Enhanced Sizing Methodology for the Renewable Energy Sources and the Battery Storage System in a Nearly Zero Energy Building

The aim of this article is to present a novel methodology to determine the correct size of the renewable energy sources (RES) and the battery storage system (BSS) that are needed to effectively convert a conventional residential building into a nearly zero-energy building (nZEB). This is attained by properly considering the long-term history of the weather at the location of the building, the energy consumption of the appliances and the performance of the energy management system (EMS). The above are embedded in a cost function that balances the impact factors which highly affect the size and have considerable effect on the reliability and lifespan of the RES and BSS in a nZEB, i.e., the depreciation of the initial investment, the self-consumption rate, the feed-in rate, the simultaneity in generating and consuming power, and the impacts of the depth-of-discharge and the discharge power on the BSS's state-of-health. Therefore, the correct sizing of RES and BSS is provided by considering both the effectiveness and the economic point of views. Specifically, the optimal solution is attained by minimizing the above cost function through the genetic algorithm technique. The effectiveness, functionality and practicality of the proposed methodology have been validated on a pilot nZEB.

Automated summary

This article introduces a novel methodology to determine the correct size of RES and BSS for converting a conventional residential building into an nZEB, considering factors such as weather history, energy consumption, and EMS performance. By balancing various impact factors, the methodology offers a correct sizing approach by considering both effectiveness and economic perspectives. The validation on a pilot nZEB shows the effectiveness, functionality, and practicality of the proposed methodology.