力學與電學耦合問題之含裂縫壓電陶瓷板動態特性研究與實驗量測

Chih-Lin Huang; 黃智麟

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/38411

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	馬劍清
dc.contributor.author	Chih-Lin Huang	en
dc.contributor.author	黃智麟	zh_TW
dc.date.accessioned	2021-06-13T16:32:47Z	-
dc.date.available	2005-07-28
dc.date.copyright	2005-07-28
dc.date.issued	2004
dc.date.submitted	2005-07-11
dc.identifier.citation	Adelman, N. T. and Stavsky, Y., “ Axisymmetric Vibrations of Radially Polarized Piezoelectric Ceramic Cylinders, ” Journal of Sound and Vibration, 38(2), 245-254 ,(1975). Bobnar, V. Kutnjak, Z. and Levstik, A., “ Temperature Dependence of Material Constants of PLZT Ceramics, ” Journal of the European Ceramic Society, 19, 1281-1284 ,(1999). Boriseiko, V. A. and Ulitko, A. F., “ Axisymmetric Oscillations of a Thin Piezoelectric Ceramic Spherical Shell, ” International Applied Mechanics, 10(10), 3-10 ,(1974). Boxiang, L., Harald, A., Heiner, E. and Eckhardt, Z., “ Real Time Investigation of Rotating Objects using ESPI System, ” Proceedings of SPIE, 1026, 218-221 ,(1988). Butters, J. N. and Leendertz, J. A., “ Speckle Pattern and Holographic Techniques in Engineering Metrology, ” Optics and Laser Technology, 3(1), 26-30 ,(1971). Chang, S. H. and Chou, C. C., “ Electromechanical Analysis of an Asymmetric Piezoelectric/Elastic Laminate Structure: Theory and Experiment,” IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 46(2), 441-451 ,(1999). Chang, S. H. and Tung, Y. C., “ Electro-elastic Characteristics of Asymmetric Rectangular Piezoelectric Laminate,” IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 46(4), 950-960 ,(1999). Chang, S. H. and Tung, Y. C., “ Electro-elastic Characteristics of Asymmetric Rectangular Piezoelectric Laminate,” IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 46(4), 950-960 ,(1999). Chang, S. H., Du, B. C. and Lin, J. F., “ Electro-Elastic Modeling of annular Piezoceramic Actuating Disk Transducers,” Journal of Intelligent Materials Systems and Structures, 10(5), 410-421 ,(2000). Creath, K. and Slettemoen, G. A., “ Vibration-Observation Techniques for Digital Speckle-Pattern Interferometry, ” Journal of Optical Society of America (A), 2(10), 1629-1636 ,(1985). Deeg, W. F., “ The Analysis of Dislocation, Crack and Inclusion Problems in Piezoelectric Solids, ” Ph.D. Dissertation, Stanford University, CA, ,(1980). Dunn, M. L., “ The Effects of Crack Face Boundary Conditions on the Fracture Mechanics of Piezoelectric Solids, ” Engineering Fracture Mechanics, 48, 25-39 ,(1994). Ellingsrud, S. and Rosvold, G. O., “ Analysis of a Data-based TV-Holography System used to Measure Small Vibration Amplitudes, ” Journal of Optical Society of America (A), 2(10), 1629-1636 ,(1985). Fung, R. F., Chao, S. C. and Kung, Y. S., “ Piezothermoelastic Analysis of an Optical Beam Deflector, ” Sensors and Actuators, 87, 179-187 ,(2001). Francois, M. G. and Jacek, J., “ Electromechanical Response of Polymer Films by Laser Doppler Vibrometry, ” Journal of Acoustic Society of