Authors:
B. Karthikeyan,K. S.Yamuna,K. Padmapriya,S. Priyadharsini,K. Sabareeshwari,P. Sree Mathi,DOI NO:
https://doi.org/10.26782/jmcms.2025.05.00006Keywords:
EMS,Energy flexibility,Island operation,Power optimization,Real-time power management,Sustainable energy,Vehicle batteries,Abstract
The paper specializes in developing a real-time power management device (EMS) to ensure resilient power distribution for medical institution operations by integrating renewable energy sources, vehicle batteries, and stationary energy storage systems. The EMS is designed to seamless transition between regular grid operation and outages with a specific consciousness on prioritizing strength supply to crucial infrastructure at some stage in grid downtimes by way of switching to island operation by utilizing strength saved in automobile batteries and sustainable sources like solar panels and wind turbines (Quiet Revolution QR5 – less noise level, compact and more efficient for sensitive environment). The gadget ensures uninterrupted energy for critical systems which includes the Intensive Care Unit and emergency gadget whilst deprioritizing non-vital loads to optimize aid allocation. Advanced manage algorithms dynamically manage power flows ensuring effective operation even in the face of renewable power variability. With real-time tracking and smart load management, this gadget enhances the resilience and sustainability of strength networks, imparting a reliable and eco-conscious solution for crucial medical institution infrastructure for the duration of outages.Refference:
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