Estimation of the Dynamic Properties of Epoxy Glass Fabric Composites with Natural Rubber Particle Inclusions

Authors

  • H. Ravi Sankar
  • R.R. Srikant
  • P. Vamsi Krishna
  • V. Bhujanga Rao
  • P. Bangaru Babu

DOI:

https://doi.org/10.15282/ijame.7.2012.13.0078

Keywords:

Composites; damping enhancement; artificial neural networks

Abstract

Conventional materials are being replaced in the field of engineering by composite materials, due to their tailorable properties and high specific properties. These materials are extensively used in structural applications. Damping is one of the important properties of the materials used in structures, and needs to be enhanced in order to reduce structural vibrations. In the present work, the  improvement of the material damping of glass fabric epoxy composites with particle rubber inclusions is studied. The effect of particle size on the damping and stiffness parameters at different frequencies and temperatures is studied experimentally. Considerable enhancement in damping without significant reduction in stiffness is observed at lower particle sizes. The damping property in both bending and shear modes is more with 0.254 mm rubber particle inclusions among the selected sizes. A lower reduction in stiffness is observed with the inclusion of lower particle sizes (0.254 mm and 0.09 mm) when compared with higher particle sizes. An ANN-based prediction model is developed to predict these properties for a given frequency/temperature and particle size. The predicted values are very close to the experimental values with an maximum error of 5%.

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Published

2022-12-09

How to Cite

[1]
H. Ravi Sankar, R.R. Srikant, P. Vamsi Krishna, V. Bhujanga Rao, and P. Bangaru Babu, “Estimation of the Dynamic Properties of Epoxy Glass Fabric Composites with Natural Rubber Particle Inclusions”, Int. J. Automot. Mech. Eng., vol. 7, pp. 968–980, Dec. 2022.

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