Mazzotti, Matteo
(2013)
Numerical methods for the dispersion analysis of Guided Waves, [Dissertation thesis], Alma Mater Studiorum Università di Bologna.
Dottorato di ricerca in
Ingegneria strutturale ed idraulica, 25 Ciclo. DOI 10.6092/unibo/amsdottorato/5951.
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Abstract
The use of guided ultrasonic waves (GUW) has increased considerably in the fields of non-destructive (NDE) testing and structural health monitoring (SHM) due to their ability to perform long range inspections, to probe hidden areas as well as to provide a complete monitoring of the entire waveguide.
Guided waves can be fully exploited only once their dispersive properties are known for the given waveguide.
In this context, well stated analytical and numerical methods are represented by the Matrix family methods and the Semi Analytical Finite Element (SAFE) methods.
However, while the former are limited to simple geometries of finite or infinite extent, the latter can model arbitrary cross-section waveguides of finite domain only.
This thesis is aimed at developing three different numerical methods for modelling wave propagation in complex translational invariant systems.
First, a classical SAFE formulation for viscoelastic waveguides is extended to account for a three dimensional translational invariant static prestress state. The effect of prestress, residual stress and applied loads on the dispersion properties of the guided waves is shown.
Next, a two-and-a-half Boundary Element Method (2.5D BEM) for the dispersion analysis of damped guided waves in waveguides and cavities of arbitrary cross-section is proposed. The attenuation dispersive spectrum due to material damping and geometrical spreading of cavities with arbitrary shape is shown for the first time.
Finally, a coupled SAFE-2.5D BEM framework is developed to study the dispersion characteristics of waves in viscoelastic waveguides of arbitrary geometry embedded in infinite solid or liquid media. Dispersion of leaky and non-leaky guided waves in terms of speed and attenuation, as well as the radiated wavefields, can be computed.
The results obtained in this thesis can be helpful for the design of both actuation and sensing systems in practical application, as well as to tune experimental setup.
Abstract
The use of guided ultrasonic waves (GUW) has increased considerably in the fields of non-destructive (NDE) testing and structural health monitoring (SHM) due to their ability to perform long range inspections, to probe hidden areas as well as to provide a complete monitoring of the entire waveguide.
Guided waves can be fully exploited only once their dispersive properties are known for the given waveguide.
In this context, well stated analytical and numerical methods are represented by the Matrix family methods and the Semi Analytical Finite Element (SAFE) methods.
However, while the former are limited to simple geometries of finite or infinite extent, the latter can model arbitrary cross-section waveguides of finite domain only.
This thesis is aimed at developing three different numerical methods for modelling wave propagation in complex translational invariant systems.
First, a classical SAFE formulation for viscoelastic waveguides is extended to account for a three dimensional translational invariant static prestress state. The effect of prestress, residual stress and applied loads on the dispersion properties of the guided waves is shown.
Next, a two-and-a-half Boundary Element Method (2.5D BEM) for the dispersion analysis of damped guided waves in waveguides and cavities of arbitrary cross-section is proposed. The attenuation dispersive spectrum due to material damping and geometrical spreading of cavities with arbitrary shape is shown for the first time.
Finally, a coupled SAFE-2.5D BEM framework is developed to study the dispersion characteristics of waves in viscoelastic waveguides of arbitrary geometry embedded in infinite solid or liquid media. Dispersion of leaky and non-leaky guided waves in terms of speed and attenuation, as well as the radiated wavefields, can be computed.
The results obtained in this thesis can be helpful for the design of both actuation and sensing systems in practical application, as well as to tune experimental setup.
Tipologia del documento
Tesi di dottorato
Autore
Mazzotti, Matteo
Supervisore
Co-supervisore
Dottorato di ricerca
Scuola di dottorato
Ingegneria civile ed architettura
Ciclo
25
Coordinatore
Settore disciplinare
Settore concorsuale
Parole chiave
semi-analytical finite element method, boundary element method, leaky guided waves, leakage, prestress,
URN:NBN
DOI
10.6092/unibo/amsdottorato/5951
Data di discussione
31 Maggio 2013
URI
Altri metadati
Tipologia del documento
Tesi di dottorato
Autore
Mazzotti, Matteo
Supervisore
Co-supervisore
Dottorato di ricerca
Scuola di dottorato
Ingegneria civile ed architettura
Ciclo
25
Coordinatore
Settore disciplinare
Settore concorsuale
Parole chiave
semi-analytical finite element method, boundary element method, leaky guided waves, leakage, prestress,
URN:NBN
DOI
10.6092/unibo/amsdottorato/5951
Data di discussione
31 Maggio 2013
URI
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