微型凸起流动控制用于翼型的减阻特性研究

微型凸起作为减小阻力的一种有效措施已经备受关注.开展了等熵压缩"弱激波"干扰鼓包用于RAE2822超临界翼型的减阻作用机制研究以及NACA0012对称翼型表面脊状结构减阻特性的数值模拟研究.结果表明:通过鼓包参数最优匹配,可达到弱化激波、减小波阻、提高升阻比、延缓抖振边界等目的;同时,通过对比不同脊状结构、不同网格密度对计算结果的影响,总结了多个速度下脊状表面的减阻规律.所得结论为进一步开展微型凸起类流动控制用于机翼的减阻特性研究奠定了坚实基础.     

后掠翼三维鼓包串激波控制参数的影响

针对跨声速后掠翼,三维鼓包串作为一种有效的减阻方式具有结构简单、高效及鲁棒性好等优点.利用全局优化算法探索了鼓包设计参数空间的整体特性,并对鼓包长度、三维鼓包展向设计参数对鼓包减阻效果的影响进行了研究,发现鼓包顶点位置和高度对阻力系数最敏感,三维鼓包的展向设计参数则对阻力系数不敏感,而鼓包长度和鼓包相对展长越长越有利于减阻.在此基础上开展了小后掠角自然层流机翼加3种不同类型鼓包串的优化研究,通过优化结果发现,增加优化后的三维鼓包串,可将小后掠角自然层流机翼阻力发散马赫数向后推移,并且鼓包平均长度和控制区越大,效果越好.三维鼓包串具有良好的局部控制特性,可用于局部较强激波的抑制.三维鼓包串对常规后掠翼波阻具有良好的控制效果,同时能够抑制激波诱导的机翼后缘气流分离.      

低雷诺数下吹吸气射流对NACA0012翼型气动性能的影响

基于Favre过滤的大涡模拟方法,对雷诺数Re=10^4,迎角α=6°下的NACA0012翼型上表面吹吸气射流进行了数值模拟,从翼型周围流场流线图、速度场云图、上下表面压力系数曲线以及上表面边界层位移厚度等多角度地分析了射流位置以及速度变化对翼型气动性能的影响。结果表明:射流位置对翼型气动性能影响较大,且吸气射流要明显优于吹气射流。对于吸气射流,前缘吸气要明显优于中后缘吸气,可有效增升减阻,并减小翼型尾部流动分离,抑制翼型气动参数扰动,其最佳吸气位置随着速度的增大逐渐向下游移动;而吹气射流对翼型气动系数的作用效果较差,但中后缘的吹气射流可减小飞行过程中的气动扰动量,且吹气越大,效果越明显。     

HLFC后掠翼优化设计的若干问题

使用扩展自由变形参数化方法,基于径向基函数的动网格技术和改进的混合粒子群算法,考虑吸气的e^N转捩预测方法和雷诺平均Navier-Stokes求解器,搭建了针对混合层流流动控制（HLFC）后掠翼的优化设计平台,对HLFC后掠翼的气动外形设计、雷诺数影响、吸气分布设计等多个问题进行了研究,对比分析了在这些因素影响下HLFC后掠翼的阻力系数和层流区长度的差别,进而探索了相应的设计准则。研究表明,对于层流区较长和阻力系数较小的HLFC后掠翼来说,它们上表面的压力分布具有共同的特征：头部峰值较低,之后有一个小的逆压,接下来是一段较长的均匀稳定的顺压,这段顺压最后终结于一道激波。应用HLFC技术后,通过实现大面积的层流区,机翼的摩擦阻力和压差阻力均可显著地降低,降低的幅度远大于不考虑层流控制的设计结果。同时,HLFC机翼的设计应综合考虑摩擦阻力、压差阻力、激波强度和配平阻力（低头力矩）,层流区最长不一定意味着阻力最小。一般来说,雷诺数越高,越难维持层流,但应用混合层流控制技术后,即使在难以实现自然层流的高雷诺数下,HLFC机翼依然有较长的层流区。通过对吸气分布的设计进行研究,说明了非均匀吸气比均匀吸气要更有效率一些,能够节省吸气量。     

