基于光学相干测振系统的微悬臂梁缺陷检测

提出了基于光学相干测振（optical coherence vibrometer, OCV）系统的微悬臂梁缺陷检测方法。自搭建的OCV系统最大振动位移量程、最大振动频率分别为2.574 mm和138.5 kHz,应用该系统对含缺陷微悬臂梁-附加质量块耦合结构进行振动测量获得其固有频率,并利用附加质量块对固有频率的影响特性实现了对缺陷的定位。在对系统采集到的干涉光谱信号处理的过程中,采用FFT（fast Fourier transform, FFT）+ FT（Fourier transform, FT）细化频谱校正算法进行误差校正,精度可提高1 000倍以上,使系统实现纳米量级的位移测量。实验结果表明,该方法能够有效识别微悬臂梁的缺陷位置,为微小型结构的缺陷检测提供了一种新的方法,同时拓展了光学相干测振技术在工程结构无损检测的应用。     

连续振动悬臂梁的瞬时三维形貌测量

提出一种连续振动悬臂梁瞬时三维形貌的测量方法。利用影栅云纹法在连续振动悬臂梁表面产生包含有三维形貌信息的云纹,采用准直双光源提高亮度,通过高速摄相机获取随时间变化的一系列变形条纹,利用傅里叶变换方法对序列图像进行处理,采用补零延拓法对数据进行处理,以减小频谱泄漏所引起的相位计算误差。将相位解包裹方法用于动态过程瞬时三维相位场的相位展开中,重建了悬臂梁的瞬时三维形貌,再现了悬臂梁的连续振动过程。     

基于时域小波变换相位提取的三维形貌测量

提出基于时域小波变换的连续振动物体相位提取方法,恢复连续振动物体的瞬时三维形貌。将小波变换用于序列影栅云纹相位分析中,对连续振动物体的序列影栅图像进行处理,利用小波变换的多分辨力特点,对各点的灰度变化进行连续复小波变换,通过提取小波脊所对应的相位,得到各点相对于基准光栅的完整相位调制信息,从而获取运动物体的瞬时三维形貌。利用该方法对连续振动悬臂梁进行了分析,得到连续振动悬臂梁的瞬时速度及瞬时三维形貌,再现了悬臂梁的连续振动过程。为研究动态物体瞬时特性提供了一种新的方法。     

试样激励下轻敲模式原子力声显微镜的非线性动力学特性

利用Euler-Bernoulli梁理论和DMT针尖-样品作用力模型建立了试样激励下轻敲模式原子力声显微镜(AFAM)系统的动力学方程,并应用非线性动力学分析方法对AFAM微悬臂梁的振动特性进行研究。通过合理改变超声激励幅值、超声激励频率和针尖-样品初始间距等模型参数模拟得到微悬臂梁的超谐波、次谐波、准周期和混沌振动现象,采用时间序列、频谱、相空间、Poincare截面和Lyapunov指数等方法对不同非线性振动特性进行表征。通过分析不同模型参数条件下微悬臂梁针尖-样品作用力特性,探索了微悬臂梁不同非线性振动现象的产生机制。此外,研究了AFAM微悬臂梁运动的分岔特性,发现当超声激励幅值和针尖-样品初始间隙连续变化时,周期、准周期和混沌运动交替出现。研究结果对AFAM系统非线性动力学行为分析和混沌振动控制提供了理论参考。      

悬臂梁压电振子宽带低频振动能量俘获的随机共振机理研究

研究了利用系统非线性来提高悬臂梁压电振子宽带低频振动能量俘获效率的随机共振机理,通过增加一对矩形永磁铁对传统线性悬臂梁压电振子结构进行了改进,结果揭示:在外部非线性磁力作用以及合适的磁铁间距条件下,这种外加磁力悬臂梁压电振子会构成一个双稳系统,在外部宽带低频随机振动源激励下发生随机共振现象,且发生随机共振时的输出电压明显增大,从而可以扩展悬臂梁压电振子的共振频率范围、提高低频振动能量的转化输出. 关键词： 压电悬臂粱 振动能量俘获 宽带低频 随机共振     

基于涡激振动的压电能量收集特性数值研究

本文设计了一种基于涡激振动的流体动能收集装置。该器件主要包括钝体和PVDF(Polyvinylidene Fluoride)压电悬臂梁,涡街的交替脱落引起梁发生振动,通过压电效应将振动能量转为电能.基于流固耦合计算对该结构压电能量收集特性,以及压电悬臂梁的升阻力系数、振幅和频率等特性进行了数值分析,并着重研究圆柱型钝体与PVDF压电悬臂梁的位置对装置发电效率的影响。结果表明,圆柱与悬臂梁直接相连(即L=0.5D)会得到较高电压输出,在雷诺数Re=6000时,振幅峰值为A=0.97D,输出电压峰值达到0.923V。     

