Battery management in IoT hybrid grid system using deep learning algorithms based on crowd sensing and micro climatic data
Srinivasan Rajamani, Arulmozhiyal Ramasamy

TL;DR
This paper proposes an IoT-enabled hybrid grid system using deep learning to manage batteries and reduce grid dependency by leveraging microclimatic data and crowd sensing.
Contribution
The novel contribution is the integration of hybrid deep learning algorithms with crowd sensing and microclimatic data for improved battery management in hybrid grid systems.
Findings
IPWS with JO-LSTM/HBO-LSTM based BMS reduces output power fluctuations and improves transient stability and damping ratio.
The system achieves a 29% improved power factor and reduces harmonics by 14%.
Comparative analysis shows the effectiveness of the proposed methods in managing DC-link and super-capacitor performance.
Abstract
Hybrid Grid System (HGS) installation in small and large residential area has major challenges due to domestic loads. Domestic loads are in different duty cycle such as (i) continuous duty i.e., vehicle charging, (ii) short time duty, (iii) periodic duty and (iv) intermittent duty. In this paper, proposed HGS comprises of Internet of Thing (IOT), Photovoltaic (PV) system and wind system (PWS) with Lithium-Phosphate battery paralleled with Super-capacitor, Deep learning controller with PWS is termed as IOT enabled PWS (IPWS). IPWS has zero export converters, reduces electricity demand on grid. Zero-export inverter avoids excess energy to grid and excess energy stored in super-capacitor. IPWS has crowd sensing for microclimatic conditions data acquisition system. Microclimatic Data is used for tuning zero export converters and Battery Management System (BMS) through IPWS. IPWS controller…
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Taxonomy
TopicsSmart Grid Energy Management · Electric Vehicles and Infrastructure · Advanced Battery Technologies Research
