A hybrid data-driven Co-simulation approach for enhanced integrations of renewables and thermal storage in building district energy systems
Youssef Elomari, Giorgos Aspetakis, Carles Mateu, Adedamola Shobo, Dieter Boer, Marc Marín-Genescà, Qian Wang
Abstract
Increasing the share of renewables is crucial for accelerating the sustainable transitions of modern building and district heating systems. This study develops a hybrid co-simulation framework, integrating a Python-based model with an established district energy system (DES) TRNSYS model, to optimize the design and control of on-site renewables such as photovoltaic panels (PV), solar thermal collectors, a water-to-water heat pump, seasonal thermal storage, a domestic hot water tank, and auxiliary heaters. The methodology combines diverse simulation tools and data-driven control sequences, enabling interaction across system components for enhanced energy efficiency and performance. The findings indicate that the optimized framework reduces net present cost by approximately 14 % and environmental impacts by 11 %. The data-driven controls further minimized temperature deviations significantly better than traditional Rule-Based Controls, achieving nearly optimal comfort levels with minimal environmental impact. The developed co-simulation enhances energy efficiency and intelligent controls in building applications, minimizes environmental impacts, and effectively covers the energy demand in building and districts (building clusters). These findings highlight the essential role of advanced hybrid co-simulation frameworks in improving DH system design and control, emphasizing their potential for sustainable urban energy transitions. • Developed TRNSYS-Python co-simulation for district energy system optimization. • Applied multi-objective optimization to minimize costs and environmental impact. • Applied Data-Driven and Rule-Based Control for optimal energy system performance. • Compared technical, environmental, and economic impacts of control strategies.