多空穴错位分布对石墨纳米带中热输运的影响

利用非平衡格林函数方法研究了石墨纳米带中三空穴错位分布对热输运性质的影响.研究结果发现:三空穴竖直并排结构对低频声子的散射较小,导致低温区域三空穴竖直并排时热导最大,而在高频区域,三空穴竖直并排结构对高频声子的散射较大,导致较高温度区域三空穴竖直并排时热导最小;三空穴的相对错位分布仅能较大幅度地调节面内声学模高频声子的透射概率,而三空穴的相对错位分布能较大幅度地调节垂直振动膜高频声子和低频声子的透射概率,导致三空穴的相对错位分布不仅能大幅调节面内声学模和垂直振动模的高温热导,也能大幅调节垂直振动模的低温热导.研究结果阐明了空穴位置不同的石墨纳米带的热导特性,为设计基于石墨纳米带的热输运量子器件提供了有效的理论依据.     

基于旋涡发生体的光纤Bragg光栅流量计的研究

结合光纤光栅传感检测技术与旋涡分离原理,研制了一种基于三角柱型旋涡发生体的光纤Bragg光栅流量计,在三角柱旋涡发生体中部设置导压腔,腔内设置粘贴Bragg光栅的等强度悬臂梁,流体经过发生体两侧时,交替分离旋涡,导压腔内部产生脉动流体,等强度悬臂梁产生振动且振动频率与旋涡分离频率成正比,通过检测悬臂梁振动频率测量流体流量。实验表明,该流量计的线性度为4.38%FS,仪表系数为K=3.659,光纤光栅波长移位频率对流量的响应度为1.182Hz/(m3/h)。     

基于旋涡发生体的光纤Bragg光栅流量计的研究

结合光纤光栅传感检测技术与旋涡分离原理,研制了一种基于三角柱型旋涡发生体的光纤Bragg光栅流量计,在三角柱旋涡发生体中部设置导压腔,腔内设置粘贴Bragg光栅的等强度悬臂梁,流体经过发生体两侧时,交替分离旋涡,导压腔内部产生脉动流体,等强度悬臂梁产生振动且振动频率与旋涡分离频率成正比,通过检测悬臂梁振动频率测量流体流量。实验表明,该流量计的线性度为4.38%FS,仪表系数为K=3.659,光纤光栅波长移位频率对流量的响应度为1.182Hz/(m3/h)。     

基于悬臂梁调谐技术的光纤光栅无源振动监测

采用匹配光纤光栅设计了一种结构简单的振动信号无源监测装置.该装置利用悬臂梁调谐技术能够将微小振动信号转化为光电探测器可探测的光强信号,利用示波器实现实时监测.实验中对振幅为3mm的简谐振动信号进行了监测,测量结果与振动频率一致,可测量7～20Hz的振动,信噪比不低于14.9dB.监测频率受限是因为悬臂梁的性质,如采用金属材料或者采用齿轮组对转子进行减速,该装置可探测更高的频率.     

非简谐振动对SiC的热膨胀系数数和介电性能的影响

利用抛物型电子能谱模型,考虑到原子的非简谐振动,求出了SiC中原子振动的简谐系数与非简谐系数,用固体物理理论和方法,得到了SiC的热膨胀系数和格林乃森参量以及介电常数随温度变化的解析式,探讨了原子非简谐振动对的影响。结果表明：的格林乃森参量和热膨胀系数均随温度升高而非线性增大,而介电常数随温度升高而非线性减小;原子振动的非简谐项（特别是第二非简谐项）对的热膨胀等热学性质和介电性能有重要影响,温度愈高,非简谐振动项的影响愈大。     

光频支格波对晶格热容的贡献

讨论晶格的光频支格波对晶格热容的贡献，得到了这部分的热容的表达式。在低温极限情况下,光频支格波对晶格热容的贡献很小，可以忽略，只有频率较低的声频支格波对晶格热容有重要贡献；在高温情况下，复式 和中光频支格波对晶格热容有重要贡献，高温情况下的结果与杜隆－珀蒂定律给出的经典数值一致，该定律在高温时与实际实验符合得很好。     

双相滞热传导的振动现象

本文用解析的方法研究了双相滞热传导的振动现象,给出了热传导振动发生的条件.发现传热介质的尺寸越小,热扩散系数越大,易引发温度场的振动现象.     

