TY - JOUR
T1 - Experimental and numerical investigation of mode II failure behavior evaluation using three point bend, end notched flexure test
AU - Nikhil, R.
AU - Shivakumar, S.
AU - Anupama, Kallol
AU - Manjunath, Shettar
N1 - Publisher Copyright:
© The Authors, published by EDP Sciences, 2018.
PY - 2018/1/9
Y1 - 2018/1/9
N2 - In the present paper the primary task is the study involving calculation of elastic properties of the composite from the individual properties of the E-glass fiber (650 GSM) and the properties of resin LY 556 with Hardener HY951. The properties of varying volumetric ratio of fiber are obtained from calculation of the properties by using rule of mixtures. Experimentally validating the theoretical and numerical approaches by comparing the load-displacement response and crack paths observed in large scale bridged crack propagation in laminated fiber-reinforced composites specimens. An effort is being made to develop a numerical framework for cohesive crack propagation and demonstrating its effectiveness by simulating failure through crack propagation in materials with complex microstructure like fiber reinforced composites. Experimentally validating the theoretical and numerical approaches by comparing the load-displacement response and crack paths observed in large scale bridged crack propagation in laminated fiber-reinforced composites specimens.
AB - In the present paper the primary task is the study involving calculation of elastic properties of the composite from the individual properties of the E-glass fiber (650 GSM) and the properties of resin LY 556 with Hardener HY951. The properties of varying volumetric ratio of fiber are obtained from calculation of the properties by using rule of mixtures. Experimentally validating the theoretical and numerical approaches by comparing the load-displacement response and crack paths observed in large scale bridged crack propagation in laminated fiber-reinforced composites specimens. An effort is being made to develop a numerical framework for cohesive crack propagation and demonstrating its effectiveness by simulating failure through crack propagation in materials with complex microstructure like fiber reinforced composites. Experimentally validating the theoretical and numerical approaches by comparing the load-displacement response and crack paths observed in large scale bridged crack propagation in laminated fiber-reinforced composites specimens.
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U2 - 10.1051/matecconf/201714402009
DO - 10.1051/matecconf/201714402009
M3 - Conference article
AN - SCOPUS:85040648911
SN - 2261-236X
VL - 144
JO - MATEC Web of Conferences
JF - MATEC Web of Conferences
M1 - 02009
T2 - 2017 International Conference on Research in Mechanical Engineering Sciences, RiMES 2017
Y2 - 21 December 2017 through 23 December 2017
ER -