PEM Fuel Cell Powered Electric Vehicle Propelled by PMSM Using Fuzzy PID Controller- A Research
How to Cite?
Uma Ravi Sankar Yalavarthy, Venkata Siva Krishna Rao Gadi, "PEM Fuel Cell Powered Electric Vehicle Propelled by PMSM Using Fuzzy PID Controller- A Research," International Journal of Engineering Trends and Technology, vol. 70, no. 3, pp. 66-74, 2022. Crossref, https://doi.org/10.14445/22315381/IJETT-V70I1P208
Fuel cells are becoming quite popular these days due to their benefits, such as simplicity, reliability, low pollution, and noiselessness. Despite the numerous flaws in the advancement of fuel cell-based electric vehicles (EV), the objective is to test the accomplishment of Fuzzy PID controlled Permanent magnet synchronous motor (PMSM) propelled electric vehicle powered by proton exchange membrane (PEM) fuel cell in terms of control design and motor drive mechanism. In this paper, the dynamics of electric vehicles are considered, and space vector pulse width modulation (SVPWM) converter control methodology is employed. This research provides a Fuzzy PID controllerbased control approach for different motor-loaded conditions, and it is compared with a classical PID controller. The system is modeled and simulated in Matlab/Simulink environment. The control strategy was found to be effective based on the outcomes. The findings confirm that the PEM fuel cell electric vehicle`s control technique is effective and efficient throughout a vast speed range.
electric Vehicle (EV), permanent magnet synchronous motor (PMSM), Proton exchange membrane (PEM), space vector pulse width modulation (SVPWM).
 Vinay. K. M and Isaac Raju, Hybrid Electric Vehicles, International Journal of Engineering Trends and Technology (IJETT), 50(2) (2017) 93-95.
 Khaled S. AlQdah, Analysis of the Causes of Hybrid Cars` Rarity in Saudi Arabia. Medina as a Case study, International Journal of Engineering Trends and Technology (IJETT), 68(8) (2020) 62-67.
 Chan. C. C, An overview of electric vehicle technology, Proceedings of the IEEE, 81(9) (1993) 1202-1213.
 Williams. M. C, Strakey. J. P and Surdoval. W. A, The US department of energy, office of fossil energy stationary fuel cell program, Journal of power sources, 143(1-2) (2005) 191-196.
 Gao. L, Dougal. R. A and Liu. S, Active power-sharing in hybrid battery/capacitor power sources, In Eighteenth Annual IEEE Applied Power Electronics Conference and Exposition, 2003, APEC`03, 1 (2003) 497-503. IEEE.
 Kim. M. J, Peng. H, Lin. C. C, Stamos. E and Tran. D, Testing, modeling, and control of a fuel cell hybrid vehicle, In Proceedings of 2005, American Control Conference, (2005) 3859-3864. IEEE.
 Schofield. N, Yap. H. T and Bingham. C. M, Hybrid energy sources for electric and fuel cell vehicle propulsion, In 2005 IEEE Vehicle Power and Propulsion Conference, (2005) 522-529. IEEE.
 Rodríguez. C, M. B, Paleta. M. A. R, Marquez. J. A. R, Pachuca. B. A and de la Vega. J. R. G. Effect of a Rigid Gas Diffusion Media Applied as Distributor of Reagents in a PEMFC in Operation, Part I: Dry Gases, In Int. J. Electrochem. Sci, 4 (2009) 1754-1769.
 Yu. X, Zhou. B and Sobiesiak. A Water and thermal management for Ballard PEM fuel cell stack, Journal of Power sources, 147(1-2) (2005) 184-195.
 Lin. R, Weng. Y, Lin. X and Xiong. F, Rapid cold start of proton exchange membrane fuel cells by the printed circuit board technology, International journal of hydrogen energy, 39(32) (2014) 18369-18378.
 Ettihir. K, Boulon. L, Becher. M, Agbossou. K and Ramadan. H. S, Online identification of semi-empirical model parameters for PEMFCs, International journal of hydrogen energy, 39(36) (2014) 21165-21176.
 Yu. Y, Li. H, Wang. H, Yuan. X. Z, Wang. G and Pan. M. U, A review on performance degradation of proton exchange membrane fuel cells during startup and shutdown processes: Causes, consequences, and mitigation strategies, Journal of Power Sources, 205 (2012) 10-23.
 Chen. M and Rincon-Mora. G. A, Accurate electrical battery model capable of predicting runtime and IV performance, IEEE transactions on energy conversion, 21(2) (2006) 504-511.
