同步電荷提取自動電路設計及其在轉動式壓電振能擷取之應用

Hsuan-Chia Chang; 張軒嘉

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/72198

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	舒貽忠(Yi-Chung Shu)
dc.contributor.author	Hsuan-Chia Chang	en
dc.contributor.author	張軒嘉	zh_TW
dc.date.accessioned	2021-06-17T06:28:25Z	-
dc.date.available	2018-08-21
dc.date.copyright	2018-08-21
dc.date.issued	2018
dc.date.submitted	2018-08-16
dc.identifier.citation	[1]Li, B. and You, J. H. (2015). Experimental Study on Self-Powered Synchronized Switch Harvesting on Inductor Circuits for Multiple Piezoelectric Plates in Acoustic Energy Harvesting. Journal of Intelligent Material Systems and Structures, 26, 1646–1655. [2] Cao, J. Y., Ren, X. L., Zhou, S. X. and Cao, B. G. (2012). Vibration Energy Harvesting Based on Synchronized Switch Control of Parallel Inductor. Journal of Vibration and Shock 31:17. [3] Zhao, L., Tang, L., Wu, H. and Yang, Y. (2014) Synchronized Charge Extraction for Aeroelastic Energy Harvesting. Proc. of SPIE ,Vol. 9057 90570N-1 [4] Zhao, L., Tang, L. and Yang, Y. (2016). Synchronized Charge Extraction in Galloping Piezoelectric Energy Harvesting. Journal of Intelligent Material Systems and Structures, 27: 453-468. [5] Leland, E. S. and Wright, P. K. (2006). Resonance Tuning of Piezoelectric Vibration Energy Scavenging Generators Using Compressive Axial Preload. Smart Materials and Structures. 15, 1413-1420. [6] Erturk, A., Renno, J. M. and Inman, D. J. (2009). Modeling of Piezoelectric Energy Harvesting from an L-Shaped Beam-mass Structure with an Application to UAVs. Journal of Intelligent Material Systems and Structures, 20:529–544. [7] Cammarano, A., Burrow, S. G., Barton, D. A. W., Carrella, A. and Clare, L. R. (2010). Tuning a Resonant Energy Harvester Using a Generalized Electrical Load. Smart Materials and Structures, 19, 055003. [8] Lallart, M., Anton, S. R. and Inman, D. J. (2010). Frequency Self-tuning Scheme for Broadband Vibration Energy Harvesting. Journal of Intelligent Material Systems and Structures, 21:897–906. [9] Karami, M. A. and Inman, D. J. (2011). Electromechanical Modeling of the Low-Frequency Zigzag Micro-Energy Harvester. Journal of Intelligent Material Systems and Structures, 22:271–282. [10] Cottone, F., Vocca, H., and Gammaitoni, L. (2009). Nonlinear Energy Harvesting. Physical Review Letters, 102, 080601. [11] Chen, Z., Guo, B., Xiong, Y., Cheng, C. and Yang, Y. (2016). Melnikov-Method-Based Broadband Mechanism and Necessary Conditions of Nonlinear Rotating Energy Harvesting Using Piezoelectric Beam. Journal of Intelligent Material Systems and Structures, 27: 2555–2567. [12] Cammarano, A., Neild, S. A., Burrow, S. G. and Inman, D. J. (2014). The bandwidth of optimized nonlinear vibration-based energy harvesters. Smart Materials and Structures, 23:055019 [13] Elvin, N. G. and Elvin, A. A. (2012). Large deflection effects in flexible energy harvesters. Journal of Intelligent Material Systems and Structures, 23, 1475-1484. [14] Gao, Y., Leng, Y., Javey, A., Tan, D., Liu, J., Fan, S. and Lai, Z. (2016). Theoretical and Applied Research on Bistable Dual-Piezoelectric-Cantilever Vibration Energy Harvesting toward Realistic Ambience. Smart Materials and Structures, 25: 115032. [15] Leadenham, S. and