Abstract
The prognostics and health management (PHM) plays the main role to handle the risk of failure before its occurrence. Next, it has a broad spectrum of applications including utility networks, energy storage systems (ESS), etc. However, an accurate capacity estimation of batteries in ESS is mandatory for their safe operations and decision making policy. ESS comprises of different storage mechanisms such as batteries, capacitors, etc. Consequently, the measurement of different charging profiles (CPs) has a strong relation to battery capacity. These profiles include temperature (T), voltage (V), and current (I) where the CPs patterns vary as the battery ages with cycles. Consequently, estimating a battery capacity, the conventional methods practice single channel charging profile (SCCP) and hop multiple channel CPs (MCCPs) that cause incorrect battery health estimation. To tackle these issues, this article proposes MCCPs based battery management system (BMS) to estimate batteries health/capacity through the deep learning (DL) concept where the patterns in these CPs are changed as the battery ages with time and cycles. Thus, we deeply investigate both machine learning (ML) and DL based methods to provide a concrete comparative analysis of our method. The adaptive boosting (AB) and support vector regression (SVR) are widely compared with long short-term memory (LSTM), multi-layer perceptron (MLP), bi-directional LSTM (BiLSTM), and convolutional neural network (CNN) to attain the appropriate approach for battery capacity and state of health (SOH) estimation. These approaches have a high learning capability of inter-relation between the battery capacity and variation in CPs patterns. To validate and verify the proposed technique, we use NASA battery dataset and experimentally prove that BiLSTM outperforms all the approaches and obtains the smallest error values for MAE, MSE, RMSE, and MAPE using MCCPs compared to SCCP.
Highlights
Renewable energy sources (RES) are important for continuous energy supply through modern smart grids
EXPERIMENTAL RESULTS we discuss the experiments obtained for battery capacity estimation, the system configuration, data acquisition, and results comparison of machine learning (ML) and deep learning (DL) based approaches for single channel charging profile (SCCP) and multiple channel charging profiles (MCCPs) in detail
A desirable way to lengthen the lifetime of a battery is the consideration of batteries capacity degradation that is needed for safety purposes
Summary
Renewable energy sources (RES) are important for continuous energy supply through modern smart grids. Many problems and challenges are arisen for the operators in the smart grids such as increase in the frequency variation, reduction in the transient voltage (V) and reliability, and decrease in power quality due the enlarged penetration of unreliable and unbalanced RES [1]. These issues can be handled through separating energy demands from energy generation with the help of efficient energy storage systems (ESS) approach. In order to balance the energy demand and its supply, BESS uses frequency reaction facilities, loop of peak power, and support for voltage. Several mechanisms in batteries all over the world are settled to support the modern grid
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