1. KHALID RAHMAN - PhD Electrical, CECOS University of IT & Emerging Sciences, Department of Electrical Engineering,
CECOS University of Information Technology & Emerging Sciences, Peshawar, Pakistan.
2. MUHAMMAD MUDASSIR SHAH - MS Electrical, CECOS University of IT & Emerging Sciences, Department of Electrical Engineering, CECOS
University of Information Technology & Emerging Sciences, Peshawar, Pakistan.
3. ENGR. SANA - Department of Electrical Engineering, University of Engineering and Technology, Peshawar, Pakistan.
4. JAN SHER KHAN - MS Electrical, CECOS University of IT & Emerging Sciences, Department of Electrical Engineering, CECOS
University of Information Technology & Emerging Sciences, Peshawar, Pakistan.
5. JUNAID MIRAJ - MS Electrical, CECOS University of IT & Emerging Sciences, Department of Electrical Engineering, CECOS
University of Information Technology & Emerging Sciences, Peshawar, Pakistan.
This research presents a multi-criteria evaluation technique for a sustainable mechanical arrangement that incorporates renewable sources. It investigates the most compelling methods to use the combined control of solar, hydro, and wind power to solve the difficulties of flexible, viable, and tried and true energy capacity. Scientific reenactments with cross-breed arrangements are created using a variety of constraints and working standards. An electrical development framework based mostly on wind and solar technologies, as well as pumped-storage hydropower plans, is drawn out in order to determine how much renewable energy and capacity are necessary to satisfy renewables-only era goals. The proposed strategy in the current study blends pumped hydro capacity innovation with a cross-breed sun-based wind turbine framework (a renewable vitality source) to alleviate vitality shortages while safeguarding network stability. Solar and wind power are inherently unpredictable and untrustworthy sources of energy. As a result, they cannot guarantee the critical stack request. However, by integrating these two renewable assets (photovoltaics and wind turbines) into a pumped hydro capacity framework, the effects of variability in solar and wind assets can be mitigated, and the overall framework can be made more predictable and financially feasible to operate. According to the analysis, the most realistic strategy to achieving this goal is to mix pumped hydropower with solar and wind energy. The findings indicate that, in terms of common sense and consistency, pumped hydro capacity combined with solar and wind energy is the best configuration for achieving energy independence.
Pumped Hydro Storage System (PHSS), Wind Turbine Model, PV Model, Hybrid HydroWind-Solar Solutions (HHWSS), New Power Generation, Hydro Generators, Technical Feasibility.