面向可行的小型转子和叶片段流动模拟

IF 0.7 Q4 MECHANICS
J. Svorcan, Aleksandar Kovačević, Dragoljub Tanović, M. Hasan
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引用次数: 0

摘要

本文的重点是充分模拟多旋翼飞机小型螺旋桨周围复杂流场的可能性。这种无人驾驶飞行器(uav)因其各种应用(监视,通信,交付等)而稳步普及,对可行(即可用,满意,实用)计算工具的需求也在激增。从工程的角度来看,在合理的时间内获得足够准确的流场变量预测是很重要的,这样设计过程才能快速有效,特别是随后的结构和飞行力学分析。这就是为什么或多或少的标准流体流动模型,例如由有限体积法(FVM)求解的reynolds -average Navier-Stokes (RANS)方程,不断被采用和验证的原因。另一方面,必须特别注意发生在翼型叶片段周围的各种流动特性,因为这些流动的特点是弦线(长度尺度)小,速度低,因此雷诺数(Re)低,并且具有明显的粘性效应。所研究的低re流包括过渡区和湍流区、层流分离泡(LSBs)、流动分离以及旋转尾迹,这需要一些特定的流动建模方法(先进的湍流模型、精细的时空尺度等)。本文给出并解释了在不同湍流模型下进行的计算(围绕静止叶片段和旋转转子)。提供、比较和讨论了各种定性和定量结果。介绍了各种计算方法的主要可能性和障碍。在可能的情况下,数值结果与实验数据进行验证。两组结果之间的对应关系可以被认为是令人满意的(推力系数的相对差异为15%,而扭矩系数的相对差异甚至更低)。可以得出结论,湍流建模(和/或解析)的选择极大地影响了最终输出,即使在设计操作条件下(在中等攻角下,层流,附流占主导地位)。独特的流动现象仍然存在,为了充分模拟,需要采用综合的建模方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Towards viable flow simulations of small-scale rotors and blade segments
The paper focuses on the possibilities of adequately simulating complex flow fields that appear around small-scale propellers of multicopter aircraft. Such unmanned air vehicles (UAVs) are steadily gaining popularity for their diverse applications (surveillance, communication, deliveries, etc.) and the need for a viable (i.e. usable, satisfactory, practical) computational tool is also surging. From an engineering standpoint, it is important to obtain sufficiently accurate predictions of flow field variables in a reasonable amount of time so that the design process can be fast and efficient, in particular the subsequent structural and flight mechanics analyses. That is why more or less standard fluid flow models, e.g. Reynolds-averaged Navier-Stokes (RANS) equations solved by the finite volume method (FVM), are constantly being employed and validated. On the other hand, special attention must be given to various flow peculiarities occurring around the blade segments shaped like airfoils since these flows are characterized by small chords (length-scales), low speeds and, therefore, low Reynolds numbers (Re) and pronounced viscous effects. The investigated low-Re flows include both transitional and turbulent zones, laminar separation bubbles (LSBs), flow separation, as well as rotating wakes, which require somewhat specific approaches to flow modeling (advanced turbulence models, fine spatial and temporal scales, etc). Here, the conducted computations (around stationary blade segments as well as rotating rotors), closed by different turbulence models, are presented and explained. Various qualitative and quantitative results are provided, compared and discussed. The main possibilities and obstacles of each computational approach are mentioned. Where possible, numerical results are validated against experimental data. The correspondence between the two sets of results can be considered satisfactory (relative differences for the thrust coefficient amount to 15%, while they are even lower for the torque coefficient). It can be concluded that the choice of turbulence modeling (and/or resolving) greatly affects the final output, even in design operating conditions (at medium angles-of-attack where laminar, attached flow dominates). Distinctive flow phenomena still exist, and in order to be adequately simulated, a comprehensive modeling approach should be adopted.
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来源期刊
CiteScore
0.90
自引率
0.00%
发文量
4
审稿时长
32 weeks
期刊介绍: Theoretical and Applied Mechanics (TAM) invites submission of original scholarly work in all fields of theoretical and applied mechanics. TAM features selected high quality research articles that represent the broad spectrum of interest in mechanics.
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