TY - JOUR
T1 - The effect of fiber orientation on the formability and failure behavior of a woven self-reinforced composite
AU - Zanjani, Nima A.
AU - Wang, Wentian
AU - Kalyanasundaram, Shankar
N1 - Publisher Copyright:
© 2015 by ASME.
PY - 2015/10/1
Y1 - 2015/10/1
N2 - This article investigates the effect of fiber orientation on forming and failure behaviors of a preconsolidated woven self-reinforced polypropylene (SRPP) composite during the stamp-forming process. Specimens with different aspect ratios were employed to study their formability during forming through a hemispherical punch in an open die configuration. The strain evolution in specimens was captured using a real-time strain measurement system (the aramis). A forming limit diagram (FLD), inspired from metal forming, was constructed to investigate the failure onset in the woven composite. The FLD revealed dominant failure mechanisms in [0 deg,90 deg] specimens were yarn splitting and fiber fracture as depicted by optical microscopy. A modified FLD was proposed to investigate failure mechanisms in [45 deg,-45 deg] samples. It was shown that delamination and intralaminar shear are the main causes of failure in this set of specimens. The outcomes of this study suggest that by changing forming parameters, such as fiber orientation, boundary condition, and aspect ratio, the formability of a preconsolidated SRPP can be improved. These results show the possibility of producing cost-effective, flawless, and fully recyclable products from consolidated woven composites. The proposed criterion can accurately predict failure in a woven composite by considering the combined strain interactions. This is reflected in the implementation of induced deformation modes and strain history into the failure criterion, making it a practical measure for rapid manufacturing techniques, such as stamping. The novel path-dependent failure criterion, introduced in this study, attempts to fill the gap for a reliable and accurate failure measure for woven composites.
AB - This article investigates the effect of fiber orientation on forming and failure behaviors of a preconsolidated woven self-reinforced polypropylene (SRPP) composite during the stamp-forming process. Specimens with different aspect ratios were employed to study their formability during forming through a hemispherical punch in an open die configuration. The strain evolution in specimens was captured using a real-time strain measurement system (the aramis). A forming limit diagram (FLD), inspired from metal forming, was constructed to investigate the failure onset in the woven composite. The FLD revealed dominant failure mechanisms in [0 deg,90 deg] specimens were yarn splitting and fiber fracture as depicted by optical microscopy. A modified FLD was proposed to investigate failure mechanisms in [45 deg,-45 deg] samples. It was shown that delamination and intralaminar shear are the main causes of failure in this set of specimens. The outcomes of this study suggest that by changing forming parameters, such as fiber orientation, boundary condition, and aspect ratio, the formability of a preconsolidated SRPP can be improved. These results show the possibility of producing cost-effective, flawless, and fully recyclable products from consolidated woven composites. The proposed criterion can accurately predict failure in a woven composite by considering the combined strain interactions. This is reflected in the implementation of induced deformation modes and strain history into the failure criterion, making it a practical measure for rapid manufacturing techniques, such as stamping. The novel path-dependent failure criterion, introduced in this study, attempts to fill the gap for a reliable and accurate failure measure for woven composites.
KW - failure
KW - fiber orientation
KW - forming
KW - woven thermoplastic composite
UR - http://www.scopus.com/inward/record.url?scp=84941076964&partnerID=8YFLogxK
U2 - 10.1115/1.4030894
DO - 10.1115/1.4030894
M3 - Article
SN - 1087-1357
VL - 137
JO - Journal of Manufacturing Science and Engineering
JF - Journal of Manufacturing Science and Engineering
IS - 5
M1 - 051012
ER -