of flutter equation by means of numerical
methods: the p-k method and the non-linear direct method.
Readings/Bibliography
Dynamics of Structures - R.W. Clough, J. Penzien, Ed. McGraw-Hill, 1975.
Aeroelasticity - R.L. Bisplinghoff, H. Ashley and R.L. Halfman, 1996.
An introduction to the theory of aeroelasticity - Y.C. Fung, 1993.
Assessment methods
During the first examination phase student must resolve two
distinct exercises: a structural dynamics problem and a problem of
aeroelasticity (static or dynamic).
In the next phase it takes place a discussion of results obtained
by the student and some questions about theory (modal analysis and
aeroelasticity) will be asked.
Office hours
See the website of Mario Rosario Chiarelli