Erturk, A. (2014). M-Shaped Asymmetric Nonlinear Oscillator for Broadband Vibration Energy Harvesting: Harmonic Balance Analysis and Experimental Validation. Journal of Sound and Vibration, 333, 6209-6223. [16] Al-Ashtari, W., Hunstig, M., Hemsel, T., and Sextro, W. (2013). Enhanced Energy Harvesting Using Multiple Piezoelectric Elements: Theory and Experiments. Sensors and Actuators A, 200:138–146. [17] Castagnetti, D. (2013). A Wideband Fractal-Inspired Piezoelectric Energy Converter: Design, Simulation and Experimental Characterization. Smart Materials and Structures, 22:094024. [18] Ferrari, M., Ferrari, V., Guizzetti, M., Marioli, D., and Taroni, A. (2008). Piezoelectric Multifrequency Energy Converter for Power Harvesting in Autonomous Microsystems. Sensors and Actuators A, 142:329–335. [19] Lumentut, M. F., Francis, L. A., and Howard, I. M. (2012) Analytical Techniques for Broadband Multielectromechanical Piezoelectric Bimorph Beams with Multifrequency Power Harvesting. IEEE Transaction on Ultrasonics, Ferroelectrics, and Frequency Control, 59:2555–2568. [20] Moon, J. W., Jung, H. J., Baek, K. H., Song, D., Kim, S. B., Kim, J. H. and Sung, T. H. (2014). Optimal Design and Application of a Piezoelectric Energy Harvesting System Using Multiple Piezoelectric Modules. Journal of Electroceramics, 32:396–403. [21] Song, H. J., Choi, Y. T., Purekar, A. S., and Wereley, N. M. (2009). Performance Evaluation of Multitier Energy Harvesters Using Macrofiber Composite Patches. Journal of Intelligent Material Systems and Structures, 20:2077–2088. [22] Song, H. J., Choi, Y. T., Purekar, A. S., and Wereley, N. M. (2009). Performance Evaluation of Multitier Energy Harvesters Using Macrofiber Composite Patches. Journal of Intelligent Material Systems and Structures, 20:2077–2088. [23] Wang, W., Huang, R. J., Huang, C. J. and Li, L. F. (2014). Energy Harvester Array Using Piezoelectric Circular Diaphragm for Rail Vibration. Acta Mechanica Sinica, 30:884–888. [24] Xia, H. and Chen, R.(2014) Design and Analysis of a Scalable Harvesting Interface for Multi-Source Piezoelectric Energy Harvesting. Sensors and Actuators A, 218:33–40. [25] Xiao, Z., Yang, T. Q., Dong, Y.and Wang, X. C. (2014). Energy Harvester Array Using Piezoelectric Circular Diaphragm for Broadband Vibration. Applied Physics Letters, 104:223904. [26] Xue, H., Hu, Y. T., and Wang, Q. M. (2008). Broadband Piezoelectric Energy Harvesting Devices Using Multiple Bimorphs with Different Operating Frequencies. IEEE Transaction on UItrasonics Ferroelectrics and Frequency Control, 55:2104–2108. [27] Yang, Z. and Yang, J. (2009). Connected Vibrating Piezoelectric Bimorph Beams as a Wide-Band Piezoelectric Power Harvester. Journal of Intelligent Material Systems and Structures, 20:569–574. [28] Alemany, C., Pardo, L., Jimenez, B., Carmona, F., Mendiola, J. and Gonzalez, A. M. (1994). Automatic Iterative Evaluation of 1 Complex Material Constants in Piezoelectric Ceramics. Journal of Physics D: Applied Physics, 27, 148-155. [29] Shin, D. J. and Koh, J. H. (2017). Comparative Study on Storing Energy for (Ba,Zr)TiO3 and CuO-(Ba,Zr)TiO3 Ceramics for Piezoelectric Energy Harvesting Applications. Ceramics International, 