NPU翼型的气动力分析和改进设计

 在飞行器设计中用计算方法设计超临面翼型已完全取代了选用现成翼型的设计方法。为考察已设计出的NPU翼型是否满足飞行器设计要求我们对其进行了全面气动分析,发现这些翼型尚有不足之处,有必要进行改进设计。     

Laminar flow control research at TsAGI: Past and present

This paper presents a brief review of activities in laminar flow control being performed at the Central Aerohydrodynamic Institute named after Prof. N.E. Zhukovsky (TsAGI). These efforts are focused on the improvement of the existing laminar flow control methods and on the development of new ones. The investigations have demonstrated the effectiveness of aircraft surface laminarization applications with the aim of friction drag reduction. The opportunity of considerable delaying of laminar-turbulent transition due to special wing profile geometry and using boundary layer suction and surface cooling has been verified at sub- and supersonic speeds through various wind tunnel testing at TsAGI and during flying laboratory experiments at the Flight Research Institute (LII). The investigations on using hybrid laminar flow control systems for friction drag reduction were also carried out. New techniques of laminar flow control were proposed, in particular, the method of local heating of the wing leading edge, boundary layer laminarization by means of receptivity control, and electrohydrodynamic methods of boundary layer stability control.     

超声速压气机叶栅前缘通道激波损失的鼓包控制研究

为了有效减小超声速压气机叶栅变进气马赫数条件下的前缘通道激波损失及由激波诱导的边界层分离,提出了一种带有平直过渡区的新型鼓包结构,并采用数值方法详细分析了新型鼓包结构对激波与激波/边界层相互作用机理以及鼓包几何尺寸与位置对控制效果的影响机制。研究结果表明:新型鼓包在迎风侧凹面产生的压缩波系有效削弱了前缘通道激波的强度,鼓包过渡区产生的膨胀波系使边界层流体加速,明显抑制了局部流动分离,并使分离提前再附。当某一超声速压气机叶栅的前缘通道激波入射在鼓包的过渡区范围内,鼓包高度为0.35倍的边界层厚度且鼓包迎风侧与背风侧长度分别为过渡区长度4倍与5倍时,可以实现较好的控制效果。此外,与无鼓包方案相比,新型鼓包结构可使超声压气机叶栅在设计工况下的总压损失减少4.6%,同时超声速压气机叶栅进气马赫数在1.65~1.8范围内仍能取得较好的气动减损效果。      

减小翼型激波阻力的鼓包流动控制技术

针对2020年使用的N+2代民用飞机的翼身融合(BWB)布局发展需要,以减小激波阻力为目标,采用计算流体力学(CFD)方法,开展弱化激波、减小激波阻力的鼓包流动控制技术研究.提出了λ形激波结构“强干扰”和等熵压缩“弱干扰”两种鼓包激波减阻流动控制原理,给出了两种鼓包基本形状设计方法和工程应用的可行性分析,指出λ形激波结...     

Instability analysis and drag coefficient prediction on a swept RAE2822 wing with constant lift coefficient

Swept wing is widely used in civil aircraft,whose airfoil is chosen,designed and optimized to increase the cruise speed and decrease the drag coefficient.The parameters of swept wing,such as sweep angle and angle of attack,are determined according to the cruise lift coefficient requirement,and the drag coefficient is expected to be predicted accurately,which involves the instability characteristics and transition position of the flow.The pressure coefficient of the RAE2822 wing with given constant lift coefficient is obtained by solving the three-dimensional Navier-Stokes equation numerically,and then the mean flow is calculated by solving the boundary layer(BL) equation with spectral method.The cross-flow instability characteristic of boundary layer of swept wing in the windward and leeward is analyzed by linear stability theory(LST),and the transition position is predicted by eNmethod.The drag coefficient is numerically predicted by introducing a laminar/turbulent indicator.A simple approach to calculate the lift coefficient of swept wing is proposed.It is found that there is a quantitative relationship between the angle of attack and sweep angle when the lift coefficient keeps constant;when the angle of attack is small,the flow on the leeward of the wing is stable.when the angle of attack is larger than 3°,the flow becomes unstable quickly;with the increase of sweep angle or angle of attack the disturbance on the windward becomes more unstable,leading to the moving forward of the transition position to the leading edge of the wing;the drag coefficient has two significant jumping growth due to the successive occurrence of transition in the windward and the leeward;the optimal range of sweep angle for civil aircraft is suggested.     

