Designing a High Speed Morphing Rotor Blade

Proceedings of the Vertical Flight Society 77th Annual Forum Pub Date : 2021-05-10 DOI:10.4050/f-0077-2021-16710

A. Kuczek, F. Gandhi, Daniel V. Camp, Z. Chaudhry, Wenping Zhao

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Abstract

High speed rotorcraft experience regions of reverse flow over the inboard sections of blades. In these regions, because of the reverse flow, the rotor blade experiences high drag, large dynamic pitching moments, and the resulting significant vibrations. If the shape of the rotor can be changed “morphed” in the inboard section, a number of these adverse effects can be minimized. This paper outlines the approach to morphing the rotor blade to achieve two desired shapes suited for hover and forward flight. Different elements and associated risk reduction of the morphing system are discussed in details. A key element of a successful morphing structure is a flexible skin which can change shape and at the same time maintain rigidity and stiffness. The approach to achieving these conflicting goals through interleaved and off set layers of elastomers and composite sections, all co-cured in one step, is described. In addition an actuation approach and associated kinematics to achieve the shape change while minimizing actuation forces is also described. Assembly of the full-scale (in the chord-wise direction) prototype hardware of an 18% thick SC325218 airfoil is also included.

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高速变形转子叶片的设计

高速旋翼机经历了叶片内侧部分的逆流区域。在这些区域，由于反向流动，转子叶片经历高阻力，大的动态俯仰力矩，并由此产生显著的振动。如果转子的形状可以改变“变形”在板内部分，一些这些不利影响可以最小化。本文概述了旋翼叶片变形的方法，以获得适合悬停和前飞的两种理想形状。详细讨论了变形系统的不同元素和相关的风险降低。一个成功的变形结构的关键因素是一个灵活的皮肤，可以改变形状，同时保持刚性和刚度。本文描述了通过将弹性体和复合材料部分的交错层和偏移层在一步中共固化来实现这些相互冲突的目标的方法。此外，还描述了在最小化驱动力的同时实现形状变化的驱动方法和相关的运动学。一个18%厚SC325218翼型的全尺寸组装(在弦方向)原型硬件也包括在内。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the Vertical Flight Society 77th Annual Forum

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