Improved load frequency control considering dynamic demand regulated power system integrating renewable sources and hybrid energy storage system

Demand response (DR) has emerged as a key component of the future electric power system's reliability and frequency stability. This study explores the effect of DR regulation and hybrid energy storage (HES) on an identical two-area test power system that comprises of solar photovoltaic, wind turbine, biogas unit, and a thermal power plant for improved frequency regulation services. By including intrinsic communication latency in the DR loop, a generalised load frequency control (LFC) model of a hybrid hierarchical DR mechanism is developed. The stability of the analysed system before and after DR is compared in terms of stability margin. A Quasi- oppositional Harris Hawks Optimization (QOHHO) is suggested to optimize the coefficients of the proposed cascade fractional order two-degree-of-freedom CC[FO(TDOF)] controller. The supremacy of the proposed algorithm is affirmed by comparing its figure of demerit with different existing algorithms. The investigations also manifest the efficacy of proposed controller over proportional integral derivative with filter (PID) and two degree of freedom (tilt integral derivative with filter) [TDOF (TID)] controllers. QOHHO optimized designed controller performance is also evaluated for the studied system under random load disturbances. Furthermore, the suggested technique's practical feasibility is verified through experimental validation using OPAL-RT based real-time analysis.