压电陶瓷超声波马达

压电陶瓷超声波马达是利用压电陶瓷材料激发超声波实现驱动的一种新型电机,同传统的电磁马达和静电马达比较,它具有低速下大力矩输出、无电磁干扰、静音操作、保持力矩大、响应速度快、结构简单等特点.在国外,它已经在精密仪器、航天航空、自动控制、办公自动化、微型机械系统、微装配、精密定位等领域得到了实际应用.文章系统地总结了压电陶瓷声马达的特点,简略介绍了国内外相关技术的发展情况及前沿性研究方向,并提出进一步开发研究的几点建议,希望会对我国压电陶瓷声马达的研究以及相应产品的开发起到积极的促进作用.     

压电陶瓷超声波马达

压电陶瓷超声波马达是利用压电陶瓷材料激发超声波实现驱动的一种新型电机，同传统的电磁马达和静电马达比较，它具有低速下大力矩输出、无电磁干扰、静音操作、保持力矩大、响应速度快、结构简单等特点。在国外，它已经在精密仪器、航天航空、自动控制、办公自动化、微型机械系统、微装配、精密定位等领域得到了实际应用。文章系统地总结了电压陶瓷声马达的特点，简略介绍了国内外相关技术的发展发问及前沿性研究方向，并提出进一步开发研究的几点建议，希望会对我国压电陶瓷声马达的研究以及相应产品的开发起到积极的促进作用。     

宏声声学器材厂生产压电陶瓷材料

河北省保定市宏声声学器材厂（原化新压电陶瓷器件厂）生产的PMN压电材料，其配方于1987年通过了由声学专家组成的省级技术鉴定．这是一种高KP，高介电常数，低Q。的压电材料，适用于接收型换能器．该厂目前已形成PMN、PZT等四大系列产品的生产能力：1．用P（ZTNU七；压电材料制造的油田声波测井YTG－l－7型高温测井压电陶瓷换能元件，测井时可发射、接收并用，从室温到20OC高温，机电转换率的变化率＜6％．2．用于接收的PMN压电材料及FTD蜂鸣片产品，适用于仪器仪表，传感器，电话机及讯响器．3．大功率发射型材料PZT－8，适…     

新书评介

电子陶瓷情报网编的《压电陶瓷应用》一书,于1985年8月由山东大学出版社出版.压电陶瓷是声学中广泛应用的电-声换能材料,由压电陶瓷做成的各种声学器件,是一些声学仪器、设备中的关键部件.该书从实用角度出发,对压电陶瓷在各类声学仪器中的作用、工作机理与方式等,给予了简要的说明;对一些典型的换能器,给出了设计的考虑原则、制做工艺、计算公式,并给出了具体结构的实例. 全书共分七章:第一章“在高电压发生装置中的应用”,介绍了压电陶瓷点火器、变压器、玩具遥控信号发生器、压电按扭开关等;第二章“在电声等设备上的     

功能材料及其应用于换能器技术的研究进展

文章综述了功能材料及其应用于换能器技术的研究进展,包括声学换能器领域应用的功能材料发展状况及基于这些材料的换能器新设计,所提及的材料包括磁致伸缩材料、弛豫铁电材料、压电复合材料、压电聚合物材料及高温压电陶瓷材料等等.文章还概要介绍了一项应用于声学换能器领域的新技术——微机电(MEMS)技术及其换能器.     

功率型压电陶瓷的分类及研究进展综述

功率型压电材料是大功率换能器及压电变压器等的核心功能材料,广泛应用于声纳系统、超声检测、振动控制及其它机电设备等。尽管其组成和制备方法与其他压电材料类似,但特定的使用目的对功率型压电材料提出了特殊的综合性能要求。本文基于对功率型压电陶瓷材料组成的分类归纳,综述了该材料的性能特点、国内外研究进展,并对现存问题和应用前景进行了论述。     

同步辐射中双压电片反射镜的研究现状

反射镜是同步辐射光束线中应用广泛的光学元件之一,双压电片反射镜由于具有结构简单、面形能动以及自适应可调等优点,逐渐引起同步辐射界的重视.本文综述了同步辐射中双压电片反射镜的研究现状.主要讨论了双压电片反射镜的工作原理和研究概况,包括在几个大型同步辐射装置中的结构特点、制备技术及面形校正结果等;简要介绍了双压电片反射镜面形校正时所采用的反射波前探测技术和反馈控制算法;最后总结了其发展中存在的关键问题,并展望了其未来的发展方向.     

面向空耦电声换能器应用的高性能FEP/PTFE复合膜压电驻极体

压电驻极体(也称为铁电驻极体)是一类具有强压电效应的微孔结构驻极体材料,具有柔韧、低密度、低特性声阻抗等特征,是制备柔性空气耦合声电换能器的理想材料.针对器件对高灵敏度和高温工作环境的应用需求,本文报道高性能氟化乙丙烯/聚四氟乙烯(FEP/PTFE)复合膜压电驻极体的制备和性能表征.研究结果表明,FEP/PTFE膜的特...     