43, S649-S654. [30] Choi, W. J., Jeon, Y., Jeong, J. H., Sood, R. and Kim, S. G. (2006). Energy Harvesting MEMS Device Based on Thin Film Piezoelectric Cantilevers. J Electroceram,17:543-548. [31] Kamel, T. M., Elfrink, R., Renaud, M., Hohlfeld, D., Goedbloed, M., de Nooijer, C., Jambunathan, M. and van Schaijk, R. (2010). Modeling and Characterization of MEMS-Based Piezoelectric Harvesting Devices. Journal of Micromechanics and Microengineering, 20:105023. [32] Lin, S. C. and Wu, W. J. (2013). Piezoelectric micro energy harvesters based on stainless-steel substrates. Smart Materials And Structures, 22: 045016. [33] Majdoub, M. S., Sharma, P., and Cagin, T. (2008). Enhanced Size-Dependent Piezoelectricity and Elasticity in Nanostructures Due To The Flexoelectric Effect, Physical Review B, 77:125424. [34] Janphuang, P., Lockhart, R., Uffer, N., Briand, D. and Rooij, N.F. de(2014). Vibrational piezoelectric energy harvesters based on thinned bulk PZTsheets fabricated at the wafer level. Sensors and Actuators, A 210 : 1–9 [35] Lien, I. C. and Shu, Y. C. (2012) Array of Piezoelectric Energy Harvesting by Equivalent Impedance Approach. Smart Materials and Structures, 21:082001. [36] Lin, H. C., Wu, P. H., Lien, I. C. and Shu, Y. C. (2013). Analysis of an Array of Piezoelectric Energy Harvesters Connected in Series. Smart Materials and Structures, 22:094026. [37] Lefeuvre, E., Badel, A., Richard, C. and Guyomar, D. (2005) Piezoelectric Energy Harvesting Device Optimization by Synchronous Electric Charge Extraction. Journal of Intelligent Material Systems and Structures, 16:865–876. [38] Lefeuvre, E., Badel, A., Richard, C. and Guyomar, D. (2007). Energy Harvesting Using Piezoelectric Materials: Case of Random Vibrations. Journal of Electroceramics, 19:349–355. [39] Lallart, M., Garbuio, L., Petit, L., Richard, C. and Guyomar, D.(2008). Double Synchronized Switch Harvesting (DSSH): A New Energy Harvesting Scheme for Efficient Energy Extraction. IEEE Transaction on Ultrasonics, Ferro- electrics, and Frequency Control, 55:2119–2130. [40] Shen, H., Qiu, J., Ji, H., Zhu, K. and Balsi, M. (2010). Enhanced Synchronized Switch Harvesting: A New Energy Harvesting Scheme for Efficient Energy Extraction. Smart Materials and Structures, 19:115017. [41] Wang, H., Shi, D., and Zheng, S. (2015). Synchronous Charge Extraction and Voltage Inversion (SCEVI): A New Efficient Vibration-Based Energy Harvesting Scheme. Journal of Vibroengineering, 17:1037–1050. [42] Wu, Y., Badel, A., Formosa, F., Liu, W. and Agbossou, A. E. (2013). Piezoelectric Vibration Energy Harvesting by Optimized Synchronous Electric Charge Extraction. Journal of Intelligent Material Systems and Structures, 24:1445–14 58. [43] Wu, Y., Badel, A., Formosa, F., Liu, W. and Agbossou, A. E. (2014). Self-Powered Optimized Synchronous Electric Charge Extraction Circuit for Piezoelectric Energy Harvesting. Journal of Intelligent Material Systems and Structures, 25:2165–2176. [44] Liu, W. Q., Badel, A., Formosa, F., Wu, Y. P. and Agbossou, A. (2013). Wideband Energy Harvesting Using a Combination of an Optimized Synchronous Electric Charge Extraction Circuit and a Bistable Harvester. Smart Materials and Structures, 22:125038. [45] Liu, W., Formosa, F., Badel, A., Wu, Y. and