Research on the aerodynamic characteristics of electrically controlled rotor under Parallel Blade Vortex Interaction using Lattice Boltzmann Method

IF 5 1区 工程技术 Q1 ENGINEERING, AEROSPACE
Lingzhi Wang , Taoyong Su , Kewei Li , Bonan Zhao
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引用次数: 0

Abstract

An electrically controlled rotor (ECR), also known as a swashplateless rotor, employs a trailing edge flap (TEF) system for primary rotor control instead of a swashplate, demonstrating the significant potential in rotor vibration and noise reduction. To investigate the aerodynamic characteristics of the blade flap segment of the ECR under parallel blade vortex interaction, an aerodynamic analysis model based on the lattice Boltzmann method (LBM) is established using the D3Q27 lattice model. The model is validated against experimental data of both the airfoil with trailing edge flap and conventional airfoil under vortex interaction, showing that the LBM can effectively predict variations in aerodynamic loads under both conditions. Based on this model, the effects of different flap deflection angles and miss distances on the aerodynamic characteristics of the ECR under parallel BVI are analyzed. The results indicate that under strong vortex interaction, a region of flow separation forms due to the entrainment effect of the vortex and adverse pressure gradient. The small-scale vortex structure upstream of the flap can also be observed and is believed to contribute to the unsteady flow phenomena such as vortex structure splitting, development, and separation on the upper surface of the flap. The different flap deflection angles mainly affect the scale and type of vortex structures developed on the flap upper surface. As the miss distance increases, the interaction effect is significantly weakened compared to strong vortex interaction. However, as the vortex moves downstream along the airfoil lower surface, it entrains vorticity from the lower surface, ultimately forming a negative pressure region on the lower surface of the flap. The different flap deflection angles will influence the structural characteristics during the downstream motion of the vortex, which changes the size of the negative pressure region, causing differences in the magnitude of the variations in aerodynamic parameters.
利用格子波尔兹曼法研究平行叶片涡流相互作用下电控转子的气动特性
电控转子(ECR)又称无斜盘转子,它采用后缘襟翼(TEF)系统代替斜盘进行主转子控制,在减少转子振动和噪音方面具有巨大潜力。为了研究平行叶片涡流相互作用下 ECR 叶片襟翼部分的气动特性,使用 D3Q27 晶格模型建立了基于晶格玻尔兹曼法(LBM)的气动分析模型。该模型根据涡流相互作用下带后缘襟翼的机翼和传统机翼的实验数据进行了验证,结果表明 LBM 可以有效预测这两种条件下的气动载荷变化。基于该模型,分析了不同襟翼偏转角和失误距离对平行 BVI 条件下 ECR 气动特性的影响。结果表明,在强涡流相互作用下,由于涡流的夹带效应和不利的压力梯度,会形成一个气流分离区域。襟翼上游的小尺度涡旋结构也可以被观察到,并被认为是襟翼上表面涡旋结构分裂、发展和分离等非稳态流动现象的原因。不同的襟翼偏转角主要影响襟翼上表面形成的涡流结构的规模和类型。随着偏离距离的增加,与强涡流相互作用相比,相互作用效果明显减弱。然而,当涡流沿机翼下表面向下游移动时,会夹带下表面的涡流,最终在襟翼下表面形成负压区。不同的襟翼偏转角度会影响涡流顺流运动时的结构特性,从而改变负压区的大小,造成气动参数变化幅度的差异。
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来源期刊
Aerospace Science and Technology
Aerospace Science and Technology 工程技术-工程:宇航
CiteScore
10.30
自引率
28.60%
发文量
654
审稿时长
54 days
期刊介绍: Aerospace Science and Technology publishes articles of outstanding scientific quality. Each article is reviewed by two referees. The journal welcomes papers from a wide range of countries. This journal publishes original papers, review articles and short communications related to all fields of aerospace research, fundamental and applied, potential applications of which are clearly related to: • The design and the manufacture of aircraft, helicopters, missiles, launchers and satellites • The control of their environment • The study of various systems they are involved in, as supports or as targets. Authors are invited to submit papers on new advances in the following topics to aerospace applications: • Fluid dynamics • Energetics and propulsion • Materials and structures • Flight mechanics • Navigation, guidance and control • Acoustics • Optics • Electromagnetism and radar • Signal and image processing • Information processing • Data fusion • Decision aid • Human behaviour • Robotics and intelligent systems • Complex system engineering. Etc.
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