Title of article
Dynamic mixed-mode I/II delamination fracture and energy release rate of unidirectional graphite/epoxy composites
Author/Authors
Wosu، نويسنده , , Sylvanus N. and Hui، نويسنده , , David and Dutta، نويسنده , , Piyush K.، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2005
Pages
28
From page
1531
To page
1558
Abstract
Mixed-mode open-notch flexure (MONF), anti-symmetric loaded end-notched flexure (MENF) and center-notched flexure (MCNF) specimens were used to investigate dynamic mixed I/II mode delamination fracture using a fracturing split Hopkinson pressure bar (F-SHPB). An expression for dynamic energy release rate Gd is formulated and evaluated. The experimental results show that dynamic delamination increases linearly with mode mixing. At low input energy Ei ⩽ 4.0 J, the dynamic (Gd) and total (GT) energy rates are independent of mixed-mode ratio. At higher impact energy of 4.0 ⩽ Ei ⩽ 9.3 J, Gd decreases slowly with mixed I/II mode ratio while GT is observed to increase more rapidly. In general, Gd increases more rapidly with increasing delamination than with increasing energy absorbed. The results show that for the impact energy of 9.3 J before fragmentation of the plate, the effect of kinetic energy is not significant and should be neglected. For the same energy-absorption level, the delamination is greatest at low mixed-mode ratios corresponding to highest Mode II contribution. The results of energy release rates from MONF were compared with mixed-mode bending (MMB) formulation and show some agreement in Mode II but differences in prediction for Mode I. Hackle (Mode II) features on SEM photographs decrease as the impact energy is increased but increase as the Mode I/II ratio decreases. For the same loading conditions, more pure Mode II features are generated on the MCNF specimen fractured surfaces than the MENF and MONF specimens.
Keywords
Mixed mode , Delamination , energy release rate , Split Hopkinson pressure bar , Dynamic interlaminar fracture
Journal title
ENGINEERING FRACTURE MECHANICS
Serial Year
2005
Journal title
ENGINEERING FRACTURE MECHANICS
Record number
2341035
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