Your search keyword '"Rao, Mohan"' showing total 4 results

1. Vibration analysis of a multiple-layered viscoelastic structure using the Biot damping model

Author

Lin, Fei and Rao, Mohan D.

Subjects

Viscoelastic materials -- Mechanical properties, Viscoelastic materials -- Acoustic properties, Viscoelastic materials -- Testing, Vibration tests -- Methods, Vibration tests -- Technology application, Damping (Mechanics) -- Models, Technology application, Aerospace and defense industries, Business

Abstract

The viscoelastic damping treatment is a very popular method for attenuating vibration and noise problems. It provides the designer much flexibility in adjusting the system damping to eliminate resonances in the structures. A survey of the previous research on material damping models found inadequacies in developing the numerical models of multiple-layer constrained layers and the introduction of the combination of different viscoelastic damping materials through advanced frequency domain damping models. In this paper, a detailed numerical analysis and design of a multiple-layer constrained damping structure using the Biot damping model are presented to investigate the vibration performance. The nonlinear curve fitting of the complex shear modulus and the transient response solution of the numerical viscoelastic damping structure are also discussed. By the proposed approach, the simple beam problem that is presented can be easily extended to the industrial problem with arbitrary geometries and boundary conditions. The validation of this numerical approach is proven by comparison with the previous closed-form results. DOI: 10.2514/1.44339

Published

2010

2. Optimum design of multiple-constraint-layered systems for vibration control

Author

Hao, Min, Rao, Mohan D., and Schabus, Matthias H.

Subjects

Aerospace engineering -- Research, Aerospace and defense industries, Business

Abstract

An analytical formulation is presented for predicting the stiffness and damping of constrained layered beams that have multiple viscoelastic damping layers. A model is derived for symmetrical setups using variational methods. The equations to evaluate the stiffness and damping are derived in closed form and can be evaluated for different boundary conditions. The complex modulus approach is used to model the elastic and shear moduli of the viscoelastic material. A parametric analysis has been conducted to study the effects of different parameters on the damping and stiffness of the system under simply supported boundary conditions. The optimization process to obtain structural and material parameters maximizing system damping for a given temperature and frequency range is also presented.

Published

2004

3. Dynamic analysis and design of laminated composite beams with multiple damping layers

Author

Rao, Mohan D. and Shulin He

Subjects

Laminated materials -- Research, Damping (Mechanics) -- Research, Aerospace and defense industries, Business

Abstract

A model for the prediction of damping and natural frequencies of laminated composite beams with multiple viscoelastic damping layers was presented. The model takes the in-plane shear strains of the damping layers and the constraining layers into account. In addition, the model derives closed-form solutions for the resonance frequencies and modal loss factors of the composite beam system.

Published

1993

4. Vibration Analysis of a Multiple-Layered Viscoelastic Structure Using the Biot Damping Model.

Author

Fei Lin and Rao, Mohan D.

Subjects

*VIBRATION (Mechanics), *DAMPING (Mechanics), *RESONANCE, *NOISE, *OSCILLATIONS

Abstract

The viscoelastic damping treatment is a very popular method for attenuating vibration and noise problems. It provides the designer much flexibility in adjusting the system damping to eliminate resonances in the structures. A survey of the previous research on material damping models found inadequacies in developing the numerical models of multiple-layer constrained layers and the introduction of the combination of different viscoelastic damping materials through advanced frequency domain damping models. In this paper, a detailed numerical analysis and design of a multiple-layer constrained damping structure using the Biot damping model are presented to investigate the vibration performance. The nonlinear curve fitting of the complex shear modulus and the transient response solution of the numerical viscoelastic damping structure are also discussed. By the proposed approach, the simple beam problem that is presented can be easily extended to the industrial problem with arbitrary geometries and boundary conditions. The validation of this numerical approach is proven by comparison with the previous closed-form results. [ABSTRACT FROM AUTHOR]

Published

2010