 Poushali Pal, Devabalaji K. R and S. Priyadarshini, Design of Battery management system for Residential applications, International Journal of Engineering Trends and Technology (IJETT), 68(3) (2020) 12-17.
 Dai. Y, Song. L and Cui. S, Development of PMSM drives for hybrid electric car applications, IEEE transactions on magnetics, 43(1) (2006) 434-437.
 Pranoti. G and A. A. Bhole, Integrated Starter Alternator using PMSM, International Journal of Engineering Trends and Technology (IJETT), 62(2) (2019) 113-117.
 Chin. Y. K and Soulard. J, A permanent magnet synchronous motor for traction applications of electric vehicles, In IEEE International Electric Machines and Drives Conference, 2003, IEMDC`03.2, (2003) 1035-1041. IEEE.
 Bose. B. K, Modern power electronics and AC drives, Upper Saddle River, NJ: Prentice hall. 123 (2002).  Krishnan. R, Permanent magnet synchronous and brushless DC motor drives, CRC press. (2017).
 Temitayo O. Olowu, Funso K. Ariyo and Moses O. Onibonoje, Performance Analysis of Direct Torque Controlled, Inverter-fed PMSM Drive for Wire Drawing Machines, International Journal of Engineering Trends and Technology (IJETT), 55(1) (2018) 8-15.
 Mohan. N, Advanced electric drives: analysis, control, and modeling using MATLAB/Simulink. John wiley & sons. (2014).
 K. Mounika and B. Kiran Babu, Sinusoidal and Space Vector Pulse Width Modulation for Inverter, International Journal of Engineering Trends and Technology (IJETT), 4(4) (2013) 1012-1017.
 Swagata Banerjee and Biswamoy Pal, Two Level Inverter Based on Space Vector Pulse Width Modulation Technique, International Journal of Engineering Trends and Technology (IJETT), 22(6) (2015) 265-269.
 Wang. S, Shi. Y and Feng. Z, Research on control method based on fuzzy PID controller [J], Mechanical Science and Technology, 30(1) (2011) 166-172.
 ZHANG Tao ZHANG Xiao-jiang. L. U and Yu-long. W. L. Y, Research of PMSM Vector Control System Based on Fuzzy Selftuning PID, Microcomputer Information, 10 (2012).
 Liu. J, Advanced PID control and MATLAB simulation, Beijing: Publishing House of electronics industry, 9 (2004).
 Thounthong. P, Raël. S and Davat. B, Control strategy of fuel cell/supercapacitors hybrid power sources for electric vehicle. Journal of Power Sources, 158(1) (2006) 806-814.
 Lukic. S. M, Cao. J, Bansal. R. C, Rodriguez. F and Emadi. A, Energy storage systems for automotive applications. IEEE Transactions on industrial electronics, 55(6) (2008) 2258-2267.
 Hilairet. M, Ghanes. M, Béthoux. O, Tanasa. V, Barbot. J. P and Normand-Cyrot. D, A passivity-based controller for coordination of converters in a fuel cell system. Control engineering practice, 21(8) (2013) 1097-1109.
 Tremblay. O and Dessaint. L. A, A generic fuel cell model for the simulation of fuel cell vehicles, In 2009 IEEE vehicle power and propulsion conference, (2009) 1722-1729. IEEE.
 Larminie. J, Dicks. A and McDonald. M. S, Fuel cell systems explained, Chichester, UK: J. Wiley. 2 (2003) 207-225.
 Dicks. A. L and Rand. D. A, Fuel cell systems explained. John Wiley & Sons. (2018).
 Mohan. N, Undeland. T. M and Robbins. W. P, Power electronics: converters, applications, and design. John wiley & sons. (2003).
 Lenin. S, Elsa. A, Paola. Q and Henry. A, Design, Construction and Research of an Electric Unicycle with Rechargeable Flow Batteries, International Journal of Engineering Trends and Technology (IJETT), 58(1) (2018) 41-45.
 Gharibeh. H. F, Yazdankhah. A. S, Azizian. M. R and Farrokhifar. M, Online Energy Management Strategy for Fuel Cell Hybrid Electric Vehicles with Installed PV on Roof, IEEE Transactions on Industry Applications, 57(3) (2021) 2859-2869.
 Nkolika O. Nwazor and Joe Samuel Otonye, Economic Feasibility Analysis of Lithium Ion Batteries for Direct Current Power Supply in Refineries, International Journal of Engineering Trends and Technology (IJETT), 67(3) (2019) 37-43.