IJE TRANSACTIONS B: Applications Vol. 31, No. 5 (May 2018) 734-740    Article in Press

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R. Zhao
( Received: August 27, 2016 – Accepted in Revised Form: February 14, 2018 )

Abstract    This paper presents a magnetostrictive in-pipe impact drive mechanism (IDM). To estimate the output performances of the IDM, a dynamics model was developed based on the magnetostrictive material constitutive model and mechanical model of the IDM. Therefore, an experimental system has been built to test the motion performance of IDM. Simulation and experimental results illustrate that the proposed model can accurately predict the step-size of the IDM. The working frequency of the designed IDM is from 10 to 120 Hz, with a the step-size resolution of 740 nm. The magnetostrictive IDM performs good linearity, and can be applied to precision positioning.


Keywords    In-pipe Motor; Impact Drive Mechanism; Magnetostritive Materials; Impact Inertia Principle; Precision Positioning 


چکیده    این مقاله مکانیزم تاثیر مگنتواستراکتیو لوله ها را ارائه میدهد. جهت تخمین کارائی مدل دینامیکی براساس موادمگنتواستراکتیو نوسعه یابد. لذا سیستم تجربی بر پایه آزمایش ها ساخته شد تا کارایی حرکت دینامیکی مورد آزمایش قرار گیرد. نتایج تجربی و سیمیوله شده نشان میدهد که مدل بطور دقیق می تواند با اندازه ایکرومنت پیش گویی نماید. تکرار پدیری از 10 الی 120 هتز و با اندازه اینکرومنت 740 نانومتر قابل اجراست. کارایی الگو مگنتواستراکتیو بصورت خطی با دقت بالا مورد قبول می باشد.


1.     Belly, C., Claeyssen, F., Le Letty, R. and Porchez, T., "Benefits from amplification of piezo actuation in inertial stepping motors and application for high-performance linear micro motors Proceeding of Actuator, Vol. 1, (2010),1-4.

2.     Zesch, W., Buechi, R., Codourey, A. and Siegwart, R.Y., "Inertial drives for micro-and nanorobots: Two novel mechanisms", in Microrobotics and Micromechanical Systems, International Society for Optics and Photonics. Vol. 2593, (1995), 80-89.

3.     Cheshmehbeigi, H.M. and Khanmohamadian, A., "Design and simulation of a moving-magnet-type linear synchronous motor for electromagnetic launch system", International Journal of Engineering-Transactions C: Aspects,  Vol. 30, No. 3, (2017), 1183-1188.

4.     Kurosawa, M. and Ueha, S., "Hybrid transducer type ultrasonic motor", IEEE transactions on ultrasonics, ferroelectrics, and frequency control,  Vol. 38, No. 2, (1991), 89-92.

5.     Sayyaadi, H. and Zakerzadeh, M., "Nonlinear analysis of a flexible beam actuated by a couple of active sma wire actuators",  International Journal of Engineering, Transactions A: Basics, Vol.25, No. 3, (2012), 249-264.

6.     Nosier, A. and ROUHI, M., "Three dimensional analysis of laminated cylindrical panels with piezoelectric layers",  International Journal of Engineering, Transactions B: Applications, Vol.19, No.1, (2006), 61-72.

7.     Yuan, M., "Compact and efficient active vibro-acoustic control of a smart plate structure", International Journal of Engineering, Transactions B: Applications,  Vol. 29, No. 8, (2006), 1068-1074.

8.     Edeler, C., Meyer, I. and Fatikow, S., "Modeling of stick-slip micro-drives", Journal of Micro-Nano Mechatronics,  Vol. 6, No. 3-4, (2011), 65-87.

9.     Hattori, S., Hara, M., Nabae, H., Hwang, D. and Higuchi, T., "Design of an impact drive actuator using a shape memory alloy wire", Sensors and Actuators A: Physical,  Vol. 219, (2014), 47-57.

10.   Ueno, T. and Higuchi, T., "Miniature magnetostrictive linear actuator based on smooth impact drive mechanism", International Journal of Applied Electromagnetics and Mechanics,  Vol. 28, No. 1, 2, (2008), 135-141.

11.   Okamoto, Y., "The development of a smooth impact drive mechanism (sidm) using a piezoelectric element", Konica Minolta Technol. Rep.,  Vol. 1, (2004), 23-26.

12.   Eigoli, A.K. and Vossoughi, G., "Dynamic modeling of stick-slip motion in a legged, piezoelectric driven microrobot", International Journal of Advanced Robotic Systems,  Vol. 7, No. 3, (2010), 201-208.

13.   Zhou, J.J., Pan, Y.L. and Huang, M., "A novel magnetostrictive drive rotary motor", in Solid State Phenomena, Trans Tech Publ. Vol. 121, (2007), 1203-1206.

14.   Kim, W.-j. and Sadighi, A., "A novel low-power linear magnetostrictive actuator with local three-phase excitation", IEEE/ASME Transactions on Mechatronics,  Vol. 15, No. 2, (2010), 299-307.

15.   Zhang, Z.G., Ueno, T. and Higuchi, T., "Magnetostrictive actuating device utilizing impact forces coupled with friction forces", in Industrial Electronics (ISIE), 2010 IEEE International Symposium on, IEEE., (2010), 464-469.

16.   Yang, C.-F., Jeng, S.-L. and Chieng, W.-H., "Motion behavior of triangular waveform excitation input in an operating impact drive mechanism", Sensors and Actuators A: Physical,  Vol. 166, No. 1, (2011), 66-77.

17.   Engdahl, G. and Mayergoyz, I., "Handbook of giant magnetostrictive materials (academic, new york, 2000)", Google Scholar,  209-217.

18.   Zheng, X. and Liu, X., "A nonlinear constitutive model for terfenol-d rods", Journal of applied physics,  Vol. 97, No. 5, (2005), 1-8.

19.   Kang, C.-Y., Yoo, K.-H., Ko, H.-P., Kim, H.-J., Ko, T.-K. and Yoon, S.-J., "Analysis of driving mechanism for tiny piezoelectric linear motor", Journal of electroceramics,  Vol. 17, No. 2-4, (2006), 609-612.

20.   Liu, Y., Li, J., Hu, X., Zhang, Z., Cheng, L., Lin, Y. and Zhang, W., "Modeling and control of piezoelectric inertia–friction actuators: Review and future research directions", Mechanical Sciences,  Vol. 6, No. 2, (2015), 95-107.

21.   Fung, R.-F., Han, C.-F. and Ha, J.-L., "Dynamic responses of the impact drive mechanism modeled by the distributed parameter system", Applied Mathematical Modelling,  Vol. 32, No. 9, (2008), 1734-1743.

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