层状粘接结构超声检测信号的同态解卷积脱粘界面定征

本文利用建立的多层粘接结构超声无损检测信号的卷积模型,推导出了检测信号的解析表达式,并用同态滤波解卷积方法有效地提取出粘接结构的系统响应,进而由其中界面多次反射响应的位置、幅度和包络等特征参数,实现了脱粘二界面（指空气脱粘）的定征和识别。仿真和实验数据的处理结果表明本文方法对脱粘检测的应用有积极的意义。     

多层粘接结构中脱粘界面的人工神经网络余弦变换谱特征识别

针对钢－橡胶多层粘接结构中界面脱粘的超声检测难题,利用余弦变换（ＤＣＴ）提取的表征检测信号的模式特征矢量,通过人工神经网络模式识别方法对不同界面脱粘时实验检测信号的正确识别,实现了脱粘一、二、三和四界面的检测。本文脱粘界面信号模式的人工神经网络识别系统对现代工业中ＮＤＴ＆ＮＤＥ的自动化有着积极的意义。     

多层结构中脱粘缺陷的超声检测方法

固体火箭发动机多层装药结构中的脱粘类型、位置和尺寸决定了其对整体安全性能构成的威胁程度。该文研究了多层结构中脱粘缺陷的超声检测方法,通过对不同脱粘缺陷超声脉冲回波的特征分析与统计,实现缺陷的定性、定位和定量。首先,采集含有多类脱粘缺陷的粘接结构的超声脉冲回波信号,分析信号中主能量波包所代表的声程,提取五种声程的波峰时刻和幅值作为特征值,组建已知脱粘类型训练样本并输入至BP神经网络,实现特征值域到类别域的非线性映射,即脱粘类型分类;其次,采用阈值法确定缺陷的界面位置;最后,提出分段线性插值-相关性定量法将待检测缺陷的定量结果缩小到±2 mm以内。该文利用COMSOL有限元仿真和实验操作验证了多层粘接结构中脱粘缺陷的定性、定位和定量方法的可行性和可靠性。     

粘接界面特性的超声检测与评价

粘接界面特性的超声检测与评价既是物理学的前沿问题,又是经济建设和国防安全亟需解决的应用问题。高波阻介质下多层低波阻介质界面脱粘检测、滑移界面检测和粘接强度定量评价是粘接质量检测中遇到的三大难题。本文综述了课题组十余年来在攻坚三大难题方面的研究工作：建立了共振匹配理论,发明了六项关键技术并实现了技术集成,研制出全新概念的超声检测设备,解决了第一个难题;成功研制出横波直探头,用纵横波综合判断方法解决了第二个难题;对第三个难题,建立了粘接界面非线性弹簧模型,为利用非线性声学参量评价粘接界面奠定了理论基础,并探索性地利用统计性方法对粘接强度进行了预测,取得较好效果。     

多胶接缺陷太赫兹检测信号的PSO-BP神经网络识别

采用太赫兹时域光谱无损检测技术对多胶接结构耐高温复合材料缺陷进行检测。为了识别同一位置上、下层同时存在脱粘缺陷,分析无缺陷区域、上层脱粘区域、下层脱粘区域的太赫兹信号波形,以特征峰峰度、偏度、最小值、峰谷值、波形因子以及信号幅值绝对平均值为特征,作为BP神经网络的输入。并通过粒子群算法优化BP神经网络的初始权重和阈值,解决了BP神经网络易陷入局部最优的问题。粒子群算法优化后的BP神经网络可实现上层100μm和下层100μm脱粘缺陷的识别,准确率达到90.71%和86.92%。     

太赫兹无损检测的多特征参数神经网络分析技术

提出一种基于太赫兹无损检测的多特征参数神经网络分析技术,用于分析耐高温复合材料的粘贴质量无损检测.采用抽片式方法设计了一种耐高温复合材料的脱粘缺陷样品,抽片厚度为0.1mm.采用太赫兹时域光谱无损检测技术对耐高温复合材料的多层脱粘缺陷进行了检测试验研究,对比了上下脱粘缺陷所对应的太赫兹时域波形及频谱信息的异同,针对性地建立了耐高温复合材料粘贴质量的上层脱粘参数、下层脱粘参数、频域吸收质心参数等多特征参数,将特征参数进行优化作为反向传播神经网络的输入并对其进行上下脱粘分类识别.通过对反向传播神经网络的训练测试,实现了耐高温复合材料上层脱粘0.1mm、下层脱粘0.1mm的脱粘缺陷的识别.     

