Influence of the insertion of shape memory wires in composite materials on impact response

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Publicado en:	Archives of Civil and Mechanical Engineering vol. 24, no. 4 (Nov 2024), p. 240
Autor principal:	Junqueira, Diego Morais
Otros Autores:	Gomes, Guilherme Ferreira, Silveira, Márcio Eduardo, Ancelotti Jr., Antonio Carlos
Publicado:	Springer Nature B.V.
Materias:	Mechanical properties Finite element method Resin transfer molding Smart materials Wire Design of experiments Epoxy resins Mathematical analysis Impact tests Dynamic mechanical analysis Glass-epoxy composites Energy Nickel base alloys Computer simulation Composite materials Crystal structure Fiberglass Design analysis Polymers Carbon fibers Alloying elements Impact strength Energy absorption Temperature Intermetallic compounds Glass fiber reinforced plastics Martensitic transformations Polymer matrix composites Impact analysis Impact response Mathematical models Resin matrix composites Deformation Alloys Shape memory alloys Crashworthiness
Acceso en línea:	Citation/Abstract Full Text Full Text - PDF
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024	7		\|a 10.1007/s43452-024-01049-7 \|2 doi
035			\|a 3111371139
045	2		\|b d20241101 \|b d20241130
100	1		\|a Junqueira, Diego Morais \|u Federal University of Itajubá-UNIFEI, Mechanical Engineering Institute, Itajubá, Brazil (GRID:grid.440561.2) (ISNI:0000 0000 8992 4656)
245	1		\|a Influence of the insertion of shape memory wires in composite materials on impact response
260			\|b Springer Nature B.V. \|c Nov 2024
513			\|a Journal Article
520	3		\|a In recent decades, the quest for high-performance materials—those that combine low weight with high mechanical strength—has intensified. A promising solution involves composites reinforced with fiber and a polymeric matrix. However, these composite materials often exhibit deficiencies in crashworthiness. To address this issue, we investigated the incorporation of shape memory alloys, specifically nickel–titanium (NiTi), into the laminate structure. This study aimed to develop an equation, using a design of experiments approach, capable of predicting the energy absorption capacity of fiberglass and epoxy resin matrix composites upon impact, with integrated NiTi wires. Additionally, we proposed a model through numerical simulation using the finite element method to correlate with experimental analyses, thereby establishing a reliable model for future research. We selected the appropriate NiTi alloy (martensitic or superelastic) for the impact specimens through a full factorial design and dynamic mechanical analysis. After choosing the statistically superior superelastic wire, we manufactured test specimens using vacuum assisted resin transfer molding. These specimens, designed with three variables (diameter, spacing, and position in the laminate), followed a fractional factorial design. The drop-weight impact tests, conducted according to the ASTM D7136 standard, demonstrated increased energy absorption when NiTi wire was included in the composite. A non-linear numerical simulation (dynamic analysis) was performed, and its results—showing an excellent correlation with experimental data (above 95%)—validated the model.
653			\|a Mechanical properties
653			\|a Finite element method
653			\|a Resin transfer molding
653			\|a Smart materials
653			\|a Wire
653			\|a Design of experiments
653			\|a Epoxy resins
653			\|a Mathematical analysis
653			\|a Impact tests
653			\|a Dynamic mechanical analysis
653			\|a Glass-epoxy composites
653			\|a Energy
653			\|a Nickel base alloys
653			\|a Computer simulation
653			\|a Composite materials
653			\|a Crystal structure
653			\|a Fiberglass
653			\|a Design analysis
653			\|a Polymers
653			\|a Carbon fibers
653			\|a Alloying elements
653			\|a Impact strength
653			\|a Energy absorption
653			\|a Temperature
653			\|a Intermetallic compounds
653			\|a Glass fiber reinforced plastics
653			\|a Martensitic transformations
653			\|a Polymer matrix composites
653			\|a Impact analysis
653			\|a Impact response
653			\|a Mathematical models
653			\|a Resin matrix composites
653			\|a Deformation
653			\|a Alloys
653			\|a Shape memory alloys
653			\|a Crashworthiness
700	1		\|a Gomes, Guilherme Ferreira \|u Federal University of Itajubá-UNIFEI, Mechanical Engineering Institute, Itajubá, Brazil (GRID:grid.440561.2) (ISNI:0000 0000 8992 4656)
700	1		\|a Silveira, Márcio Eduardo \|u Federal University of São João del Rei-UFSJ, Department of Mechanical Engineering, São João del Rei, Brazil (GRID:grid.428481.3) (ISNI:0000 0001 1516 3599)
700	1		\|a Ancelotti Jr., Antonio Carlos \|u Federal University of Itajubá-UNIFEI, Mechanical Engineering Institute, Itajubá, Brazil (GRID:grid.440561.2) (ISNI:0000 0000 8992 4656)
773	0		\|t Archives of Civil and Mechanical Engineering \|g vol. 24, no. 4 (Nov 2024), p. 240
786	0		\|d ProQuest \|t Engineering Database
856	4	1	\|3 Citation/Abstract \|u https://www.proquest.com/docview/3111371139/abstract/embedded/7BTGNMKEMPT1V9Z2?source=fedsrch
856	4	0	\|3 Full Text \|u https://www.proquest.com/docview/3111371139/fulltext/embedded/7BTGNMKEMPT1V9Z2?source=fedsrch
856	4	0	\|3 Full Text - PDF \|u https://www.proquest.com/docview/3111371139/fulltextPDF/embedded/7BTGNMKEMPT1V9Z2?source=fedsrch