A Numerical Investigation the Effects of the Voltage on the Displacement and Stress of Copper-based Ionic Polymer-Metal Composites
Subject Areas :
Hamid Soleimanimehr
1
,
Amin Nasrollah
2
1 - Assistant Professor of Mechanical Engineering, Department of mechanical engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
2 - Bsc. of Mechanical Engineering, Department of Mechanical Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
Keywords:
Abstract :
[1] Yang, L., Zhang, D., Zhang, X., Tian, A. and Wang, X. 2020. Models of displacement and blocking force of ionic-polymer metal composites based on actuation mechanism. Applied Physics A. 126(5): 126-365.
[2] Kinji, A., Naoya, M., Kohtaku, H., Yoshihiro, N., Toshiharu, M. and Zhi-Wei, L. 2004. Modeling of the electromechanical response of ionic polymer metal composites (ipmc). Proc.SPIE. 5385(1): 172-181.
[3] Soleimanimehr, H. 2021. Analysis of the cutting ratio and investigating its influence on the workpiece’s diametrical error in ultrasonic-vibration assisted turning. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture. 235(4): 640-649.
[4] Wang, J., Wang, Y., Zhu, Z., Wang, J., He, Q. and Luo, M. 2019. The effects of dimensions on the deformation sensing performance of ionic polymer-metal composites. Sensors. 19(9): 1-12.
[5] Nasrollah, A., Soleimanimehr, H. and Javangoroh, S. 2021. Finite element analysis assisted improvement of ionic polymer metal composite efficiency for micropump of 3d bioprinter. Advanced Journal of Science and Engineering. 2(1): 23-30.
[6] Nguyen, T.T., Goo, N.S., Nguyen, V.K., Yoo, Y. and Park, S. 2008. Design, fabrication, and experimental characterization of a flap valve ipmc micropump with a flexibly supported diaphragm. Sensors and Actuators A: Physical. 141(2): 640-648.
[7] Vokoun, D., He, Q., Heller, L., Yu, M. and Dai, Z. 2015. Modeling of ipmc cantilever's displacements and blocking forces. Journal of Bionic Engineering. 12(1): 142-151.
[8] Makinouchi, T., Tanaka, M. and Kawakami, H. 2017. Improvement in characteristics of a nafion membrane by proton conductive nanofibers for fuel cell applications. Journal of Membrane Science. 530(1): 65-72.
[9] Wang, F., Jin, Z., Zheng, S., Li, H., Cho, S., Kim, H.J., Kim, S. J., Choi, E., Park, J.-O. and Park, S. 2017. High-fidelity bioelectronic muscular actuator based on porous carboxylate bacterial cellulose membrane. Sensors and Actuators B: Chemical. 250(1): 402-411.
[10] MohdIsa, W., Hunt, A. and HosseinNia, S.H. 2019. Sensing and self-sensing actuation methods for ionic polymer-metal composite (ipmc): A review. Sensors (Basel). 19(18): 3967-4003.
[11] Lee, S.G., Park, H., Pandita, S. and Yoo, Y. 2006. Performance improvement of ipmc (ionic polymer metal composites) for a flapping actuator. International Journal of Control Automation and Systems. 4(6): 748-755.
[12] Nasrollah, A., Soleimanimehr, H. and Khazeni, H. 2021. Nafion-based ionic-polymer-metal composites: Displacement rate analysis by changing electrode properties. Advanced Journal of Science and Engineering. 2(1): 51-58.
[13] COMSOL. 2021. Mems module user’s guide, creating and analyzing mems models: The electromechanics interface. ed.
[14] COMSOL. 2021. Mems module user’s guide, the electrostatics interface: Charge conservation. ed.
[15] Sakthi Swarrup, J. and Ranjan, G. 2015. Effect of mass loading on ionic polymer metal composite actuators and sensors. Proc.SPIE. 9430: 1-18.
[16] Nasrollah, A. and Soleimanimehr, H. 2021. Electromechanical analysis on elasticity modulus of ionic-polymer-metal composites with platinum-based electrode and its comparison with experimental results. The 6th International and 17th National Conference on Manufacturing Engineering (ICME).
