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AuthorAbdulqadir, Samer Fakhri; Tarlochan, Faris
Available date2023-01-26T07:03:28Z
Publication Date2022
Publication NameMaterials
ResourceScopus
URIhttp://dx.doi.org/10.3390/ma15031084
URIhttp://hdl.handle.net/10576/38890
AbstractRegarding crashworthiness, many published works have focused on designing thinwalled structures for frontal collisions compared to side-impact collisions. This paper presents an experimental investigation and finite element modelling of a carbon-reinforced thin-walled tophat section subjected to quasi-static and dynamic transverse bending loads at different impact speeds. The top-hat sections and their closure assembly plates were made of MTM44 prepreg carbon. The specimens were manufactured by vacuum bagging. Dynamic work was performed to validate the results obtained from the finite element analysis (FEA). The predicted results are in good agreement with the experimental results. The study also showed that the peak load and energy absorption owing to dynamic loading were higher than those under static loading. In the four-point bend analysis, the stacking sequence affected the energy absorption capabilities by 15-30%. In addition, the distance between the indenters in the four-point analysis also affected the energy absorption by 10% for the same impact condition, where a larger distance promoted higher energy absorption. The study also demonstrated that a top-hat shaped thin-walled structure is suitable for deep intrusion beams in vehicle doors for side-impact crashworthiness applications. 2022 by the authors. Licensee MDPI, Basel, Switzerland.
SponsorAcknowledgments: This study was financially supported by the Council for the At Risk Academy (CARA). The authors would like to acknowledge the University of Warwick and Warwick manufacturing group (WMG) and the staff for providing full support, equipment, and facilities to complete this research. In addition, we appreciate the Sika Power Company for providing the adhesives necessary for this investigation. The authors would also like to thank the Qatar National Research Fund for supporting this open-access publication fee.
Languageen
PublisherMDPI
SubjectBending collapse
Composite material
Door intrusion beam
Energy absorption
Top-hat section
TitleComposite Hat Structure Design for Vehicle Safety: Potential Application to B-Pillar and Door Intrusion Beam
TypeArticle
Issue Number3
Volume Number15
dc.accessType Open Access


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