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Optimizing the Size of Autonomous Hybrid Microgrids with Regard to Load Shifting

Alexander Lavrik, Y L Zhukovskiy, Pavel Tcvetkov

2021Energies35 citationsDOIOpen Access PDF

Abstract

The article proposes a method of multipurpose optimization of the size of an autonomous hybrid energy system consisting of photovoltaic, wind, diesel, and battery energy storage systems, and including a load-shifting system. The classical iterative Gauss–Seidel method was applied to optimize the size of a hybrid energy system in a remote settlement on Sakhalin Island. As a result of the optimization according to the minimum net present value criterion, several optimal configurations corresponding to different component combinations were obtained. Several optimal configurations were also found, subject to a payback period constraint of 5, 6, and 7 years. Optimizing the size of the hybrid power system with electric load shifting showed that the share of the load not covered by renewable energy sources decreases by 1.25% and 2.1%, depending on the parameters of the load shifting model. Net present cost and payback period also decreased, other technical and economic indicators improved; however, CO2 emissions increased due to the reduction in the energy storage system.

Topics & Concepts

Payback periodRenewable energyPhotovoltaic systemHybrid systemEnergy storageAutomotive engineeringComputer scienceWind powerMathematical optimizationEnvironmental sciencePower (physics)EngineeringElectrical engineeringMathematicsQuantum mechanicsMacroeconomicsMachine learningEconomicsProduction (economics)PhysicsHybrid Renewable Energy SystemsIntegrated Energy Systems OptimizationElectric Power Systems and Control
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