航空钛合金板胶接表面粗糙度的超声测量

采用一种新的超声频谱法快速测量航空钛合金板经喷砂预处理后的胶接表面粗糙度,并引入表面面积均方根粗糙度系数Sr来表征材料表面三维微观形貌．以航空Ti-6Al—4V钛合金胶接板为测量试样,超声换能器接收测试试样表面的反射回波,并计算得到AR参数谱．以反射脉冲AR参数谱和声波镜面反射理论为基础,建立了有关脉冲波声反射系数和表面均方根粗糙度系数Sr的数学模型．利用表面粗糙度系数理论模型．数值计算反射回波的理论频谱曲线,并与实测反射回波AR谱进行拟合．利用最小值搜索算法,处于最佳拟合时的表面粗糙度系数Sr即为试样胶接表面的测量结果．实验表明,超声反射频谱法测量结果与轮廓仪测量结果符合得很好,该测量方法在材料或零部件表面粗糙度在线测量中具有广泛的应用前景．     

航空钛合金板胶接表面粗糙度的超声测量

采用一种新的超声频谱法快速测量航空钛合金板经喷砂预处理后的胶接表面粗糙度,并引入表面面积均方根粗糙度系数ST来表征材料表面三维微观形貌.以航空Ti-6Al-4V钛合金胶接板为测量试样,超声换能器接收测试试样表面的反射回波,并计算得到AR参数谱.以反射脉冲AR参数谱和声波镜面反射理论为基础,建立了有关脉冲波声反射系数和表面均方根粗糙度系数ST的数学模型.利用表面粗糙度系数理论模型.数值计算反射回波的理论频谱曲线,并与实测反射回波AR谱进行拟合.利用最小值搜索算法,处于最佳拟合时的表面粗糙度系数ST即为试样胶接表面的测量结果.实验表明,超声反射频谱法测量结果与轮廓仪测量结果符合得很好,该测量方法在材料或零部件表面粗糙度在线测量中具有广泛的应用前景.     

粗糙界面法向接触振动响应与能量耗散特性研究

粗糙界面的法向接触振动与能量耗散特性对描述界面动力学机理具有重要的理论和实际意义。本文通过建立粗糙界面法向接触振动的动力学模型,提出了其法向接触振动响应特征量和振动能量耗散量的计算方法。基于粗糙表面的三维分形模型描述,构造了粗糙界面的接触力-变形关系式,并与Hertz接触模型的力-变形关系进行了对比分析;建立了粗糙界面接触振动系统的动力学方程,计算了不同表面形貌粗糙界面系统每周期的振动能量耗散率和累计能量耗散率;分析了粗糙界面法向接触振动的响应特征与能量耗散特性,从理论上对界面法向微动能量耗散的实验结果进行了解释,为描述接触界面的动力学机理提供了理论依据。     

混合润滑状态下粗糙界面法向接触刚度计算模型与特性研究

机械装备系统的静态特性和动力学特性取决于系统接触界面法向接触刚度。基于粗糙表面形貌的Greenwood-Williamson统计模型描述与液体润滑界面的油膜共振模型和弹簧模型,推导了机械结构混合润滑粗糙界面固体接触刚度和液体润滑介质接触刚度,并实现粗糙微凸体固体接触刚度与液体润滑介质接触刚度的耦合,提出了一种混合润滑状态下粗糙界面法向接触刚度的计算模型,分析了接触界面形貌参数、润滑介质和接触基体材料属性对界面法向接触刚度的影响规律。结果表明:润滑介质的声阻抗是影响液体接触刚度的主要因素,声阻抗增大时,液体接触刚度减小;接触基体材料的表面形貌和弹性模量是影响固体接触刚度的主要因素,界面粗糙度和弹性模量增大时,固体接触刚度增大。混合润滑粗糙界面接触刚度计算模型的提出,为机械结构润滑接触界面的刚度计算、性能预测与优化提供理论和实验参考。     

基于分形理论的两粗糙表面接触的黏滑摩擦模型EI北大核心CSCD

两粗糙表面的接触本质上是大量微凸体的接触,具有复杂的力学行为,连接界面的力学建模是重要的科学问题。从微观角度出发,对单个微凸体进行接触分析,并考虑了微凸体相互作用造成的基底面的下降,根据分形理论积分,建立了整个接触面的法向接触模型。利用该模型,可确定在给定法向预紧载荷下微接触截面积的概率密度函数;根据Mindlin模型、Masing准则和分形理论,建立了两粗糙表面接触的切向载荷与切向位移的关系,并研究了不同参数对系统能量耗散的影响。数值仿真结果表明,能量耗散随分形维数D增大而增大,随分形粗糙度参数G及法向预紧力增大而降低。     

