Abstract
This study focuses on the evolution of shaft resistance during operation of a geothermal energy foundation installed in a saturated glacial till layer. Energy foundations are a sustainable alternative to traditional space heating and cooling approaches for buildings. Despite efficient operational performance, there are still valid concerns regarding the effects of heating on the structural performance of foundations. To investigate the effect of heating at the soil-pile interface, four drilled shafts are utilized as energy foundations on the Urbana-Champaign campus of the University of Illinois and instrumented. Although the energy foundations are not yet operational, a theoretical investigation is possible to understand the effects of heating on the evolution of thermally induced pore water pressures and the shaft resistance of an energy foundation. A thermo-poroelastic numerical model is validated against an analytical solution, then is used to analyze the thermo-mechanical response of the soil-structure system under different conditions. The results indicate that the evolution of pore water pressure is affected by the rate of heating and the hydraulic conductivity of the surrounding soil, as expected. Higher pore water pressures are generated in the case of low hydraulic conductivity and higher rates of heating. Prior to the dissipation of excess pore pressures, the changes in shaft resistance are variable and influenced by the thermally-induced deformation of the foundation and the surrounding soil.
Highlights
Energy foundations are used to exchange heat between structural elements of foundations and surrounding soil for heating and cooling of buildings, and they are proven to provide efficient and sustainable heating and cooling [1]
One advantage of geothermal energy foundations compared to other shallow geothermal energy technologies, such as thermal energy storage systems and ground source heat pumps where horizontal or vertical boreholes are used, is that they don’t require extra drilling or excavation [2,3]
Bodas-Freitas et al [16] performed numerical simulations to investigate the effect of heating on the shaft resistance in an energy foundation
Summary
Energy foundations are used to exchange heat between structural elements of foundations and surrounding soil for heating and cooling of buildings, and they are proven to provide efficient and sustainable heating and cooling [1]. Potential issues include thermally induced axial and radial stresses and strains within the foundation and adjacent soil, as well as the generation of thermally induced excess pore water pressures in soils having low hydraulic conductivity. These stresses and pore water pressures could affect the mobilized or ultimate foundation shaft resistance and lead to instability in the overlying structure. The model is first validated against results from two laboratory experiments in the literature that allow to perform parametric study to investigate the factors affecting excessive pore water pressure development and consequent changes in shaft resistances
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
