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Developing a micro-macromechanical approach for evaluating long-term creep in composite cylinders
Abstract In most industries, composite materials have dominated the market compared with traditional materials and structures, due to their unique properties. Composite structures are usually subjected to long-term loading and experience creep phenomenon. In this study, an integrated modeling for evaluating long-term creep in cylindrical composite structures under constant loading is developed. The modeling procedure is performed at two levels of micro and macro comprising four distinct stages as modeling stress analysis at macro level, long-term creep analysis in pure resin, stress analysis at micro level for extending creep behavior of resin to lamina and updating constitutive relations of each layer. The modeling is in need of short-term creep tests on pure resin as input data and the long-term creep of the composite structure is evaluated for a period of 10,000 h as the output of the modeling. The developed modeling is validated on the basis of a long-term empirical study on a composite pipe subjected to compressive transverse loading. The very good agreement between experimental data and theoretical modeling is observed.
Highlights Integrated procedure is developed for modeling long-term creep in composites. Long-term creep in composites are predicted based on short-term creep behavior of pure resin. Long-term creep test on composite pipe under the transverse loading is simulated. The stress changes in the layers of composite pipe and its importance are studied. Updating constitutive equations, nonlinear viscoelastic behavior is estimated.
Developing a micro-macromechanical approach for evaluating long-term creep in composite cylinders
Abstract In most industries, composite materials have dominated the market compared with traditional materials and structures, due to their unique properties. Composite structures are usually subjected to long-term loading and experience creep phenomenon. In this study, an integrated modeling for evaluating long-term creep in cylindrical composite structures under constant loading is developed. The modeling procedure is performed at two levels of micro and macro comprising four distinct stages as modeling stress analysis at macro level, long-term creep analysis in pure resin, stress analysis at micro level for extending creep behavior of resin to lamina and updating constitutive relations of each layer. The modeling is in need of short-term creep tests on pure resin as input data and the long-term creep of the composite structure is evaluated for a period of 10,000 h as the output of the modeling. The developed modeling is validated on the basis of a long-term empirical study on a composite pipe subjected to compressive transverse loading. The very good agreement between experimental data and theoretical modeling is observed.
Highlights Integrated procedure is developed for modeling long-term creep in composites. Long-term creep in composites are predicted based on short-term creep behavior of pure resin. Long-term creep test on composite pipe under the transverse loading is simulated. The stress changes in the layers of composite pipe and its importance are studied. Updating constitutive equations, nonlinear viscoelastic behavior is estimated.
Developing a micro-macromechanical approach for evaluating long-term creep in composite cylinders
Rafiee, Roham (author) / Ghorbanhosseini, Amin (author)
Thin-Walled Structures ; 151
2020-03-04
Article (Journal)
Electronic Resource
English
A micro-macromechanical approach for composite laminates
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