America, 103(3), 1421-1427 ,(1996). Gabor, D., “ A New Microscope Principle, ” Nature, 161, 777-778 ,(1948). Gao, C. F. and Fan, W. X., “ Exact Solutions for the Plane Problem in Piezoelectric Materials with an Elliptic or a Crack, ” International Journal of Solids and Structures, 36, 2527-2540, (1999). Guo, N., Cawley, P. and Hitchings, D., “ The Finite Element Analysis of the Vibration Characteristics of Piezoelectric Discs, ” Journal of Sound and Vibration, 159(1), 115-138 ,(1992). Holland, R., “ Contour Extensional Resonant Properties of Rectangular Piezoelectric Plates, ” IEEE Transactions on Sonics and Ultrasonics, 15(2), 97-105 ,(1968). Holland, R., “ Resonant Properties of Piezoelectric Ceramics Rectangular Parallelepipeds,”Journal of Acoustical Society of America, 43(5), 988-997 ,(1968). Huang, C. H. and Ma, C. C.,“ Vibration Characteristics for Piezoelectric Cylinders using Amplitude-Fluctuation Electronic Speckle Pattern Interferometry, ” AIAA Journal, 36(12), 2262-2268 ,(1998). Huang, C. H. and Ma, C. C,“Vibration Characteristics of Composite Piezoceramic Plates at Resonant Frequencies: Experimental and Numerical Calculations,”IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 48(4), 1147-1156 ,(2001). Hibbit, Karlsson and Sorensen, Inc., ABAQUS User’s Manual, version 5.8 ,(1998). Ivina, N. F., “ Analysis of the Natural Vibrations of Circular Piezoceramic Plates with Partial Electrodes, ” Acoustical Physics, 47(6), 714-720 ,(2001). Jones, R. and Wykes, C., “ General Parameters for the Design and Optimization of Electronic Speckle Pattern Interferometers, ” Optica Acta, 28(7), 949-972 ,(1981). Jones, R. and Wykes, C., Holographic and Speckle Interferometry, Cambridge University Press ,(1989). Karlash, V. L., Klyushnichenko, V. A., Kramarov, Yu. A. and Ulitko, A. F., “ Radial Vibrations of Thin Piezoceramic Disks under a Nonuniform Electric Load, ” International Applied Mechanics,, 13(8), 56-62 ,(1977). Koyuncu, B., “ The Investigation of High Frequency Vibration Modes of PZT-4 Transducers using ESPI Techniques with Reference Beam Modulation, ” Optics and Lasers in Engineering, 1(1), 37-49 ,(1980). Kyihwan, P., Seonjae, K., Sangyol, Y. and Jekil, R., “ Development of Continuous Scanning Laser Doppler Vibrometer for Vibration Mode Shape Analysis, ” Proceedings of the 2000 IEEE International Conference on Control Applications, September, 25-27 ,(2000). Kumar, S. and Singh, R. N., “ Crack Propagation in Piezoelectric Materials under Combined Mechanical and Electrical Loadings, ” Acta Materialia, 44, 173-200, (1996). Kumar, S. and Singh, R. N., “ Energy Release Rate and Crack Propagation in Piezoelectric Materials Part I: Mechanical/Electrical Load, ” Acta Materialia, 45, 849-857 ,(1997). Kumar, S. and Singh, R. N., “ Energy Release Rate and Crack Propagation in Piezoelectric Materials Part II: Combined Mechanical and Electrical Loads, ” Acta Materialia, 45, 859-868, (1997). Lφkberg, O. J., “ Electronic Speckle Pattern Interferometry, ” Physics in Technology, 11, 16-22 ,(1980). Lφkberg, O. J., “ ESPI-The Ultimate Holographic Tool for Vibration Analysis, ” Journal of Acoustic Society of America, 75(6), 1783-1791 ,(1984). Lφkberg, O. J. and Malmo, J. T., “ Long-Distance Electronic Speckle Pattern Interferometry, ” Optical Engineering, 27(2), 150-156 ,(1988). Lee, C. K. and Wu, G. Y., “ High Performance Doppler Interferometer for Advanced Optical Storage Systems, ” Japanese Journal of Applied Physics, 38(3B), 1730-1741 ,(1999). Lee, H. J. and Saravanos, D. A., “ A Mixed Multi-field Finite Element Formulation for Thermopiezoelectric Composite Shells,” International Journal of Solids and Structures, 37, 4949-4967 ,(2000). 142 Lee, H. J., “ Generalized Finite Element Formulation for Smart Multilayered Thermal Piezoelectric Composite Plates, ” International Journal of Solids and Structures, 34(26), 3355-3371 ,(1997). Lin, H. Y. and Ma, C. C., “ Experimental Investigations on Dynamic Characteristics of a Multilayer Piezoelectric Stack Actuator, ” The Chinese Journal of Mechanics-Series A, 18(2), 95-102 ,(2002). Lin, H. Y., Huang, J. H. and Ma, C. C., “ Vibration Analysis of Angle-Ply Laminated Composite Plates with an Embedded Piezoceramic Layer, ” IEEE Trans. Ultrasonics, ferroelectrics, and Frequency Control, 50(9), 1084-1099 ,(2003). Lin, H. Y., Huang, J. H. and Ma, C. C., “ Vibration Analysis of Piezoelectric Materials by Optical Methods, ” IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 49(8), 1139-1149 ,(2002). Ma, C. C. and Huang, C. H., “ Experimental and Numerical Analysis of Vibrating Cracked Plates at Resonant Frequencies, ” Experimental Mechanics, 41(1), 8-18 ,(2001). Ma, C. C. and Huang, C. H., “ Experimental Full Field Investigations of Resonant Vibrations for Piezoceramic Plates by an Optical Interferometry Method, ” Experimental Mechanics, 42(2), 140-146 ,(2002). Ma, C. C. and Huang, C. H., “ The Investigation of Three-Dimensional Vibration for Piezoelectric Rectangular Parallelepipeds Using the AF-ESPI Method, ” IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 48(1), 142-153 ,(2001). Mason, W. P., Piezoelectric Crystals and Their Application to Ultrasonics. New York: Van Nostrand ,(1950). Mazúch, T., Horáček, J., Trnka, J. and Veselý, J., “ Natural Modes and Frequencies of a Thin Clamped-Free Steel Cylindrical Storage Tank Partially Filled with Water : FEM and Measurement, ” Journal of Sound 143 and Vibration, 193(3), 669-690 ,(1996). Mindlin, R. D., “ Forced Thickness –Shear and Flexural Vibrations of Piezoelectric Crystal Plates, ” Journal of Applied Physics, 22(1), 83-88(1952). Nakadate, S., Saito, H. and Nakajima, T., “ Vibration Measurement using Phase-Shifting Stroboscopic Holographic Interferometry, ” Optical Acta, 33(10), 1295-1309 ,(1986). Ogi, H., Kawasaki, Y., Hirao, M. and Ledbetter, H., “ Acoustic Spectroscopy of Lithium Niobate : Elastic and Piezoelectric Coefficients, ” Journal of Applied Physics, 92(5), 2451-2456 ,(2002). Oh, I. K., Han, J. H. and Lee, I., “ Postbuckling and Vibration Characteristics of Piezolaminated Composite Plate Subject