MODELING STIFFNESS LOSS IN QUASI-ISOTROPIC LAMINATES DUE TO MICROSTRUCTURAL DAMAGE Academic Article

abstract

• Continuous fiber laminated composites are known to undergo substantial load induced damage in the form of matrix cracking, interior delamination, fiber fracture, etc. These damage modes produce significant losses in component performance measures such as stiffness, residual strength, and life. The authors have previously constructed a general model for predicting the response of laminated composites with damage. The current paper utilizes the model to predict stiffness loss as a function of damage in quasi-isotropic and angle-ply laminates with matrix cracks. It is shown that the model is capable of predicting the stiffness loss for any layup by utilizing the same input data, thus producing a model which is independent of stacking sequence. The favorable comparisons of the model to experimental results reported herein support the validity of the model.

authors

• Allen, David

published proceedings

• JOURNAL OF ENGINEERING MATERIALS AND TECHNOLOGY-TRANSACTIONS OF THE ASME

author list (cited authors)

• HARRIS, C. E., ALLEN, D. H., NOTTORF, E. W., & GROVES, S. E.

citation count

• 11

complete list of authors

• HARRIS, CE||ALLEN, DH||NOTTORF, EW||GROVES, SE

publication date

• January 1988

publisher

• ASME International  Publisher

published in

• Journal of Engineering Materials and Technology  Journal

Digital Object Identifier (DOI)

• 10.1115/1.3226020

start page

• 128

end page

• 133

volume

• 110

issue

• 2

URL

• http://dx.doi.org/10.1115/1.3226020