Agbossou, A. (2014). Self-Powered Nonlinear Harvesting Circuit with a Mechanical Switch Structurefor a Bistable Generator with Stoppers. Sensors and Actuators A, 216:106–115. [46] Cammarano, A., Neild, S. A., Burrow, S. G. and Inman D. J. (2014). The Bandwidth of Optimized Nonlinear Vibration-Based Energy Harvesters. Smart Materials and Structures, 23:055019. [47] Cammarano, A., Neild, S. A., Burrow, S. G., Wagg, D. J. and Inman, D. J. (2014). Optimum Resistive Loads for Vibration-Based Electro-magnetic Energy Harvesters with a Stiffening Nonlinearity. Journal of Intelligent Material Systems and Structures, 25:1757–1770. [48] Wu, P. H. and Shu, Y. C. (2015). Wideband Energy Harvesting by Multiple Piezoelectric Oscillators with SECE Interface. ASME Conference on Smart Materials, Adaptive Structures and Intelligent Systems (SMASIS), SMASIS 2015-8862. [49] Y. Yang and L. Tang. Equivalent Circuit Modeling of Piezoelectric Energy Harvesters. Journal of Intelligent Material Systems and Structures, 20:2223–2235, 2009. [50] S.Putter and H.Manor, ‘‘Natural Frequencies of Radial Rotating Beams.’’ Journal of sound and Vibration, 56:175-185, 1978 [51] S. V. Hoa, “Vibration of a Rotating Beam with Tip Mass.” Journal of Sound and Vibration, 67:369-381, 1979. [52] A. Yigit, R. A. Scott, and A. Galip Ulsoy, “Flexural Morion of a Radially Rotating Beam Attached to a Rigid Body.” Journal of Sound and Vibration, 121:201-210, 1988. [53]王偉承，「轉動式週期性磁力應用於壓電振能截取之研究」，台灣大學應用力學研究所碩士論文 [54]趙仁奎，「串並聯混合陣列壓電能量擷取搭配電感並聯同步切換電路之成效比較」，台灣大學應用力學研究所碩士論文 [55]陳彥禎，「混合陣列式壓電振子應用於能量擷取之實驗驗證」，台灣大學應用力學研究所碩士論文 [56] Y. C. Shu and I. C. Lien. “Analysis of Power Output for Piezoelectric Energy Harvesting Systems.” Smart Materials and Structures, 15:1499–1512, 2006. [57] Tang, L. and Yang, Y. (2011). Analysis of Synchronized Charge Extraction for Piezoelectric Energy Harvesting, Smart Materials and Structures 20:085022. [58] Chen, C., Zhao, K. and Liang, J. (2017). Impedance Analysis of Piezoelectric energy Harvesting System using Synchronized Charge Extraction Interface circuit. Active and Passive Smart Structures and Integrated Systems, SPIE Proceedings, 10164: 101642Q. [59]陳世惟，，台灣大學應用力學研究所碩士論文 [60] 謝宇傑，「適用於壓電能量擷取系統的同步電荷擷取整流器與脈衝頻率調變直流降壓轉換器」，台灣大學工程科學及海洋工程學研究所碩士論文 [61] Romani, A., Filippi, M., Dini, M. and Tartagni, M. (2015). A Sub-μA Stand-By Current Synchronous Electric Charge Extractor for Piezoelectric Energy Harvesting. ACM Journal on Emerging Technologies in Computing Systems, 12, 7.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/72198	-
dc.description.abstract	本論文旨在探討同步電荷提取開關的自動切換電路設計，因為過往團隊以外加控制訊號來決定電路開關開啟的時機，然而該方法若應用於陣列架構，會有因必須同時監控多根振子導致無法精確判斷開關開啟時機。故藉由自動切換電路的運行，除可改善外加控制訊號操作困難等問題，並可延伸至非單一弦波週期性振盪狀態的旋轉式磁激振模型實驗，來進行同步電荷提取能量擷取之研究。根據設計，該自動切換電路覆蓋本團隊實驗所需的頻率區間。而實驗結果顯示，由同步電荷提取自動切換電路操控的發電功率與理論預測是相符合的。另外該切換電路對於開關開啟的時間誤差，也低於原先以外加控制訊號操控的誤差，證實了所開發的自動切換電路足以取代傳統由外加控制訊號開啟電路開關的操作方式。	zh_TW