脱粘缺陷对粘接结构频散特性的影响

采用全局矩阵理论,通过引入内聚强度弱化模型和弹簧模型,计算了脱粘缺陷对粘接结构频散特性的影响。分析了内聚强度缺陷、界面缺陷及混合缺陷等因素对粘接结构频散特性的影响,发现频散曲线的演化规律与材料声学性质密切相关。不同材料和不同组合,其规律有很大不同。针对各向同性粘接结构,可能通过考察特定频率段内频散模态的变化,实现对脱粘缺陷的检测。     

“多通道数字成像超声探伤设备”项目简介

高波阻介质下面多层低波阻抗介质的界面脱粘检测是长期以来国内外一直没有解决的世界性难题，称为“二界面问题”。困难主要有两点：其一、高波阻介质与低波阻介质之间的界面两侧波阻抗相差较大，前一介质表面上接收到的界面脱粘反射信号相对入射信号而言是经过了4次镜面屏蔽作用之后的十分微弱的信号；其二、声波在高波阻介质内的多次反射强信号淹没了低波阻介质表面反射的信号。对于高低波阻介质界面间脱粘的超声检测，犹如光学中兽看到一个双面镜子后面的物体一样。     

玻璃纤维蜂窝复合材料的太赫兹无损检测技术(英文)

采用双高斯脉冲反卷积滤波技术对太赫兹时域波形进行滤波优化,提出一种基于太赫兹时域光谱无损检测的太赫兹反射式层析成像技术,用于分析玻璃纤维蜂窝复合材料的粘接质量.结合玻璃纤维蜂窝复合材料结构的特点,分别在蜂窝上层胶膜和下层胶膜中设计了不同直径的圆形和梯形脱粘缺陷,在此基础上,完成了脱粘缺陷蜂窝结构样品的制作.提出的太赫兹反射式层析成像和B-scan成像方法,适用于玻璃纤维蜂窝复合材料的脱粘缺陷分析.针对反射式层析成像图像对比度差的问题,结合脱粘缺陷处的太赫兹时域波形数据特征,采用缺陷特征时间区域成像优化技术,提高了脱粘缺陷的检测能力和识别准确率,实现了玻璃纤维蜂窝材料的上层脱粘厚度50μm、下层脱粘厚度50μm缺陷的太赫兹无损检测.     

电磁声实验平台的研制与实验研究

研制了一个多功能的电磁声实验平台,在此实验平台,进行了"减小盲区"、 "钢层下多层橡胶层脱粘检测"、 "线性调频脉冲压缩"等方面的实验研究.实验结果表明,该平台可精确控制实验参数,提供单一频率脉冲串和线性调频脉冲两种激励波形,具有信噪比高盲区小的优点和线性调频脉冲压缩的功能.将该实验平台应用在钢层与多层橡胶层粘接件的脱粘检测,取得了与压电检测相当的结果.作为一个电磁声方法和技术研究的工具,该实验平台对开展电磁声检测方法和技术研究以及实际检测应用都是有意义的.     

NDT&E using shearography with impulsive thermal stressing and clustering phase extraction

Shearography has been widely adopted for nondestructive testing and evaluation of various materials, especially in the rubber industry and aerospace industry. It detects flaws and defects by identifying deformation anomalies when the specimen is stressed by a certain means. Conventional stressing methods for shearography include pressurization, mechanical or acoustic loading and vibration excitation. These stressing techniques are favorably applied in various applications. In this study, we propose a novel impulsive thermal stressing method using high-power flash lamps for convenient nondestructive testing and evaluation in both laboratory and industrial environment. The proposed technique employs a high-energy heat flux to excite the specimen and detects the thermal deformation anomaly using a shearographic setup. By incorporating a novel clustering phase extraction method, the movement of the continuously deforming object is obtained using only one single deformed speckle image at each deformed stage, thus enabling both qualitative and quantitative measurement. Experiments conducted on various samples with cracks and debonds demonstrate the practicability of proposed technique for both laboratory and industrial applications.     

Dynamic evaluation of flaw size in ultrasonic testing of steel plates

The paper deals with the problems of ultrasonic non-destructive testing of steel plates, such as distance sensitivity, acoustic coupling, flaw position dependence and their influence upon the flaw size evaluation, and describes equipment for the automated testing of circular stampings and their classification according to the size and number of flaws detected.     

A high-frequency warm shallow water acoustic communications channel model and measurements

Underwater acoustic communication is a core enabling technology with applications in ocean monitoring using remote sensors and autonomous underwater vehicles. One of the more challenging underwater acoustic communication channels is the medium-range very shallow warm-water channel, common in tropical coastal regions. This channel exhibits two key features-extensive time-varying multipath and high levels of non-Gaussian ambient noise due to snapping shrimp-both of which limit the performance of traditional communication techniques. A good understanding of the communications channel is key to the design of communication systems. It aids in the development of signal processing techniques as well as in the testing of the techniques via simulation. In this article, a physics-based channel model for the very shallow warm-water acoustic channel at high frequencies is developed, which are of interest to medium-range communication system developers. The model is based on ray acoustics and includes time-varying statistical effects as well as non-Gaussian ambient noise statistics observed during channel studies. The model is calibrated and its accuracy validated using measurements made at sea.     