to Thermo-Piezoelectric Loads, ” Journal of Sound and Vibration, 233(1), 19-40 ,(2000). Ohno, I., “ Rectangular Parallelepiped Resonance Method for Piezoelectric Crystals and Elastic Constants of Alpha-Quartz, ” Physics and Chemistry of Minerals, 17(5), 371-378 ,(1990). Pak, Y. E., “ Crack Extension Force in a Piezoelectric Material, ” Transactions of the ASME, Journal of Applied Mechanics, 57, 647-653 ,(1990). Park, S. and Sun, C. T., “ Fracture Criteria for Piezoelectric Ceramics, ” Journal of the American Ceramic Society, 78, 1475-1480 ,(1995). Parton, V. Z., “ Fracture Mechanics of Piezoelectric Materials, ” Acta Astronautica, 3, 671-683, (1976). Rogacheva, Nellya N., The Theory of Piezoelectric Shells and Plates, CRC Press, USA ,(1994). Schmidt, G. H., “ Extensional Vibrations of Piezoelectric Plates, ” Journal of Engineering Math, 6(2), 133-142 ,(1972). 144 Shaw, E. A. G., “ On the Resonant Vibrations of Thick Barium Titanate Discs, ” Journal of Acoustical Society of America, 28, 38-50 (1956). Shellabear, M. C. and Tyrer, J. R., “ Application of ESPI to Three-dimensional Vibration Measurements, ” Optics and Lasers in Engineering, 15, 43-56 ,(1991). Shen, S. and Nishioka, T., “ Fracture of Piezoelectric Materials: Energy Density Criterion, ” Theoretical and Applied Fracture Mechanics, 33, 57-65 , (2000). Slettemoen, G. A., “ Electronic Speckle Pattern Interferometric Systems Based on a Speckle Reference Beam, ” Applied Optics, 19(4), 616-623 ,(1980). Wang, W. C., Hwang, C. H. and Lin, S. Y., “ Vibration Measurement by the Time-Averaged Electronic Speckle Pattern Interferometry Methods, ” Applied Optics, 35(22), 4502-4509 ,(1996). Vovkodav, I. F., Karlash, V. L. and Ulitko, A. F., “ Asymmetric Vibrations of Thin Piezoceramic Disks with Split Electrodes, ” International Applied Mechanics, 15(2), 77-82 ,(1979). Grinchenko, V. T., Karlash ,V. T., Meleshko V. V., Ulitko A. F., “ Investigation of Planar Vibrations of Rectangular Piezoceramic Plates, ” Institute of Applied Mechanics , Academy of Sciences of the Ukrainian SSR , Kiev, 12(5), 71-78 ,(1976). Xu, X. L. and Rajapakse, R. K. N. D., “ Analytical Solution for an Arbitrarily Oriented Void/Crack and Fracture of Piezoceramics, ” Acta Materialia, 47, 1735-1747 ,(1999). Zuo, J. Z. and Sih, G. C., “ Energy density theory formulation and interpretation of cracking behavior for piezoelectric ceramics, ” Theoretical and Applied Fracture Mechanics , 34, 17-33 ,(2000). 林憲陽，壓電陶瓷複合層板動態特性之數值分析與實驗量測， 145 國立台灣大學機械工程研究所博士論文，91 年6 月。吳錦源，創新雷射都卜勒振動/干涉儀之研製-高性能微光機電系統之量測，國立台灣大學應用力學研究所博士論文，87 年6 月。黃吉宏，應用振幅變動電子斑點干涉術探討三維壓電材料體及含裂紋板的振動問題，國立台灣大學機械工程研究所博士論文，87 年 6 月。黃育熙，壓電石英晶體之平板結構的動態特性研究，國立台灣大學機械工程研究所碩士論文，92 年6 月。林育志，壓電元件於不同介質中的動態特性研究與實驗量測，國立台灣大學機械工程研究所博士論文，93 年6 月。蔡松木，利用數位相機量測裂縫應力集中係數之研究，國立成功大學土木工程研究所碩士論文，93年7月。翁世明，材料非等向性對結構破壞行為的影響，國立成功大學機械工程研究所博士論文，93年5月
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/38411	-
