Abstract
Peak load reduction is one of the most essential obligations and cost-effective tasks for electrical energy consumers. An isolated microgrid (IMG) system is an independent limited capacity power system where the peak shaving application can perform a vital role in the economic operation. This paper presents a comparative analysis of a categorical variable decision tree algorithm (CVDTA) with the most common peak shaving technique, namely, the general capacity addition technique, to evaluate the peak shaving performance for an IMG system. The CVDTA algorithm deals with the hybrid photovoltaic (PV)—battery energy storage system (BESS) to provide the peak shaving service where the capacity addition technique uses a peaking generator to minimize the peak demand. An actual IMG system model is developed in MATLAB/Simulink software to analyze the peak shaving performance. The model consists of four major components such as, PV, BESS, variable load, and gas turbine generator (GTG) dispatch models for the proposed algorithm, where the BESS and PV models are not applicable for the capacity addition technique. Actual variable load data and PV generation data are considered to conduct the simulation case studies which are collected from a real IMG system. The simulation result exhibits the effectiveness of the CVDTA algorithm which can minimize the peak demand better than the capacity addition technique. By ensuring the peak shaving operation and handling the economic generation dispatch, the CVDTA algorithm can ensure more energy savings, fewer system losses, less operation and maintenance (O&M) cost, etc., where the general capacity addition technique is limited.
Highlights
The comparative analysis has been conducted between the categorical variable decision tree algorithm and the conventional capacity addition technique to evaluate the improved performance on peak shaving application of the CVDTA algorithm
This paper presents a comparative analysis of two different peak shaving techniques namely the categorical variable decision tree algorithm (CVDTA) and the general capacity addition technique to find out the appropriate technique for peak shaving application
The CVDTA algorithm can assure the economic operation for an isolated microgrid (IMG) system as it considers the economic generation dispatch operation where the capacity addition technique is limited
Summary
Peak load means the maximum demand in a power system for a certain period. It can occur at any time depending on the required power of the system and can stay for a small proportion of the operating period. Due to the increasing number of electricity consumers, the peak demand is changing continuously for the power system around the world. Balancing the supply and demand during the peak periods is a key challenge for the power provider to ensure uninterrupted power flow [1,2,3]. A grid-connected power system needs to purchase more electricity during the peak periods. The price of electricity during the peak periods is very high with respect to the off-peak periods
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