跨音速机翼采用鼓包主动减阻技术研究

对二维、三维鼓包进行激波控制减阻,并在大型客机的机翼上进行了对比研究。在研究鼓包减阻的机理时,采用了超临界翼型,鼓包的几何形状及鼓包位置的优化也进行了研究。研究结果表明,鼓包位置、形状及串列式分布对机翼的减阻影响较大。最后把得到的研究结果应用到大型飞机的激波减阻上,结果表明,该方法能较大程度地减小激波阻力,进而提高飞机的升阻比,提高飞机的气动效率。     

基于升华法的后掠翼混合层流控制研究

在低湍流度风洞中针对45°后掠角NACA64A-204翼型模型,采用升华流动显示技术研究不同吸气量和不同迎角状态下混合层流控制（HLFC）对转捩位置的影响。结合热线方法测量流向速度研究扰动增长的机制。实验结果表明：萘升华流动显示技术适合用来研究HLFC方法对后掠翼转捩的影响,可以直观和准确地表示后掠翼上的转捩位置;在无吸气的情况下,随着迎角从-6°到2°增大,层流区长度先增大后减小;HLFC方法可以显著推迟由横流不稳定触发的转捩;在同一迎角下增加吸气量,可以更有效地减小主要扰动波的能量。     

剪切翼梢增升减阻机理

在计算与风洞实验的基础上 ,提出了机翼剪切翼梢气动布局 ,对平面形状与翼型进行了优化设计 ,达到了巡航状态与爬升阶段较高的增升减阻要求。计算采用涡格面元法与涡升力展向分布吸力比拟法相结合的方法 ,既能考虑气动力的非线性因素 ,又有较高的计算精度与速度。计算结果与实验数据十分吻合。通过分析得到 ,在矩形翼翼梢处增加具有较大前缘后掠角的梯形剪切翼梢有不仅增加机翼展弦比 ,且可改变展向环量分布 ,使其接近椭圆分布 ;剪切翼梢上的前缘涡可抑制翼端涡的作用 (使翼端涡强度变弱 ) ,并在剪切翼梢上产生附加升力     

激波控制鼓包提高翼型跨声速抖振边界

翼型抖振边界是仅次于升阻比的一项重要气动指标.采用定常雷诺平均Navier-Stokes方程,以升力线斜率平缓及激波位置振荡作为基本判据确定了RAE2822翼型在指定跨声速来流条件下的抖振边界.通过大量计算流体力学(CFD)验证,针对RAE2822翼型设计了一种特定外形的激波控制鼓包并确定了其具体安装位置.该激波控制鼓...     