dc.description.abstract	由於壓電陶瓷材料是屬於脆性材料，且在動態的週期性高頻電壓驅動下壓電陶瓷材料的溫度會急速升高，在這種高溫且高頻率的動態負載環境下，脆性壓電陶瓷材料極易由於疲勞的累加而產生微裂紋，並逐漸擴展成巨觀形式的裂紋，不但對於壓電材料會衍生應力集中甚至裂紋快速擴展的破壞問題而影響壓電陶瓷材料的安全及穩定性，進而由於裂紋的產生也會影響壓電陶瓷材料的動態特性，並對於壓電陶瓷平板表面的電極也會形成部分的短路而影響壓電材料內部電場的分布，因而對於壓電陶瓷平板的動態加載衍生額外的問題進而改變壓電陶瓷平板的動態特性。本論文主要應用光學全域式的振幅變動電子斑點干涉術並配合逐點式的雷射都卜勒振動儀和阻抗分析儀等三種實驗量測技術，並配合有限元素分析和理論解析針對無裂縫、含單一對稱裂縫及非對稱裂縫壓電陶瓷平板在自由邊界及單邊固定的邊界條件下，以兩種不同厚度的試片，對於其振動特性加以分析，文中亦將探討特殊電極分布對振動特性的影響，以及溫度與振動特性的關係，以期能對於壓電元件日漸廣泛之應用與研究分析能有所助益；並對於工業上不同需求的壓電元件，提供設計上的參考與依據	zh_TW
dc.description.abstract	Because piezoelectric material is a brittle material and usually be driven by high frequency and voltage, cracks are easily found in piezoceramic material. These cracks will result in stress concentration and the safety and reliability of the materials will become a problem. Moreover, the existence of cracks will change the shape of electrodes and the dynamic characteristics of the piezoceramic plates will be influenced. Hence the problem of piezoceramic plates with cracks is complicated because it combines the fields of vibration analysis, electricity and fracture mechanics. In this thesis, three experimental techniques, AF-ESPI, LDV and impedance analyzer are used to obtain the vibration characteristics of piezoceramic plates and the experimental results are verified by FEM simulation. The dynamic characteristics of piezoceramic plates without crack, with one center crack and two cracks are investigated in detail. It is shown that the theoretical predictions by the finite element method and the experimental results agree fairly well for the resonant frequencies and mode shapes. Besides, in order to understand the influence of electrode on the vibration properties, we also analyze dynamic characteristics of the piezoceramic plates with special design of electrodes. Finally, the relationship between temperature and vibration characteristics of piezoceramic plates is established base on experimental measurement.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T16:32:47Z (GMT). No. of bitstreams: 1 ntu-93-R92522502-1.pdf: 34442953 bytes, checksum: 7c4a3d396b3839921fb09a76bebb30d8 (MD5) Previous issue date: 2004	en
dc.description.tableofcontents	誌謝......................................................一摘要......................................................二目錄......................................................四表目錄....................................................七圖目錄..................................................十一符號說明................................................十九第一章緒論 1-1 研究動機.............................................1 1-2 文獻回顧.............................................4 1-3 內容簡介............................................13 第二章實驗理論基礎與技術及系統架設 2-1 電子斑點干涉術(ESPI)之基本理論......................16 2-1-1 面外振動的量測......................................17 2-1-2 面內振動的量測......................................22 2-1-3 電子斑點干涉術之實驗與理論關係探討..................24 2-2 雷射都卜勒振動儀....................................28 2-2-1 簡介................................................28 2-2-2 雷射都卜勒振動儀的量測原理..........................29 2-2-3 雷射都卜勒動態信號分析之量測系統....................33 2-3 阻抗分析............................................34 2-3-1 