Optimization of Pin Position and Angle for Z-Pin-Reinforced Foam Core Sandwich Structures

Optimization of Pin Position and Angle for Z-Pin-Reinforced Foam Core Sandwich Structures

Sandwich panels (SP) are very promising components for structures as they ally high levels of specific stiffness and strength. Civil, marine and automotive industries are some examples of the sectors that use SPs frequently. This work demonstrates the potential of manufacturing Z-pin-reinforced foam...

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Bibliographic Details
Published in:Materials Vol. 16; no. 1; p. 352
Main Authors: Kerche, Eduardo Fischer, Kairytė, Agnė, Członka, Sylwia, da Silva, Amanda Albertin Xavier, Tonatto, Maikson Luiz Passaia, Bresolin, Francisco Luiz, Delucis, Rafael de Avila, Amico, Sandro Campos
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 30-12-2022
MDPI
Subjects:
Algorithms
Analysis
Design
Design optimization
finite element analysis
Manufacturing
Mechanical properties
Optimization
Polyesters
Sandwich panels
Sandwich structures
Search algorithms
Stiffness
structure optimization
three-point bending test
Transportation equipment industry
vacuum bag
Brazil
vacuum bag
structure optimization
finite element analysis
three-point bending test
sandwich panels
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Summary:Sandwich panels (SP) are very promising components for structures as they ally high levels of specific stiffness and strength. Civil, marine and automotive industries are some examples of the sectors that use SPs frequently. This work demonstrates the potential of manufacturing Z-pin-reinforced foam core SPs, using a design strategy that indicated optimal values for both pin position and angle, keeping the same pin diameter as determined in a previous study. A simple search algorithm was applied to optimize each design, ensuring maximum flexural stiffness. Designs using optimal pin position, optimal pin angle and optimal values for both parameters are herein investigated using numerical and experimental approaches. The optimal pin position yielded an increase in flexural stiffness of around 8.0% when compared to the non-optimized design. In this same comparison, the optimal pin angle by itself increased the flexural stiffness by about 63.0%. Besides, the highest increase in the maximum load was found for those composites, molded with optimized levels of pin position and pin angle, which synergistically contributed to this result. All results were demonstrated with numerical and experimental results and there was a good agreement between them.
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ISSN:1996-1944
1996-1944
DOI:10.3390/ma16010352