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Flexibility-centric sizing and optimal operation of building-thermal energy storage systems: A systematic modelling, optimization and validation approach

Yangzhe Chen, Thomas Ohlson Timoudas, Qian Wang

2025Energy and Buildings5 citationsDOIOpen Access PDF

Abstract

• An optimization-based method for sizing and operation of thermal energy storage is proposed. • The proposed method is validated across multiple building types and climates, achieving up to 35 % cost reduction. • The sizing Framework significantly enhances energy flexibility, with flexibility factor increased by up to 1.03. The increasing integration of renewable energy sources (RES) and the transition towards a decarbonized energy sector present significant challenges, particularly in demand-side management. Thermal energy storage (TES) systems offer a cost-effective solution for enhancing energy flexibility in building heating systems. However, improper sizing and operation of TES systems can lead to increased investment costs and energy losses. To bridge this gap, this study proposes a novel, optimization-based framework for the systematic sizing and operation of TES systems. The methodology encompasses two key components: (1) an innovative TES sizing framework that integrates system modelling and optimization-based sizing leveraging historical thermal load data; (2) validation and performance evaluation of the sizing outputs through building energy simulations across three diverse building types and climatic conditions. Key findings demonstrate the framework’s ability to adapt to various scenarios, achieving operational cost reductions of up to 35 % and significantly enhancing the energy flexibility in terms of flexibility factor by up to 1.03. Furthermore, the proposed framework is shown to effectively optimize TES capacities to unique building load patterns. These results highlight the framework’s potential as a robust tool for optimizing TES in buildings, contributing to flexible and cost-efficient energy systems.

Topics & Concepts

SizingFlexibility (engineering)Thermal energy storageComputer scienceReliability engineeringEnergy storageProcess engineeringEnvironmental scienceEngineeringMathematicsQuantum mechanicsStatisticsPower (physics)BiologyPhysicsEcologyArtVisual artsBuilding Energy and Comfort OptimizationIntegrated Energy Systems OptimizationSolar Thermal and Photovoltaic Systems
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