dc.description.abstract	The present thesis is focus on the auto circuit design for controlling the synchronized electric charge extraction (SECE) switch. The conventional approach for the SECE switch control is to use the external signal to monitor it. However, such an approach may not be applied to the case of multiple oscillators due to the difficulty in monitoring the electric response of each oscillator. Thus, the circuit development of switch control can not only resolve such a difficulty but also can be extended to the cases of periodic excitations of multiple signals. This includes the case of implementing an SECE interface circuit to extract energy from rotatory magnetic plucking. Our design shows the working frequency of the proposed circuit covers the resonant frequencies of the cantilever bimorphs used in our laboratory. Next, the measured harvested power output based on the proposed controller circuit agrees quite well with the theoretical predictions. In addition, the error for controlling the switching period is less than that based on the external monitoring, confirming the feasibility of the proposed controller circuit.	en
dc.description.provenance	Made available in DSpace on 2021-06-17T06:28:25Z (GMT). No. of bitstreams: 1 ntu-107-R05543060-1.pdf: 4999472 bytes, checksum: fb73816b2a73de0331429e15311621ae (MD5) Previous issue date: 2018	en
dc.description.tableofcontents	誌謝 i 中文摘要 ii ABSTRACT iii CONTENTS iv 圖目錄 vi 表目錄 viii Chapter 1 導論 1 1.1 研究動機 1 1.2 文獻回顧 2 1.3 論文架構 4 Chapter 2 壓電振子理論 5 2.1 壓電效應 5 2.2 壓電懸臂樑之數學模型 6 2.3 壓電振子等效電路參數 10 2.4 標準直流轉換電路理論-單軸往復 12 2.5 同步電荷提取電路模形與理論-單軸往復 15 2.5.1 SECE理論輸出能量 17 2.5.2 SECE電路損失 19 2.6 轉動式激振模形 23 2.7 同步電荷提取電路套用於轉動磁力激振模形 27 Chapter 3 同步電荷提取開關切換自動化設計 30 3.1 整體電路架構 30 3.2 主體電路 31 3.3 偵測系統 33 3.4 邏輯控制電路 35 3.5 開關驅動電路 37 3.6 工作電壓 39 3.7 實驗設置時注意問題 40 3.7.1 接地穩定性 40 3.7.2 量測探棒相關 41 3.7.3 壓電振子電壓超過工作電壓狀態 42 Chapter 4 同步電荷提取自動電路模擬 43 4.1 同步電荷提取開關切換自動化運行結果 43 4.2 以脈衝電壓源模擬轉動磁力的狀態 46 4.3 放大電壓源以驗證超過工作電壓的狀態 47 4.4 橋式整流器與加入場效電晶體整流器的差異 48 Chapter 5 實驗驗證與分析 49 5.1 實驗流程 49 5.1.1 壓電振子參數量測 49 5.1.2 標準直流轉換電路實驗流程 51 5.1.3 同步電荷提取電路實驗流程 51 5.1.4 轉動式激振實驗流程 55 5.1.5 LABVIEW量測系統 57 5.2 實驗儀器 58 5.3 實驗結果 63 5.3.1 開關自動化電路與訊號產生器控制開關比較 63 5.3.2 垂直模型的開關自動電路的SECE結果與標準直流輸出比較 65 5.3.3 轉動磁力開關自動電路的SECE結果與標準直流輸出比較 73 Chapter 6 結論與未來展望 78 6.1 自動化電路使用效果討論 78 6.2 結論 80 6.3 未來展望 82 Reference……………………………………………………………………………... 83 附錄…………………………………………………………………………………... 89
dc.language.iso	zh-TW
dc.subject	控制電路	zh_TW
dc.subject	壓電振動能量擷取	zh_TW
dc.subject	同步電荷提取介面開關切換	zh_TW
dc.subject	旋轉式磁激振	zh_TW
dc.subject	發電功率	zh_TW
dc.subject	power output	en
dc.subject	controller circuit	en
dc.subject	piezoelectric energy harvesting	en
dc.subject	SECE (synchronized electric charge extraction) switch control	en
dc.subject	rotatory magnetic plucking	en
dc.title	同步電荷提取自動電路設計及其在轉動式壓電振能擷取之應用	zh_TW
dc.title	Application of Synchronized Electric Charge Extraction Circuit to Rotational Piezoelectric Energy Harvesting	en
dc.type	Thesis
dc.date.schoolyear	106-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳瑞琳(Ruey-Lin Chern),謝秉璇(Ping-Hsuan Hsieh)
dc.subject.keyword	控制電路,壓電振動能量擷取,同步電荷提取介面開關切換,旋轉式磁激振,發電功率,	zh_TW
dc.subject.keyword	controller circuit,piezoelectric energy harvesting,SECE (synchronized electric charge extraction) switch control,rotatory magnetic plucking,power output,	en
dc.relation.page	96
dc.identifier.doi	10.6342/NTU201803819
dc.rights.note	有償授權
dc.date.accepted	2018-08-17
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	應用力學研究所	zh_TW
顯示於系所單位：	應用力學研究所

文件中的檔案：

檔案	大小	格式
ntu-107-1.pdf 未授權公開取用	4.88 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。