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Co-simulation of building energy and geothermal systems: A review

Hamed Yazdani, Philipp Blum, Kathrin Menberg

2025Energy and Buildings6 citationsDOIOpen Access PDF

Abstract

Integration of geothermal systems into buildings is imperative for a sustainable energy transition. Coupled simulation of building energy systems and geothermal technologies can support reliable and efficient geothermal-based system design, while ensuring thermal comfort inside the building. While co-simulation has been widely applied, a comprehensive review of existing approaches and applications is still lacking. This study, therefore, reviews co-simulation of building energy and geothermal systems covering modeling techniques, coupling approaches, software options, as well as existing case studies. A total of 141 co-simulation studies were identified, mostly conducted using one single software such as TRNSYS (58 %), EnergyPlus (9 %), IDA ICE (8 %) and Modelica (5 %) by incorporating simplified semi-analytical geothermal models. Only few studies coupled a building energy tool with a high-fidelity physical model of the subsurface for co-simulation (< 10 %). Studies mainly focused on borehole heat exchangers (BHE) (65 %), followed by borehole thermal energy storage (BTES) (19 %), ground heat exchangers (GHE) (8 %), aquifer thermal energy storage (ATES) (3 %) and energy piles (EP) (2 %). Over 80 % of research investigated residential, commercial and institutional buildings, largely for heating applications. Co-simulation revealed high potential of geothermal systems in buildings, with COP of 4 ± 1, discomfort times of 6 % ± 4 %, payback period of 14 ± 9 years, and CO 2 savings of 40 % ± 27 %. The literature review showed an evolution from early feasibility analyses to detailed physics co-simulation and hybrid geothermal energy systems. Several opportunities are highlighted for future research in the field regarding software coupling, geothermal model validation and system design. Specifically, creating a co-simulation framework for optimal design of building integrated geothermal systems is the key opportunity for advancing geothermal technology application.

Topics & Concepts

Geothermal energyEnvironmental scienceGeothermal gradientEnergy (signal processing)Geothermal heatingEngineeringEfficient energy useCivil engineeringPetroleum engineeringGeologyEnergy engineeringArchitectural engineeringRenewable energyHeat flowEnergy performanceWaste managementEnergy sourceGeothermal Energy Systems and ApplicationsBuilding Energy and Comfort OptimizationSolar Energy Systems and Technologies