Combined surface-focused acoustic microscopy in transmission and scanning ultrasonic holography

Employment of ultrasound techniques in nondestructive testing may require identification of the acoustic modes contributing to imaging. Such identification can be achieved, with some restrictions, by time-of-flight analysis. Another approach is acoustic holography that reveals the propagation properties of any selected mode. In anisotropic media, the propagation features are distinct and allow for a reliable classification of the selected mode. Both techniques were applied for classification of bonded, disbonded, and weakly bonded areas in directly bonded semiconductor wafers.     

Auditorium acoustic modelling now

Acoustic scale modelling of auditoria now has a history extending back half a century. Although progress has been intermittent, the essential viability of the modelling process has guaranteed continued elaboration of testing techniques. Modelling techniques have now achieved a certain sophistication and auditorium models have proved very valuable as consultancy and research aids. The work of Jordan and other groups involved in acoustic modelling of auditoria is reviewed briefly with a discussion of the scale factors used and the nature of testing. The current techniques for both objective and subjective model testing are discussed, concluding in each case with an assessment of the level of contribution each can make to auditorium design.     

Fiber-optic acoustic sensor for nondestructive evaluation

An experimental study was conducted to investigate the applicability of fiber-optic acoustic sensors to detect internal flaws in polymeric materials. A polarimetric fiber-optic sensor embedded in a plexiglass model received the acoustic signals generated by an ultrasonic transducer. It is shown that proper control of the polarization and phase of the optical beam is required to obtain meaningful results from the amplitude of the fiber-optic sensor signal. The sensor has shown promising results in determining acoustical properties of plexiglass and locating internal defects. The attractive feature of this sensing scheme is that the optical fibers are not modified prior to embedding. Therefore, they preserve their mechanical properties which makes the embedding process much easier.     

超声显微检测技术在电子封装中的应用与发展

超声显微检测技术应用于电子封装领域始于上世纪80年代,如今已是检测电子封装可靠性和完整性的重要手段,被广泛应用到了电子封装的缺陷检测和精密测量等方面。针对电子封装的超声显微检测存在回波重叠、信噪比低等问题,近年来,发展了许多时频分析方法,用于获得优于常规方法的纵向分辨率,即实现超分辨率。本文首先介绍了超声显微检测的发展历史,对其检测原理和分辨率理论进行了简述;其次,综述了超声显微检测技术在电子封装中的主要应用与发展现状;然后,对超声显微检测的超分辨率成像方法进行了综述,分别介绍了基于小波分析的反卷积、连续小波变换和稀疏表示在实现超分辨率时的原理及适用场景;最后,探讨归纳了电子封装超声显微检测的主要研究方向及难点。     

混凝土材料声发射信号的频率特征及其与强度参量的相关性试验研究

混凝土材料声发射信号频率特征与强度指标的关系是混凝土材料声发射检测技术的重要基础。通过实验,对声发射信号频率特征与混凝土强度指标的相关关系进行了探讨。研究结果表明,在较低的应力水平上,不同强度等级混凝土声发射信号大都是低频信号。而在较高应力水平时,随着强度等级的增加,声发射信号的优势频率则逐渐升高。     

DC effects,sub-harmonics,stochasticity and "memory" for contact acoustic non-linearity

Acoustic wave interaction with non-bonded contacts was found to be inherently non-linear due to asymmetrical stiffness distribution across the interface. A diode-type non-linearity results in local static elastic fields inside the contact, which are shown to be a source of transient longitudinal and shear DC-acoustic pulses polarized oppositely to a biasing contact stress. A parametric modulation of contact stiffness leads to acoustic instability effects, multiple sub-harmonics, and amplitude "self-modulation", and provides chaotic noise-like non-linear acoustic excitations in solids. For realistic cracked flaws, contact acoustic non-linearity exhibits amplitude hysteresis and storage caused by acoustic wave impact on the defect. Maximum storage time observed comes to several hours for read-in time less than half a minute. A long-term non-linear memory is believed to be due to a slow relaxation of thermally induced micro-strain within the crack area.     

Signal loss of double transmissions of ultrasonic waves through random rough surfaces

This paper establishes a model evaluating the signal loss of double transmitted acoustic beams through random rough liquid-solid surfaces based on Fresnel approximation and the phase-screen approximation. The numerical solution is replaced with a simple analytical solution through using the exponential substitution approach to remove the nonlinear integral terms. Therefore, the real-time inspection by using C-scan imaging systems of flaws in materials can be achieved through the proposed model. The research results show that the signal loss of double transmissions from random rough surfaces mainly depends on two factors: the root-mean-square (RMS) of the roughness and the depth of the flaw in materials. The experimentally measured signal loss is in good agreement with the theoretical predictions. The evaluation of the signal loss can be useful for improving the accuracy and reliability of the non-destructive testing (NDT).