In this study, a newly developed rate-dependent thermo-plastic constitutive model was enhanced to incorporate thermally accelerated creep and implemented into the Plaxis finite-element code, enabling the simulation of the behaviour of a well-instrumented energy pile in multilayered soft soils under thermomechanical loads. First, the model was validated against non-isothermal laboratory tests on soils surrounding the pile, and then against simulations of field tests. The results revealed that the inclusion of thermally accelerated creep improves the prediction of irreversible pile settlement, which is primarily attributed to the accumulation of volumetric contraction in the surrounding soil after each thermal cycle. The analysis also distinguishes between drag down effects resulting from thermo-elastic and thermo-plastic behaviour, as well as those induced by long-term creep.

Realistic numerical modeling of energy piles in soft soil requires advanced constitutive relationships capable of capturing the inherent thermo-plastic behavior of the surrounding ground. In this study, a newly developed rate-dependent, thermo-plastic constitutive model, called AVISA-T, is employed within the Plaxis Finite Element (FE) code to simulate the response of a well-instrumented energy pile embedded in multilayered soft soils subjected to thermo-mechanical loading. Following material parameter calibration and model prediction validation using non-isothermal laboratory tests on the soils surrounding the pile, the model was employed to simulate full-scale in-situ tests. In these simulations, the pile was initially subjected to either 0 % or 60 % of its bearing capacity and then exposed to continuous cooling over a period of up to three months. The AVISA-T model effectively reproduces the development of contractive and expansive strains, as well as compressive and tensile stresses that coexist along the pile shaft, including the accumulation of residual strains and stresses. In the absence of axial mechanical load, both residual contractive and expansive strains were observed, accompanied by irreversible uplift of the pile head, primarily attributed to non-uniform, unrecovered temperature changes. Moreover, under higher mechanical loading, the model captures dragdown effects resulting from thermal shrinkage of the surrounding soil, which contributes to the accumulation of permanent strains, stresses, and settlements. A comparison between simulations using the common Modified Cam Clay (MCC) model, the AVISA model without thermal effects and the AVISA-T model highlights the importance of using models including thermal plasticity for engineering practice.

This paper presents quantitative data from a field test on a new type of energy pile, called a displacement cast in situ energy pile. The test pile was installed in a multilayered soft soils and subjected to a continuous cooling for 3 months, with no mechanical load. Afterwards, the pile was loaded to a specific target of 20 or 60 % of its calculated ultimate bearing capacity and then subjected to up to five thermal cycles. Under zero mechanical load, the results revealed that the compressive/tensile stresses coexist along the pile. Under low mechanical load (20 %), thermal cycles induced irreversible residual contractive strains and stresses as well as a limited pile head settlement. Under high mechanical load (60 %) and extreme operating conditions, i.e., negative temperatures which could have indicated a frozen interface, further irreversible settlements observed at the end of this test. Mechanical pile tests however indicated no impact of stress history (including the freezing test) on the shaft resistance and the overall pile-bearing capacity.

Numerous full-scale in situ tests have been conducted to assess the effect of thermal cycles on the pile response. However, those studies investigated the response of only precast and cast in-situ energy piles, with limited focus on the impact of the applied mechanical load on the pile response. This study presents the results of a field test conducted on a new type of energy pile, i.e. a displacement cast in-situ energy pile in multilayered soft soils, subjected to different fixed mechanical loads while undergoing simultaneous thermal cycles. Four tests were carried out, each corresponding to various axial loads ranging from 0 % to 60 % of the pile's estimated bearing capacity. After applying the axial load on the pile head (0 %, 30 %, 40 %, or 60 % of the bearing capacity), the pile was subjected to up to ten thermal cycles. The highest magnitudes of thermal axial strains were observed near the pile top due to the lowest restraint provided by the made ground layer in all tests. Under zero (0 %) mechanical load, the thermal axial strains near the pile head were elastic and recoverable, while residual strain was observed near the toe. Under reasonable working mechanical loads (30 %, 40 %, or 60 %) residual strains were observed near both the pile head and the toe, with higher residual strains observed under higher mechanical loads. The results indicate that the cyclic thermal loadings could induce an increase in the compressive stress in the energy pile, attributed to the drag-down effects of the surrounding soil. The compressive stress induced by drag-down effects counteracts thermally induced tensile stress and thus leads to an insignificant effect on the energy pile during cooling. A limited impact of the shaft capacity was observed and was mainly attributed to the drag-down of the surrounding soil and thermal creep along the pile-soil interface.