铌酸钾钠基无铅压电陶瓷纵振换能器*

高性能环境友好型无铅压电陶瓷及其应用是当前压电材料研究的热点之一,为了探究其在水声换能器领域的应用潜力,该文对铌酸钾钠基无铅压电陶瓷和锆钛酸铅压电陶瓷纵振式换能器进行了对比研究。依据仿真结果优化结构尺寸,制作了两种换能器样机并测试了其在空气中和水中的电声性能。测试结果表明,铌酸钾钠基无铅压电陶瓷换能器的谐振频率为35kHz,最大发送电压响应为 151dB,声源级可达 190dB,在 26kHz~67kHz 的频率范围内发送电压响应的起伏不超过±4.5dB,谐振频率处-3dB 的指向性开角约为 76°。该无铅压电陶瓷换能器具有和锆钛酸铅压电陶瓷换能器相当的发射性能,有望推动无铅压电材料在水声换能器领域的应用进程。     

压电陶瓷压电特性的激光调制法测量研究

介绍可测量压电陶瓷压电特性的激光干涉调制测量方法.采用相干检测原理对信号进行提取,不仅可以抑制噪声对干涉信号的影响,而且还可以大大降低光电探测器和电路的1/f噪声.与通常干涉仪测量方法相比,这种方法具有测量灵敏度高等优点.利用该方法对压电陶瓷压电特性进行了测量,讨论了激励电压信号的频率、幅度对压电陶瓷压电常数d₃₁的影响,并对其压电迟滞曲线进行了测量.     

基于温度效应的无限长压电圆杆纵波分析

利用有限变形理论,以无限长压电圆杆为研究对象,考虑了在横向惯性、等效泊松比效应以及在热电弹藕合共同作用下,基于Hamilton原理,并引入Euler方程推导出压电圆杆的纵向波动方程.采用Jacobi椭圆函数展开法,求解压电圆杆的波动方程和对应的解.最后,通过Matlab软件得到不同波速比下的色散曲线.以及温度场对压电圆杆的波形、波幅和波数的影响曲线.数值分析结果表明:随着温度的升高,波速逐渐降低,温度场的改变可影响和控制孤立波的传播特性.     

Electro-mechanical response of functionally graded beams with imperfectly integrated surface piezoelectric layers

The time-dependent behavior of a simply-supported functionally graded beam bonded with piezoelectric sensors and actuators is studied using the state-space method. The creep behavior of bonding adhesives between piezoelectric layers and beam is characterized by a Kelvin-Voigt viscoelastic model, which is practical in a high temperature circumstance. Both the host elastic functionally graded beam and the piezoelectric layers are orthotropic and in a state of plane stress, with the former being inhomogeneous along the thickness direction. A laminate model is employed to approximate the host beam. Moreover, the coupling effect between the elastic deformation and electric field in piezoelectric layers is considered. Results indicate that the viscoelastic property of interfacial adhesives has a significant effect on the function of bonded actuators and sensors with time elapsing.     

Review of some lesser-known applications of piezoelectric and pyroelectric polymers

The piezoelectric effect was first observed in polyvinylidene fluoride polymer (PVDF) in 1969, and the pyroelectric effect was found several years later. A number of additional ferroelectric polymers have been discovered since that time including the copolymer PVDF with trifluoroethylene (P(VDF-TrFE)), and the odd-numbered nylons. A large number of applications of piezoelectricity and pyroelectricity have been developed. The magnitudes of the effects in polymers are much lower than those of ferroelectric ceramics (an exception is the piezoelectric effect in porous polymers). However, other factors make these very desirable materials for applications. The polymers have low permittivities, low acoustic impedances and low thermal conductivities. They are available in large area sheets, flexible, and relatively low in cost. Major applications include microphones and loudspeakers, ultrasonic devices, SAW transducers, actuators, single-element infrared detectors and many others. This review will describe some of the lesser-known applications of these materials in the areas of tactile devices, energy conversion, porous polymers, property measurement, pyroelectric infrared sensors, shock sensors and space science. PACS 73.61.Ph; 77.84.-s; 82.35.Lr; 85.50.-n     

Solid state detectors for neutron radiation monitoring in fusion facilities

The purpose of this communication is to summarize the main solid state based detectors proposed for neutron diagnostic in fusion applications and their applicability under the required harsh conditions in terms of intense radiation, high temperature and available space restrictions. Activation systems, semiconductor based detectors, luminescent materials and Cerenkov fibre optics sensors (C-FOS) are the main devices that are described.     