可控震源振动器平板-大地接触性质与能量传递研究

大地的表面形貌是影响可控震源振动器平板与大地之间接触性质的因素之一。为了掌握大地表面参数对可控震源振动器平板-大地接触系统接触性质及振动特性的影响规律，基于分形理论建立了三维粗糙大地表面形貌，构建了振动器平板-大地接触模型，得到了不同大地表面形貌及材料参数下振动器平板与大地之间的接触力-变形曲线；建立了振动器平板-大地接触振动动力学方程，并计算了振动器平板的位移响应以及能量传递。结果表明：振动器平板与大地之间接触力的非线性随大地表面粗糙度的增大而增大，振动器平板-大地接触系统的固有频率随大地表面粗糙度的增大而减小；粗糙表面的接触模型中振动器平板每一周期向大地传递的能量随时间的增大而减小。同时，大地表面材料参数的非线性也会影响平板-大地接触系统的振动响应和能量传递。由此可知，大地表面的粗糙度和材料的非线性是限制可控震源高频输出的重要原因。研究结果将为可控震源的优化和高频拓展提供参考。     

分形粗糙表面加卸载接触特性演变行为分析

粗糙表面加卸载接触特性演变行为对研究界面接触力学性能具有重要的理论意义。基于粗糙表面分形理论,依据修正的双参数Weierstrass-Mandelbrot(W-M)分形函数,采用点云处理技术和Coons patch曲面拟合方法生成三维分形粗糙表面数字模型。根据Prandtl-Reuss本构关系和von Mises屈服准则,选择双线性等向强化非线性材料,建立了精确的分形粗糙表面与刚性平面接触有限元模型。探讨加卸载过程中分形维数和尺度参数对粗糙表面接触载荷、接触面积和变形量的影响;同时,采用核密度估计法分析不同接触状态下粗糙表面形貌高度参数分布的演变规律,并从分形参数和能量角度揭示分形粗糙表面接触特性的内在机理,为进一步研究粗糙表面接触力学性能和载荷传递效率与增强机理提供理论依据。     

基于超声和图像的法向刚度测量方法分析

工程应用中接触界面法向刚度的检测一般采用超声法和图像法,但是采用不同检测方法对结果的影响并未深入研究。设计并搭建了一套能同时进行接触界面法向刚度超声和图像测量的实验平台,实验结果表明图像法检测刚度结果低于超声法,更接近于仿真结果。从实验原理上分析了不同检测方法对结果的影响,更深入地分析了接触界面测量机理,为工程应用中结合实际工况选用合适的检测方法提供参考。     

高温接触热阻的有限元模拟方法

基于多点接触理论建立了高温接触热阻的计算模型及其有限元格式,模型的基本尺寸取自表面粗糙度测量时的特征尺寸,该模型能有效模拟界面粗糙度、界面压力、界面温度和间隙填料热导率等参数对界面接触热阻的影响,同时也考虑了高温环境下材料热导率随温度变化的特点以及通过界面间隙的辐射换热效应。在此基础上,针对影响接触热阻的若干主要参数进行了研究。数值算例表明:该文所建立的有限元计算模型及其计算方法不仅能有效地模拟不同条件下高温接触热阻的变化规律,也为进行高温接触热阻研究提供了一种新途径。     

复合材料螺栓连接松弛的弹-黏塑性分析方法

预紧力松弛是影响复合材料螺栓连接结构耐久性的主要原因之一。本文重点讨论导致预紧力松弛的材料蠕变与粗糙表面接触蠕变的相互影响。内容包括建立了以弹-黏塑性理论为基础的复合材料蠕变本构模型,并结合考虑粗糙表面的分形接触理论,将其推广到与时间相关的弹-黏塑性接触问题。数值结果与实验结果对比表明,考虑粗糙表面接触效应时,计算误差从2.87%~4.37%降至0.04%~0.5%,预测准确性有显著提高。表面分形参数D和G的讨论结果表明,接触表面越粗糙,预紧力越容易松弛。这对工程上通过控制表面形貌参数来改善表面接触性质具有指导意义。     

Ultrasonic reflection from a stressed interface

In seeking to develop an NDE technique for verifying the serviceability of NiTi couplers for plumbing unions, it was found that the reflection coefficient for a normally incident ultrasonic wave correlated with the stress level at the NiTi-tubing interface. Current theory pertaining to interface reflection is not complete but, even at present status, there is semiquantitative accord between theoretical predictions and normalized data for reflection coefficient versus stress level. These results are at fixed frequency and with comparable surface roughness. Variation of either frequency or surface roughness further affects the reflection coefficient. Current studies are being pursued to define this effect.     