传感器电解质材料热膨胀性能和热稳定性变化规律研究

以ZrO2固体电解质材料为例,研究氧传感器电解质材料原子振动特点和热膨胀系数及其热稳定性随温度和时间的变化规律,探讨原子非简谐振动的影响。结果表明：原子振动的频率、阻尼系数,在简谐近似下为常数,在考虑到非简谐效应后随温度升高而增大;原子平均位移和热膨胀系数在简谐近似下为零,在考虑到非简谐效应后随温度升高而增大,随的时间的增长而减小;热膨胀性能稳定性温度系数随温度的升高而减小,随时间的增长而增大,即使用时间越长,材料的热膨胀性能稳定性越低;温度越高,热膨胀性能越稳定;非简谐情况下的原子振动的频率、阻尼系数和热膨胀系数与简谐近似下的差值随温度的升高而增大,即温度越高,非简谐效应越显著。     

Vibration analysis of scanning thermal microscope probe nanomachining using Timoshenko beam theory

In this paper, the effect of thermal vibration on the resonant frequency of transverse vibration of scanning thermal microscope (SThM) cantilever probe is analyzed using the Timoshenko beam theory, including the effects of rotary inertia and shear deformation. The thermal vibration effect can be considered as an axial force and is dependent of temperature distribution of the probe. In this analysis, the temperature is assumed to be distributed in accordance with the constant, linear, and quadratic models along the probe length. The Rayleigh–Ritz method is used to solve the vibration problem of the probe. The numerical results show that the frequency obtained with the constant model is the highest, while it is the lowest for the quadratic model. The frequency of vibration modes of the probe increases with increasing the temperature of the probe. As the ratio of probe length to its thickness increases, the frequency of vibration modes decreases. In addition, the effects of rotary inertia and shear deformation on the frequency are significant, especially in higher order modes and smaller values of the ratio of the probe length to its thickness.     

Influence of Anharmonic Vibration on the Solubility Curve of the Binary Alloy

Taking TiCu alloy as an example, based on the measurement of thermal expansion coefficient, the harmonic vibration cpefficient and anharmonic vibration coefficient of atoms were calculated. With the help of Collins model, the author worked out the thermodynamic function and the solubility curve under the atomic anharmonic vibration. And, the influence of the anharmonic vibration was also discussed.     

Temperature-Dependent Debye Temperature and Specific Capacity of Graphene

The shot-range interaction and the atomic anharmonic vibration are both considered,and then the analytic functions of the Debye temperature,the specific capacity and the thermal conductivity of graphene with the temperature are obtained.The influence of anharmonic vibration on these thermal physical properties is also investigated.Some theoretical results are given.If only the harmonic approximation is considered,the Debye temperature of the graphene is unrelated to the temperature.If the anharmonic terms are considered,it increases slowly with the increasing temperature.The molar heat capacity of the graphene increases nonlinearly with the increasing temperature.The mean free path of phonons and the thermal conductivity of the graphene decrease nonlinearly with the increasing temperature.The relative changes of the Debye temperature,the specific heat capacity and the thermal conductivity caused by the anharmonic terms increase with the increasing temperature.The anharmonic effect of atomic vibration becomes more significant under higher temperature.     

Effect of driving frequency on non-linear coupling between ultrasound transducer and target under inspection in Sonic Infrared Imaging

Sonic Infrared (IR) Imaging, also referred as vibrothermography, is a novel Nondestructive Evaluation (NDE) technology to find cracks through infrared imaging of vibration-induced crack heating. The vibration source plays an important role in the detection of cracks. In this paper, the effect of driving frequency on the ultrasound vibration to the thermal imaging is presented. The research is organized by using different frequency system and coupling materials on the same aluminum bar sample. The analysis is conducted by combination of the vibration waveforms with the IR images and signals. Correlation analysis between the acoustic energy and the thermal energy in the crack is discussed as well.     

An analytical study of rotor dynamics coupled with thermal effect for a continuous rotor shaft

This paper presents an analytical analysis of a continuous rotor shaft subjected to universal temperature gradients. To this end, an analytical model is derived to investigate the generic thermal vibrations of rotor structures. The analytical solutions are obtained in a rotating frame and include parameters related with both the thermal environment and the rotor dynamic structures. This provides an insight into the mechanisms for the rotor thermal vibration. Furthermore, numerical results based on the analytical solutions are given. An index denoting the temperature gradients is proposed for the occasions with nonlinear cross-sectional temperature distributions. Finally, the factors influencing the thermal vibrations are analyzed. The results show that the thermal vibration is affected by many factors including the shaft size, rotational speeds, heating locations, critical speed, etc. Moreover, it is investigated how the convection coefficient and the heat conductivity influence the thermal vibrations in order to provide an insight into the management of thermal vibrations from the perspective of thermal aspects.     

Transverse Vibration and Stability Analysis of Circular Plate Subjected to Follower Force and Thermal Load

Transverse vibration and stability analysis of circular plate subjected to follower force and thermal load are analyzed . B ased on the thin plate theory in involving the variable temperature, the differential equation of transverse vibration for the axisymmetric circular plate subjected to follower force and thermal load is established. Then, the differential equation of vibration and corresponding boundary conditions are discretized by the differential quadrature method. Meanwhile, the generalized eigenvalue under three different boundary conditions are calculated. In this case, the change curve of the first order dimensionless complex frequency of the circular plate subjected to the follower force in the different conditions with the variable temperature coefficient and temperature load is analyzed. The stability and corresponding critical loads of the circular plate subjected to follower force and thermal load with simply supported edge, clamped edge and free edge are discussed. The results provide theoretical basis for improving the dynamic stability of the circular plate.