Development of a Topology Optimization Method for the Design of Composite Lattice Ring Structures

Zheng Hu, Oleksii Vambol, Shiping Sun, Q. Zeng
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引用次数: 1

Abstract

Composite lattice ring structures are known for their lightweight and high efficiency, which have a strong attraction in the aeronautical and aerospace industries. The general manufacturing process for such structures is to use wet filament winding technology. Due to the anisotropic properties of continuous fibers, the filament winding trajectory determines the mechanical properties of the composite lattice ring structures. In this work, a topology optimization method is proposed to generate the efficient filament winding trajectory, which follows the load transfer path of the composite part and can offer higher mechanical strengths. To satisfy the periodicity requirement of the structure, the design space is divided into a prescribed number of identical substructures during the topology optimization process. In order to verify the effectiveness and capability of the proposed approach, the topological design of ring structures with the different number of substructures, the ratio of outer to inner radius and the loading case is investigated. The results reflect that the optimal topology shape strongly depends on the substructure numbers, radius ratio and loading case. Moreover, the compliance of the optimized structures increases with the total number of substructures, while the structural efficiency of the optimized structures decreases with the radius ratio. Finally, taking the specified topological structure as the object, the conceptual design of a robotic filament winding system for manufacturing the composite lattice ring structure is presented. In particular, the forming tooling, integrated deposition system, winding trajectory and manufacturing process are carefully defined, which can provide valuable references for practical production in the future
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复合材料晶格环结构拓扑优化设计方法的发展
复合材料晶格环结构以其轻量化和高效率而闻名,在航空航天工业中具有很强的吸引力。这种结构的一般制造工艺是使用湿丝缠绕技术。由于连续纤维的各向异性,长丝缠绕轨迹决定了复合材料晶格环结构的力学性能。本文提出了一种拓扑优化方法,以生成符合复合材料零件载荷传递路径的高效缠绕轨迹,并能提供更高的机械强度。在拓扑优化过程中,为满足结构的周期性要求,将设计空间划分为规定数量的相同子结构。为了验证所提方法的有效性和能力,研究了不同子结构数、不同内外半径比和不同载荷情况下环形结构的拓扑设计。结果表明,最优拓扑形状在很大程度上取决于子结构数、半径比和载荷情况。优化后结构的柔度随子结构总数的增加而增加,而结构效率随半径比的减小而降低。最后,以指定的拓扑结构为对象,提出了制造复合材料晶格环结构的机器人缠绕系统的概念设计。特别是对成形工具、综合沉积系统、缠绕轨迹和制造工艺进行了详细的定义,为今后的实际生产提供了有价值的参考
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