Processing,Structure, Properties,and Applications of PZT Thin Films

There has been a resurgence of complex oxides of late owing to their ferroelectric and ferromagnetic properties. Although these properties had been recognized decades ago, the renewed interest stems from modern deposition techniques that can produce high quality materials and attractive proposed device concepts. In addition to their use on their own, the interest is building on the use of these materials in a stack also. Ferroelectrics are dielectric materials that have spontaneous polarization in certain temperature range and show nonlinear polarization–electric field dependence called a hysteresis loop. The outstanding properties of the ferroelectrics are due to non-centro-symmetric crystal structure resulting from slight distortion of the cubic perovskite structure. The ferroelectric materials are ferroelastic also in that a change in shape results in a change in the electric polarization (thus electric field) developed in the crystal and vice versa. Therefore they can be used to transform acoustic waves to electrical signal in sonar detectors and convert electric field into motion in actuators and mechanical scanners requiring fine control. In a broader sense the ferroelectric materials can be used for pyroelectric and piezoelectric sensors, voltage tunable capacitors, infrared detectors, surface acoustic wave (SAW) devices, microactuators, and nonvolatile random-access memories (NVRAMs), including the potential production of one transistor memory cells, and applications requiring nonlinear optic components. Another set of potential applications seeks to exploit the ferroelastic properties in stacked templates where they are juxtaposed to ferromagnetic materials. Doing so would allow the control of magnetic properties with electric field, which is novel. Such templates taking advantage two or more properties acquired a new name and now goes by multiferroics. After a brief historical development, this article discusses technological issues such as growth and processing, electrical and optical properties, piezo, pyro, and ferroelectric properties, degradation, measurements methods, and application of mainly lead-zirconate-titanate (PZT = PbZr_1?xTi_xO₃). The focus on PZT stems from its large electromechanical constant, large saturation polarization and large dielectric constant.     

Hysteresis compensation of piezoelectric actuators: The modified Rayleigh model

In this study, we develop a novel modified Rayleigh model for hysteresis compensation in piezoelectric actuators. Piezoelectric actuators suffer from hysteresis, in large drive fields of more than 100 V, which can result in serious displacement errors. The typical phenomenological approach is to use the Rayleigh model; however, this model gives more than 10% difference with experiments at the large electric fields of more than 1 kV/mm. Furthermore, there are no studies that apply the Rayleigh model to the compensation of precision actuators, such as stack actuators; it has only been applied in the study of the physical properties of piezoelectric materials. Therefore, we propose a modified Rayleigh model, in which each coefficient is defined differently according to whether the field is increasing or decreasing to account for asymmetry at the high fields. By applying a computer-based control from an inverse form of this modified Rayleigh model, we show that we can compensate for hysteresis to reduce the position error to less than five percent. This model has the merits of reducing complicated fitting procedures and of saving computation time compared to the Preisach model. Specifically, this model cannot only predict the hysteresis curves in all local fields using only one fitting procedure, but also make it possible to control the displacement of various piezo-based actuators without expensive sensors, based on the charge-based model.     

Growth and high-temperature electromechanical properties of Ca3NbX3Si2O14 (X=Ga and Al) piezoelectric crystals

Piezoelectric single crystals of Ca₃NbX₃Si₂O₁₄ (CNXS, X=Ga and Al) with ordered langasite structure were successfully grown using the Czochralski technique. The structure was analyzed by X-ray powder diffraction, and the lattice parameters for CNAS were found to decrease slightly when compared to CNGS, due to the smaller ion radius of Al. The dielectric, piezoelectric and electromechanical properties were studied as function of temperature from 30 ^°C to 900 ^°C, showing a stable temperature-dependent behavior. Of particular significant is their high mechanical quality factor and electrical resistivity at elevated temperature, demonstrating CNXS crystals to be promising candidates for high-temperature applications.     

Transparent ZnO/glass surface acoustic wave based high performance ultraviolet light sensors

Surface acoustic wave(SAW) resonators are a type of ultraviolet(UV) light sensors with high sensitivity, and they have been extensively studied. Transparent SAW devices are very useful and can be developed into various sensors and microfluidics for sensing/monitoring and lab-on-chip applications. We report the fabrication of high sensitivity SAW UV sensors based on piezoelectric(PE) ZnO thin films deposited on glass substrates. The sensors were fabricated and their performances against the post-deposition annealing condition were investigated. It was found that the UV-light sensitivity is improved by more than one order of magnitude after annealing. The frequency response increases significantly and the response becomes much faster. The optimized devices also show a small temperature coefficient of frequency and excellent repeatability and stability, demonstrating its potential for UV-light sensing application.     

Survey of the present state of the art of piezoelectric linear motors

Piezoelectric ultrasonic motors have been investigated for several years and have already found their first practical applications. Their key feature is that they are able to produce a high thrust force related to their volume. Beside rotary drives like the travelling wave motor, linear drives have also been developed, but only a few are presently commercially available. In the present paper, we first describe the state of the art of linear piezoelectric motors. The motors are characterized with respect to their no-load velocity, maximum thrust force, efficiency and other technical properties. In the second part, we present a new motor, which is judged to be capable of surpassing the characteristics of other piezoelectric motors because of its unique design which allows the piezoelectric drive elements to be pre-stressed in the direction of their polarization. The piezoelectric elements convert energy using the longitudinal d33 effect which allows an improved reliability, large vibration amplitudes and excellent piezoelectric coupling. Energy loss by vibration damping is minimized, and the efficiency can be improved significantly. Experimental results show that the motor characteristics can be optimized for a particular task by choosing the appropriate operating parameters such as exciting voltage, exciting frequency and normal force.