润滑状态下线接触滑动粗糙界面的动摩擦特性研究

滑动粗糙界面的摩擦润滑特性对界面的润滑设计和润滑状态预测具有重要的理论和实际意义。本文通过建立不同润滑状态下的滑动粗糙界面模型,基于界面的法向载荷由润滑油膜和粗糙体共同承担的载荷分配思想,采用Greenwood-Williamson统计模型描述粗糙表面形貌,考虑界面润滑的时变效应和润滑油的粘-压特性,建立了线接触滑动粗糙界面的油膜厚度方程和粗糙体接触压力方程,获得了整个润滑区的润滑油膜载荷比例因子、油膜厚度和摩擦系数随滑动速度的变化关系,推导了界面由混合润滑过渡为液压润滑的临界速度关系表达式,分析了滑动粗糙界面的润滑承载机理,获得了界面油膜厚度、摩擦系数和临界速度随界面形貌参数、法向载荷、润滑油属性参数的变化规律,为机械结构的界面润滑设计、润滑状态预测和润滑优化提供理论和实验参考。     

圆柱滚子轴承混合润滑状态下的超声法膜厚测量

圆柱滚子轴承由于其线接触特点被广泛应用于各类低速重载工况下的大型设备中,其运行性能和稳定性与滚子和内外圈间的接触润滑状态密切相关;基于等效刚度的超声法可用于实际工况的滚子轴承弹流润滑油膜厚度测量,但无法直接适用于低速重载工况下流体润滑和粗糙峰接触共存的混合润滑状态膜厚测量。为此,提出了一种混合润滑状态下的超声测量方法,建立了界面油膜刚度和粗糙体接触刚度的并联模型,通过引入接触系数并结合经验公式对超声法所测界面总刚度进行分解,获取混合润滑状态下的油膜刚度,进而得到更加准确的油膜厚度。将实验结果和理论结果的对比分析,验证了该模型的可行性和有效性。     

Dry Coupling Ultrasonic High Frequency (10–100 MHz) Sensors for Detection of Surface and Tribological Properties at a Submicrometric Scale

Acoustic plane sensors adequately pressed against materials are suitable to measure elastic constants from flight-time measurement, without any coupling fluid for high temperature, with longitudinal and transverse acoustic waves in the megacycle range. Soft delay lines are generally used to match the sample roughness and to make mechanical play correction easier. At the opposite, our sensors use a hard delay line with a mirror-polished end surface. An experimental set-up is presented to perform acoustic reflection measurement in various contact conditions by increasing the applied mechanical load. The frequency dependence of this parameter is also measured in the 10- to 100-MHz range. Reproducibility tests are presented to validate this experimental set-up, but the main results concern the surprising ability of this technique to detect surface property modifications limited to thickness less than 1 m. Indeed, surface modification induced by different solvents on glass substrates has been detected by this means. This technique has also been used to detect surface property modifications of lixiviated glasses. In this case, atomic force microscopy and inductively coupled plasma analyses have demonstrated that the earlier stage of the surface damage had been detected whereas the thickness altered by ionic diffusion was less than 100 nm with almost no roughness variation. Similarly, tests on mechanically scratched glasses have shown that samples with an average roughness, respectively, of 4 and 120 nm were easily identified from their reflection coefficient versus load curves. Moreover, the pressure dependence of the acoustic reflection is used to estimate the contact stiffness and the contact area between the sensor and the material as a function of the applied compressive stress for contact, adhesion, and friction investigations.     

