This paper proposes a novel design methodology to synthesize flexure-based parallel manipulators (FPM) for high precision micro/nano-scale manipulation. Unlike traditional synthesis methods, the proposed method uses a structural optimization algorithm that is independent of human intuition, to synthesize compliant joints with optimal stiffness characteristics. This algorithm is able to evolve the topology and shape of the compliant joints. Based on finite element analysis, the synthesized compliant joints are able to achieve better stiffness characteristics than the traditional compliant joints. This allows the synthesized joints to achieve a large deflection range while maintaining their capabilities to resist external wrenches in the non-actuating directions. A planar motion FPM with a workspace of 4 mm2 × 2° is formed by assembling the optimal compliant joints. The actuating compliance of the joints and FPM are validated by experiments and their deviation between the experimental results and the simulation prediction are within 10% and 18% respectively.
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机译:本文提出了一种新颖的设计方法,用于合成基于挠性的平行机械手(FPM),用于高精度微/纳米尺度操纵。与传统的合成方法不同,所提出的方法使用与人的直觉无关的结构优化算法,以合成具有最佳刚度特性的柔性关节。该算法能够演化柔顺关节的拓扑和形状。基于有限元分析,合成的柔顺关节能够实现比传统兼容的关节更好的刚度特性。这允许合成的关节实现大的偏转范围,同时保持其能力来抵抗非致动方向上的外部扳手。平面运动FPM,工作区为4 mm 2 × 2°通过组装最佳柔顺的关节来形成。通过实验验证关节和FPM的致动依从性,并且实验结果与模拟预测之间的偏差分别在10%和18%以内。
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