Supersonic biplane—A review

One of the fundamental problems preventing commercial transport aircraft from supersonic flight is the generation of strong sonic booms. Sonic booms are the ground-level manifestation of shock waves created by airplanes flying at supersonic speeds. The strength of the shock waves generated by an aircraft flying at supersonic speed is a direct function of both the aircraft’s weight and its occupying volume; it has been very difficult to sufficiently reduce the shock waves generated by the heavier and larger conventional supersonic transport (SST) configuration to meet acceptable at-ground sonic-boom levels. It is our dream to develop a quiet SST aircraft that can carry more than 100 passengers while meeting acceptable at-ground sonic-boom levels. We have started a supersonic-biplane project at Tohoku University since 2004. We meet the challenge of quiet SST flight by extending the classic two-dimensional (2-D) Busemann biplane concept to a 3-D supersonic-biplane wing that effectively reduces the shock waves generated by the aircraft. A lifted airfoil at supersonic speeds, in general, generates shock waves (therefore, wave drag) through two fundamentally different mechanisms. One is due to the airfoil’s lift, and the other is due to its thickness. Multi-airfoil configurations can reduce wave drag by redistributing the system’s total lift among the individual airfoil elements, knowing that wave drag of an airfoil element is proportional to the square of its lift. Likewise, the wave drag due to airfoil thickness can also be nearly eliminated using the Busemann biplane concept, which promotes favorable wave interactions between two neighboring airfoil elements. One of the main objectives of our supersonic-biplane study is, with the help of modern computational fluid dynamics (CFD) tools, to find biplane configurations that simultaneously exhibit both traits. We first re-analyzed using CFD tools, the classic Busemann biplane configurations to understand its basic wave-cancellation concept. We then designed a 2-D supersonic biplane that exhibits both wave-reduction and cancellation effects simultaneously, utilizing an inverse-design method. The designed supersonic biplane not only showed the desired aerodynamic characteristics at its design condition but also outperformed a zero-thickness flat-plate airfoil. (Zero-thickness flat-plate airfoils are known as the most efficient monoplane airfoil at supersonic speeds.) Also discussed in this paper is how to design 2-D biplanes, not only at their design Mach numbers but also at off-design conditions. Supersonic biplanes have unacceptable characteristics at their off-design conditions such as flow choking and its related hysteresis problems. Flow choking causes rapid increase of wave drag and it continues to be kept up to the Mach numbers greater the cruise (design) Mach numbers due to its hysteresis. Some wing devices such as slats and flaps, which could be used at take-off and landing conditions as high-lift devices, were utilized to overcome these off-design problems. Then supersonic-biplane airfoils were extended to 3-D wings. Because that rectangular-shaped 3-D biplane wings showed undesirable aerodynamic characteristics at their wingtips, a tapered-wing planform was chosen for the study. A 3-D biplane wing having a taper ratio and aspect ratio of 0.25 and 5.12, respectively, was designed utilizing the inverse-design method. Aerodynamic characteristics of the designed biplane wing were further improved by using winglets at its wingtips. Flow choking and its hysteresis problems, however, occurred at their off-design conditions. It was shown that these off-design problems could also be resolved by utilizing slats and flaps. Finally, a study on the aerodynamic characteristics of wing-body configurations was conducted using the tapered biplane wing. In this study a body was chosen in order to generate strong shock waves at its nose region. Preliminary parametric studies on the interference effects between the body and the tapered biplane wing were performed by choosing several different wing locations on the body. From this study, it can be concluded that the aerodynamic characteristics of the tapered biplane wing are minimally affected by the disturbances generated from the body, and that the biplane wing shows promise for quiet commercial supersonic transport.     

压气机叶栅中的激波附面层相互作用

压气机叶栅中激波附面层相互作用是十分复杂的问题,由于相互作用引起分离是决定跨音速压气机性能的重要因素之一。然而迄今为止,尚未深入进行过压气机叶栅激波附面层相互作用的研究,发表的文献极少。作者经过计算和分析,说明压气机叶栅流中主要的相互作用形式是叶栅槽道中激波和湍流附面层的相互作用。作者通过分析指出,研究压气机叶栅激波附面层相互作用,不能直接应用Pearcey分离准则。作者并提出了适用于压气机叶栅的分离准则的函数关系为f(M_1,p_1/p_(L.E.),P_(r.E.)/p_2,Re_0)=O。     

跨声速翼型激波／边界层干扰被动控制的数值模拟计算

本文应用数值计算的方法着重研究了跨声速翼型开孔壁的减阻效果。计算采用了边界层与位流相互作用的模型,藉以了解开孔壁对激波强度及结构的影响和对边界层控制的效果。通过对NACA0012翼型的计算表明,本文采用的自然吹吸的开孔模型能够显著地削弱激波的强度,改善激波的结构,但会使粘性损失增加。在马赫数较小时,翼型开孔后总阻力会增加,而在大马赫数时,开孔翼型的减阻效果才表现出来。这种趋势是与实验结果相吻合的。     

