基于NPLS技术的可压缩湍流机理实验研究新进展

可压缩湍流机理的实验研究是一件难度很大的工作, 其主要的难度在于高时空分辨率的可压缩湍流结构非接触精细测试技术和低噪声的高速风洞设备技术. 近几年来, 由于在低噪声的超声速、高超声速风洞研究和可压缩流动精细结构测量技术研究方面取得的重要进展及其在可压缩湍流机理研究方面的应用, 超声速流动转捩与湍流的机理研究取得了较大的进展. 本文介绍了最近几年高速流动非接触精细测试技术, 尤其是基于纳米粒子的平面激光散射技术(nano-tracer planar laser scattering, NPLS)、背景导向纹影技术(background oriented schlieren, BOS) 和超声速流场的粒子图像测速技术(particle image velocimetry, PIV)的研究进展和发展前景, 以及基于这些技术, 在可压缩湍流机理实验研究方面的进展和发展前景, 其中包括在超声速混合层转捩、超声速绕流与尾流结构、超声速边界层转捩、激波边界层干扰等典型流场的机理研究方面, 以及气动光学机理研究方面的研究进展. 最后, 展望了目前湍流机理实验研究对湍流工程模型研究的可能贡献.      

Simultaneous density and velocity measurements in a supersonic turbulent boundary layer

A novel technique for simultaneous measurements of instantaneous whole-field density and velocity fields of supersonic flows has been developed.The density measurement is performed based on the nano-tracer planar laser scattering(NPLS) technique,while the velocity measurement is carried out using particle image velocimetry(PIV).The present experimental technique has been applied to a flat-plate turbulent boundary layer at Mach 3,and the measurement accuracy of the density and velocity are discussed.Based on this new technique,the Reynolds stress distributions were also obtained,demonstrating that this is an effective means for measuring Reynolds stresses under compressible conditions.     

示波器在EMC仪器校准中的应用

介绍了在EMC的电快速脉冲群（EFT/B）、浪涌（Surge）和静电放电（ESD）发生器的测试中,使用示波器的相关设置和应用,并对3项测试中示波器设置的异同进行了辨析。     

基于NPLS的超声速后台阶流场精细结构及其非定常特性

在马赫数3.4的低噪声超声速风洞中,分别采用纹影技术及基于纳米示踪的平面激光散射技术(NPLS),对台阶高度为3 mm的层流后台阶绕流结构进行了流动显示实验,旨在研究后台阶流场再附区的平均流动规律及再附边界层的瞬态流场精细结构,并通过比较不同时刻的NPLS数据,发现后台阶再附边界层涡结构的非定常演化特性;并且与马赫数4.2条件下的纹影结果和前期研究成果进行了比较.结果表明,两种流动显示方法均可以捕捉激波膨胀波的位置,但NPLS技术在揭示流场某一截面内的瞬态精细结构方面更具优势,其时间分辨率可达6 ns,空间分辨率微米量级;该流场条件下的回流剪切层的倾角为-3.1?,再附边界层的平均增长斜率为0.07519;再附边界层中发卡涡脱落的特征时间尺度为大约10μs.相同膨胀比条件下,再附随着马赫数增大而推迟;膨胀比越大,再附越提前,并且流动折转角变大.     

纳米示踪平面激光散射技术在激波复杂流场测量中的应用

在激波以及激波边界层相互作用这类含激波的复杂流场中,流场结构具有明显的三维特征.研究这类流场,采用纹影、阴影和干涉等传统流动显示技术空间分辨率较低,难以分辨流场的三维特性.基于纳米示踪的平面激光散射技术(nano-tracer planar laser scattering,NPLS),是作者近年来开发的一种新的研究超声速流场的测试与显示技术,可对超声速复杂三维流场进行高时空分辨率流动显示与测量.NPLS技术的特点使其成为测量激波复杂流场的有力手段.近年来,作者以NPLS技术为主要手段,对航空航天领域典型的激波复杂流场进行了试验研究,包括超声速弹头绕流、超声速混合层、超声速边界层,以及激波边界层相互作用流场,显示出NPLS技术在激波复杂流场精细测试与流动显示中优势.本文简要介绍NPLS技术在激波复杂流场测量中应用的研究进展.      

Instantaneous and time-averaged flow structures around a blunt double-cone with or without supersonic film cooling visualized via nano-tracer planar laser scattering

In a Mach 3.8 wind tunnel, both instantaneous and time-averaged flow structures of different scales around a blunt double-cone with or without supersonic film cooling were visualized via nano-tracer planar laser scattering (NPLS), which has a high spatiotemporal resolution. Three experimental cases with different injection mass flux rates were carried out. Many typical flow structures were clearly shown, such as shock waves, expansion fans, shear layers, mixing layers, and turbulent boundary layers. The analysis of two NPLS images with an interval of 5 μs revealed the temporal evolution characteristics of flow structures. With matched pressures, the laminar length of the mixing layer was longer than that in the case with a larger mass flux rate, but the full covered region was shorter. Structures like K-H (Kelvin-Helmholtz) vortices were clearly seen in both flows. Without injection, the flow was similar to the supersonic flow over a backward-facing step, and the structures were relatively simpler, and there was a longer laminar region. Large scale structures such as hairpin vortices were visualized. In addition, the results were compared in part with the schlieren images captured by others under similar conditions.