A Piezocomposite Solid-State Rotor: Theoretical Analysis of Thrust and Efficiency Metrics

ASME 2019 Conference on Smart Materials, Adaptive Structures and Intelligent Systems Pub Date : 2019-12-05 DOI:10.1115/smasis2019-5558

Taís Carneiro Ferreira de Castro, O. Bilgen

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Abstract

This paper presents a summary on the ongoing research and development of a solid-state piezoelectric composite rotor design for use in rotary systems. The paper focuses on the theoretical analysis of a two-bladed rotor with varying parameters such as flight speed, blade pitch angle, and rotational speed. XROTOR, a blade element method based software, is used for analysis. The two-dimensional aerodynamic characteristics are acquired from the previous research on a Macro-Fiber Composite actuated simply supported thin airfoil. A set of simulations are conducted to determine the best geometric configuration, so the piezoelectric increase in thrust is maximized. The proposed hub-rotor system has the potential to be implemented in unmanned-aerial-vehicles such as single-rotor, tandem-rotor, multi-copter, and ducted-fan rotorcraft, or other rotating systems such as wind turbines, turbine engines, and marine propellers. This paper presents a summary of previous findings on a solid-state rotor prototype, and a new investigation on the theoretical aerodynamic behavior.

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一种压电复合材料固态转子:推力和效率指标的理论分析

本文综述了用于旋转系统的固态压电复合转子设计的研究和发展。本文主要对飞行速度、桨叶俯仰角和转速等参数变化时的双叶旋翼进行了理论分析。采用基于叶片单元法的XROTOR软件进行分析。通过对宏纤维复合材料驱动简支薄翼型的研究，获得了二维气动特性。通过一组仿真来确定最佳几何构型，使压电式推力增量最大化。所提出的轮毂-旋翼系统有潜力应用于无人飞行器，如单旋翼、串联旋翼、多旋翼和导管风扇旋翼机，或其他旋转系统，如风力涡轮机、涡轮发动机和船用螺旋桨。本文综述了固态转子原型机的研究成果，并对其理论气动性能进行了新的研究。

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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ASME 2019 Conference on Smart Materials, Adaptive Structures and Intelligent Systems

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