C型机翼局部优化设计研究

以DLR-F4模型为基本外形,利用涡格法以诱导阻力最小为原则,优选出了C型翼翼梢几何参数.采用N-S方程数值求解方法,研究了C型翼布局各部件之间的流动干扰机理.针对机翼与翼梢之间的流动干扰产生局部激波和翼梢水平段产生负升力问题,采用C型翼梢翼型优化配置的方法.仿真结果表明,这一方法较好地克服了上述不利干扰,进一步提高了C型翼的升阻性能.     

基于0.6 m量级三声速风洞的压敏漆试验技术

基于0.6 m暂冲式三声速风洞,建立了压敏漆测压系统,解决了各分系统的同步控制问题。研究了涂料喷涂影响、图像滤波和系统测量稳定性及精准度等技术细节,并将该系统首次应用于未来大型客机减阻与激波控制的机翼表面压力测量中,获得了基本外形和鼓包外形机翼表面的压力分布、激波位置及形态。检验了设计鼓包在设计状态和稍偏离设计状态下的激波控制效果及其对上翼面压力分布和升力特性的影响。研究结果表明：涂料喷涂质量不佳造成的表面粗糙度和厚度变化会显著影响压力分布,喷涂质量需严格控制。窗口直径8像素迭代3次的高斯滤波对压力波动的平滑效果较好且不会失真。建立的压敏漆系统与压力传感器的压力系数测量均方根偏差在0.022以内,压力均方根偏差小于620 Pa,测量精准度较高。设计鼓包在设计状态及稍偏离设计状态下,均能够有效减弱激波强度,保证机翼升力变化很小,从而提高机翼的升阻比。     

Bump进气道中鼓包诱导的激波/边界层干扰特性

为了探索Bump进气道中鼓包诱导的锥形激波和机身发展而来的湍流边界层干扰问题,分析其气动优势,首先选取了半锥和半棱锥这两种与鼓包的流场结构具有一定相似性的构型作为参照,采用数值仿真方法,分别对这三类典型的三维激波/湍流边界层干扰问题进行了流场分析。在此基础之上,设计了三个不同马赫数的鼓包,并研究了设计马赫数对鼓包流场特性的影响。结果表明:当三类构型的无黏激波强度相等时,半锥诱导产生的旋涡强度最强,鼓包次之,半棱锥最弱。尽管鼓包诱导的流场非常复杂,其干扰流场却呈现出准锥形相似的特性。虽然半锥对边界层的排移能力最强,但是综合考虑边界层排移能力及进气道出口流场畸变下,鼓包最具优势,这也是其被选为超声速进气道前缘压缩面的重要原因之一。此外,在设计状态下,适当增加设计马赫数能改善鼓包排移边界层的能力,但设计马赫数太高,边界层排移能力基本不变,反而使得进气道总压损失急剧增加。      

Control of a decelerating boundary layer. Part 1: Optimization of passive vortex generators

The control of boundary layer separation on the suction side of an airfoil at high angle of attack has been renewed by the possibilities of active control. Nevertheless, such an active control needs a deep understanding of the flow to manipulate and of the actuating flow, both being 3D and unsteady. For that purpose, a model experiment has been designed in the frame of a coordinated European project called AEROMEMS, with a simpler (2D) geometry and with a dilatation of the scales in order to be able to characterize the actuation flow. This model is a bump in a boundary layer wind tunnel, which mimics the adverse pressure gradient on the suction side of an airfoil at the verge of separation. The present contribution describes preliminary tests done to optimize standard passive devices before testing active systems. The optimization was done with hot film shear stress probes, the characterization with hot wire anemometry and PIV. The results show quantitatively the improvement brought by the passive devices in terms of skin friction. They also show the mechanism which is at the origin of this improvement. The next step of the project is to replace passive devices by synthetic jets.