阻抗分析之基本原理..................................34 2-3-2 阻抗分析之實驗架設..................................36 第三章壓電陶瓷平板之振動特性分析 3-1 壓電理論及材料特性介紹..............................39 3-2 自由邊界之壓電陶瓷平板(厚度1mm)之振動特性分析.......44 3-2-1 實驗方法、架設與結果 44 3-2-2 數值分析比較與結果探討 50 3-3 自由邊界之壓電陶瓷平板(厚度0.5mm)之振動特性分析.....54 3-3-1 實驗方法、架設與結果................................54 3-3-2 數值分析比較與結果探討..............................56 3-4 單邊固定之壓電陶瓷平板(厚度1mm)之振動特性分析.......59 3-4-1 實驗方法、架設與結果 59 3-4-2 數值分析比較與結果探討 62 3-5 單邊固定之壓電陶瓷平板(厚度0.5mm)之振動特性分析.....66 3-5-1 實驗方法、架設與結果................................66 3-5-2 數值分析比較與結果探討..............................68 3-6 特殊電極分佈對自由邊界之壓電陶瓷平板(厚度1mm) 之振動特性分析......................................72 3-6-1 實驗方法、架設與結果................................72 3-6-2 數值分析比較與結果探討..............................75 第四章含對稱裂縫之壓電陶瓷平板之振動特性分析 4-1 相關破壞力學理論簡介................................77 4-2 自由邊界之含裂縫壓電平陶瓷平板(厚度1mm) 之振動特性分析......................................81 4-2-1 實驗方法、架設與結果................................81 4-2-2 數值分析比較與結果探討..............................84 4-2-3 含裂縫壓電陶瓷平板與無裂縫壓電陶瓷平板 (厚度1 mm)之振動特性比較分析........................87 4-3 自由邊界之含裂縫壓電陶瓷平板(厚度0.5mm) 之振動特性分析......................................90 4-3-1 實驗方法、架設與結果................................90 4-3-2 數值分析比較與結果探討..............................92 4-3-3 含裂縫壓電陶瓷平板與無裂縫壓電陶瓷平板 (厚度0.5 mm)之振動特性比較分析......................96 4-4 單邊固定之含裂縫壓電陶瓷平板(厚度1mm) 之振動特性分析......................................99 4-4-1 實驗方法、架設與結果................................99 4-4-2 數值分析比較與結果探討.............................102 4-4-3 含裂縫壓電陶瓷平板與無裂縫壓電陶瓷平板 (厚度1 mm)之振動特性比較分析.......................105 4-5 單邊固定之壓電陶瓷平板(厚度0.5mm) 之振動特性分析.....................................108 4-5-1 實驗方法、架設與結果...............................108 4-5-2 數值分析比較與結果探討.............................110 4-5-3 含裂縫壓電陶瓷平板與無裂縫壓電陶瓷平板 (厚度0.5 mm)之振動特性比較分析....................114 4-6 含裂縫壓電陶瓷平板與無裂縫壓電陶瓷平板振動特性與溫度之關係.............................................117 4-6-1 實驗方法、架設與結果...............................117 4-6-2 結果探討...........................................119 第五章含非對稱裂縫之壓電陶瓷平板之振動特性分析 5-1 自由邊界之含非對稱裂縫壓電陶瓷平板之振動特性分.....122 5-1-1 實驗架設、過程及結果...............................122 5-1-2 數值分析比較與結果探討.............................126 5-1-3 自由邊界無裂縫、含對稱裂縫及非對稱裂縫壓電陶瓷平板(厚度1 mm)之振動特性比較分析...............129 第六章結論與展望 6-1 本文主要成果.........................................132 6-2 未來展望.............................................136 參考文獻.................................................138
dc.language.iso	zh-TW
dc.subject	壓電陶瓷	zh_TW
dc.subject	裂縫	zh_TW
dc.subject	Crack	en
dc.subject	Piezoceramic	en
dc.title	力學與電學耦合問題之含裂縫壓電陶瓷板動態特性研究與實驗量測	zh_TW
dc.title	Experimental Measurements on Dynamic Characteristics of Piezoceramic Plates with Cracks	en
dc.type	Thesis
dc.date.schoolyear	93-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	趙振綱,吳光鐘
dc.subject.keyword	裂縫,壓電陶瓷,	zh_TW
dc.subject.keyword	Piezoceramic,Crack,	en
dc.relation.page	322
dc.rights.note	有償授權
dc.date.accepted	2005-07-11
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	機械工程學研究所	zh_TW
顯示於系所單位：	機械工程學系

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