An Analysis of Harmonic Airloads Acting on Helicopter Rotor Blades

Iftekhar A. Riyad, U. Chakravarty
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Abstract

Rotary wing aircrafts in any flight conditions suffer from excessive vibration which makes the passengers feel uncomfortable and causes fatigue failure in the structure. The main sources of vibration are the rotor harmonic airloads which originate primarily from the rapid variation of flow around the blade due to the vortex wake. Unlike fixed wing aircrafts, helicopter wake consists of helical vortex sheets trailed behind each blade and remains under the rotor disk which induces vertical downwash velocities at chordwise and spanwise stations of the blade. In this study, a mathematical model is developed for rotor blades to compute the harmonic loads induced velocity at rotor blades for two flight conditions-vertical takeoff and landing, and forward flight. This method is useful for the performance analysis of rotor blade and selection of airfoils for the blade. The sectional lift, drag, and pitching moment are computed at a radial blade station for both flight conditions. The numerical integration of Biot-Savart relation are done for all the trailing and shed vortices to calculate the downwash through the rotor disc. The airloads are calculated using the relation between harmonic and inflow coefficients. The lift at a particular radial station is computed considering trailing and shed vortices and summing over each blade. Lifting-surface and lifting-line theories are applied to near wake and far wake, respectively, to calculate the downwash and inflow through the rotor disc. The results for lift are compared to the experimental flight-test data.
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作用在直升机旋翼叶片上的谐波载荷分析
旋翼飞机在任何飞行条件下都会遭受过大的振动,使乘客感到不舒服,并导致结构疲劳失效。振动的主要来源是转子谐波载荷,谐波载荷主要来自旋涡尾迹引起的叶片周围流动的快速变化。与固定翼飞机不同,直升机尾流由每个叶片后面的螺旋涡片组成,并保持在旋翼盘下方,从而在叶片的弦向和展向位置产生垂直下洗速度。本文建立了桨叶谐波载荷诱导速度的数学模型,计算了垂直起降和前飞两种飞行状态下桨叶谐波载荷诱导速度。该方法对旋翼叶片的性能分析和叶片翼型的选择具有一定的指导意义。截面升力、阻力和俯仰力矩分别在径向叶片站计算两种飞行条件。对所有尾涡和尾涡进行毕奥-萨瓦特关系的数值积分,计算通过转子盘的下洗。采用谐波系数与入流系数之间的关系计算空载。在一个特定的径向站升力计算考虑尾涡和脱落涡和累加在每个叶片。采用升力面理论和升力线理论分别对近尾迹和远尾迹进行了下洗和通过转子盘的流入计算。将升力计算结果与实验飞行试验数据进行了比较。
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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