A Numerical Investigation the Effects of the Voltage on the Displacement and Stress of Copper-based Ionic Polymer-Metal Composites
محورهای موضوعی : MEMS/NEMSHamid 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
کلید واژه: displacement, Finite Element Method, MEMS, voltage, smart material, Ionic-polymer-metal Composites,
چکیده مقاله :
Ionic polymer material composites (IPMCs) are a group of polymeric material which deform by applying voltage and the movement of cations of polymer; it should be mentioned that the finite element method using electromechanics equations can be used to analyze these types of problem and measure the deformation. This phenomenon can causes bending and internal stress. This research, it is tried to investigate the displacement and stress of IPMC by modeling and finite element method analysis. Firstly, a 2D IPMC is designed; then the materials are applied which are cooper for the electrodes and Nafion for the polymeric core. After applying boundary conditions and meshing, the results have been analyzed by the finite element method. It is found that the relation between voltage and its effect on the bending displacement of IPMC is direct. The conclusions include the maximum displacement of IPMC membrane under the voltage of 5V is 0.42 mm and the maximum Von Mises stress on the electrode is gained 3.29×1016 (N/m2).
[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).