摘要
为预测粗糙壁面诱导的流动转捩,对Langtry提出的γ-Reθ转捩模型增加粗糙壁面的比耗散率和涡黏性的边界条件,并对模型中的经验关联函数——转捩动量厚度雷诺数进行修正,引入等效沙粒表面粗糙度作为变量,使模型具有一定的预测粗糙壁面诱导的流动转捩的能力.对粗糙平板自然转捩算例和变压力梯度平板绕流算例进行数值模拟,计算结果与风洞实验数据符合的较好.主要结论如下:表面粗糙度一般会增加边界层内的传热系数和阻力系数,同时使层流到湍流的转捩位置提前;自然转捩的转捩位置受表面粗糙度影响较大,与光滑壁面相比,平板算例中0.15mm的表面粗糙度使转捩位置提前40%;分离诱导转捩的转捩位置受表面粗糙度影响较弱,随着表面粗糙度逐渐增加,转捩位置和分离泡位置略有后移,且分离泡强度逐渐减弱,分离泡之后的阻力系数增加.
For the purpose of simulating roughness induced transition, the boundary conditions of turbulent dissipation rate and eddy viscosity for rough surface were added to Langtry's γ-Reo transition model; furthermore, equivalent sand surface roughness height was introduced to rewrite the correlation equations of the transition momentum thickness Reynolds number, making it appropriate for roughness-induced transition. Numerical simulation was made by referring to the wind tunnel data of several rough flat plate experiments and variable-pressure-gradient plate experiment, in which the results were satisfactory. Main conclusions are made as follows: surface roughness will enhance the heat transfer, increase the skin friction coefficient and shift the transition position upstream in general compared with smooth cases; effects for natural transition is significant, as surface roughness of 0. 15 mm could shift the transition position upstream about 40%; while affect for separating induced transition is weaker; with the increase of surface roughness, transition position and separating bubble position are shifted backwards a little, the strength of separating bubble becomes weaker while the friction coefficient increases.
出处
《航空动力学报》
EI
CAS
CSCD
北大核心
2016年第9期2251-2257,共7页
Journal of Aerospace Power
关键词
转捩
表面粗糙度
边界层
转捩模型
间歇因子
transition
surface roughness
boundary layertransition model
intermittency factor
