Structural Response and Remaining Life of Damaged Composites

Dalbir Singh; C. Ganesan; A. Rajaraman

doi:10.4028/www.scientific.net/AMM.813-814.106

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 813-814Structural Response and Remaining Life of Damaged...

Structural Response and Remaining Life of Damaged Composites

Abstract:

Composites are being used in variety of applications ranging from defense and aircraft structures, where usage is profuse, to vehicle structures and even for repair and rehabilitation. Most of these composites are made of different laminates glued together with matrix for binding and now-a-days fibers of different types are embedded in a composite matrix. The characterizations of material properties of composites are mostly experimental with analytical modeling used to simulate the system behavior. But many times, the composites develop damage or distress in the form of cracking while they are in service and this adds a different dimension as one has to evaluate the response with the damage so that its performance during its remaining life is satisfactory. This is the objective of the present study where a hybrid approach using experimental results on damaged specimens and then analytical finite element are used to evaluate response. This will considerably help in remaining life assessment-RLA- for composites with damage so that design effectiveness with damage could be assessed. This investigation has been carried out on a typical composite with carbon fiber reinforcements, manufactured by IPCL Baroda (India) with trade name INDCARF-30. Experimental studies were conducted on undamaged and damaged specimens to simulate normal continuous loading and discontinuous loading-and-unloading states in actual systems. Based on the experimental results, material characterization inputs are taken and analytical studies were carried out using ANSYS to assess the response under linear and nonlinear material behavior to find the stiffness decay. Using stiffness decay RLA was computed and curves are given to bring the influence of type of damage and load at which damage had occurred.

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Periodical:

Applied Mechanics and Materials (Volumes 813-814)

Pages:

106-110

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.813-814.106

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Online since:

November 2015

Authors:

Dalbir Singh, C. Ganesan, A. Rajaraman

Keywords:

Composites, Cracking, Damage, Experimental Tests, Finite Element Analysis, Remaining Life Assessment

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