Structural Design and Properties of Carbon Fiber-Reinforced Sandwich Composites with Small-Angle Grid
Mengyu Wang, Yonglian Sun, Weiwei Zhao, Xiao Wu, Mingyu Wang, Hailing Cong, Fayuan Pang, Huawei Jiang, Shaokai Hu, Kun Qiao

TL;DR
This study explores how adjusting the core angle in carbon fiber sandwich composites affects their bending and compression performance, showing improved strength and deformation resistance.
Contribution
The paper introduces small-angle grid sandwich structures that combine benefits of 2D and 3D lattice designs, offering enhanced mechanical performance.
Findings
Small-angle grid structures show better anti-deformation performance than 2D periodic structures and are easier to form than 3D lattices.
Bending failure load increases by 33.2–71.9% when core angle is reduced from 90° to 60° at core heights of 6–10 mm.
Core shear failure dominates in bending, while core wrinkling and collapse are main failure modes in flat compression.
Abstract
This paper designs and fabricates small-angle grid sandwich composites and carbon fiber composite panels by adjusting core support angles, integrating the advantages of two-dimensional (2D) periodic and three-dimensional (3D) lattice sandwich structures. The effects of core angle and height on the bending and flatwise compression performance of the composites are investigated, and finite element simulations are conducted via ABAQUS to verify experimental results and comprehensively analyze failure mechanisms. The results show that the small-angle grid sandwich structures exhibit better anti-deformation performance than 2D periodic sandwich structures and are easier to form than 3D lattice sandwich structures. The bending properties of composites with small-angle grid core are superior to those with 90° 2D periodic cores, and core shear failure is the dominant failure mode. At the same…
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Taxonomy
TopicsCellular and Composite Structures · Composite Structure Analysis and Optimization · Mechanical Behavior of Composites
