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Research Article |

A Fractional Order Tilt Integral Controller Based Load Frequency Control with Dispersed Generation and Electric Vehicle

Author(s): T. Dinesh1* and M. Manjula2

Published In : International Journal of Electrical and Electronics Research (IJEER)        Volume 11, Issue 2

Publisher : FOREX Publication

Published : 15 June 2023

e-ISSN : 2347-470X

Page(s) : 401-411

DOI: https://doi.org/10.37391/IJEER.110221

Abstract

The elevated level of entrance of decentralized power sources with their Intermittent and volatility gives us a accost task to control load frequency, moreover this quandary is getting worsen up with the Involvement of electric vehicles in the rundown. This paper presents a censorious robust fractional order operative established tilt integral derivative controller (FOTID) for regulating the frequency. To emulate distributed power sources a linearized model of a wind power plant is considered and a small signal model of EV is developed. With the consideration dynamic nature of EV & wind power plants, the dynamic pursuance of the envisaged FOTID controller is investigated by comparing them with integral order PID controller, Fractional order PID controller, sliding mode controller under various conditions. The transfer function model of proposed controllers is derived and the robustness of the proposed FOTID controller is examined by conducting detailed simulation studies.

Keywords: Load frequency control, Multi area power systems, FOC (Fractional order control), IOC (Integral order control), TID (Tilt angle Derivative), EV (Electric Vehicle), TPP (Thermal Power plant), SMC (Sliding Mode Control).




T. Dinesh*, Department of Electrical Engineering, Osmania University, Hyderabad, Telangana, India; Email: dinuferrari03@gmail.com

M. Manjula, Department of Electrical Engineering, Osmania University, Hyderabad, Telangana, India; Email: manjulagooga@gmail.com

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T. Dinesh and M. Manjula (2023), A Fractional Order Tilt Integral Controller Based Load Frequency Control with Dispersed Generation and Electric Vehicle. IJEER 11(2), 401-411. DOI: 10.37391/IJEER.110221.