Ultrasonic wave scattering from rough,imperfect interfaces. Part I. Stochastic interface models

A theoretical model for ultrasonic wave scattering by geometrically irregular and imperfectly bonded interfaces is presented. In Part I, the normal stiffness of interfaces formed by the partial contact of solids with rough surfaces is estimated for two models of contacting surfaces with random roughness in one dimension only. The first model considers nonconforming surfaces with a single-scale of roughness, while double-scale roughness characterizes the surfaces of the second model, which are conforming at the large scale and nonconforming at the smaller scale. The surfaces' profiles are described by Gaussian probability and spectral densities. The surfaces at each contact are modeled by two cylinders under a compressive load and the normal stiffness per unit area of the interface is evaluated by averaging the stiffness of all the contacts, assuming they do not interact with each other. It is shown that the smaller the roughness, the softer the interface; the larger the autocorrelation length, the softer the interface; and the smaller the initial aperture, the stiffer the interface. Furthermore, interfaces described by the second model appear much stiffer than those described by the first model. The interface characterizations and normal stiffness models developed in Part I will be used in Part II to study the scattering of ultrasonic plane waves by such an interface.     

Measurements of surface texture using ultrasound

A new ultrasonic spectroscopic technique has been developed to measure the gross surface texture of materials. A surface roughness coefficient has been introduced that specifies the texture of a surface on a quantitative basis. Comprehensive theoretical models based on analyzing the frequency spectrum of the received ultrasonic signals have been developed to study the effect of surface texture on reflected ultrasonic pulses from rough surfaces. A minimization function obtains the best match between theoretical models and actual measurements in such a way that the resultant coefficient for the best match represents the surface roughness     

Anomalies in the ultrasound reflection from a solid-dissipative medium interface

The reflection of longitudinal acoustic waves from the interface between a solid and a strongly dissipative medium was theoretically studied. It is shown that the reflection coefficient and the reflected signal phase significantly depend on the coefficient of ultrasound absorption in the dissipative medium. An algorithm for restoring the time variation of the dissipative medium viscosity during solidification is proposed, which is based on the results of measurements of the amplitude reflection coefficient for a pulsed ultrasonic signal. The reflection and transmission coefficients are determined for the ultrasound wave amplitude, velocity, pressure, and intensity. An expression is derived for the acoustic energy absorbed upon reflection from a dissipative medium. A frequency dependence of the amplitude and generalized phase of the signals reflected from and transmitted through the interface are restored from the results of spectral calculations. The theoretical results are confirmed by experimental data on the reflection of acoustic pulses from an organic glass-epoxy compound resin interface measured during solidification of the latter medium. According to these data, the reflection coefficient and the reflected acoustic pulse duration decreased upon solidification of the epoxy compound.     

涂层界面刚度的超声数值仿真检测

针对涂层结合界面刚度在非破坏条件下难以精确测量的问题,提出了一种超声检测特征参量表征刚度系数的方法。利用声波在n层各向同性介质中的反射、透射原理,结合界面的弹簧模型,建立了多层介质界面刚度系数的超声检测数学模型。基体选用钢、铸铁、铝合金,表面选用不同喷涂工艺得到的Al2O3陶瓷涂层,获得了不同界面刚度系数的超声反射频谱。仿真结果表明:分离界面和理想界面时,谐振频率都具有周期性,但周期大小不同;弱结合界面时,随着界面的刚度系数逐渐增加,谐振频率逐渐增多,这些谐振频率均向高频方向移动。与频率较高处相比,频率较低处的谐振频率随着刚度系数的增加向高频移动的速度更快。因此建立了第一个谐振频率与刚度系数之间的关系。在同一刚度系数下,由谐振频率与材料的特性阻抗关系获得如下规律:当涂层材料不变时,谐振频率随着基体特性阻抗的增大而增大;当基体材料不变时,谐振频率随着涂层特性阻抗的增大而减小。给出了以指数函数形式拟合的刚度系数与谐振频率的变化曲线。通过对该指数函数参数与材料特性阻抗之间关系的分析,获得了弱界面时谐振频率与刚度系数和材料特性阻抗三者之间的函数表达式。该方法为涂层复合材料弱界面的超声检测提供了理论支持。     

小斜率近似方法分析粗糙界面声散射问题

利用小斜率近似方法计算了起伏海面的声散射特性,得到了具有高斯分布粗糙海面的平均反射系数（即镜反射系数）计算公式,并与微扰法和Kirchhoff近似做了比较,结果表明小斜率近似是一种非常有效的分析起伏表面散射特性的近似方法。最后讨论了海面镜反射系数随海面的不平整度（波浪的均方根高度）、声波频率和声波入射方向的变化关系,得出了只有在声波波长和起伏波浪高度可比拟时,才有明显的镜反射的结论。这为分析浅海目标声散射特性时,选择是否需要考虑海面（海底）所引起的多途效应提供了理论依据。