Thermo-mechanical radial expansion of heat exchanger piles and possible effects on contact pressures at pile–soil interface

Olgun, C. Güney; Ozudogru, Tolga Y.; Arson, Chloé

doi:10.1680/geolett.14.00018

Cited by 88 publications

(30 citation statements)

References 18 publications

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“…Evaluation of the radial thermal response will also provide confirmation of the role of pile-soil 5 interface stresses due to radial thermal expansion of energy piles on their ultimate capacity, which has been proposed as a possible mechanism contributing to the side shear resistance of centrifuge-scale energy piles in compacted silt along with changes in effective stress in unsaturated soils associated with thermally induced drying (McCartney and Rosenberg, 2011;Goode and McCartney, 2015). Preliminary numerical and analytical studies using cavity expansion analyses by Olgun et al (2014) and Zhou et al (2016) indicate that no significant changes in pile-soil interface stresses are expected from the radial thermal expansion of the pile. However, these studies have not been validated against field scale studies.…”

Section: Introductionmentioning

confidence: 85%

“…Frequent temperature reversals may induce different magnitudes of thermal loads in the pile and at the pile-soil interface compared to monotonic 4 temperature changes. Depending on the soil surrounding the energy pile, thermal cycles could cause fatigue-like processes which could intensify deformations of the pile and the surrounding soil (Suryatriyastuti et al 2013;Olgun et al, 2014;Pasten and Santamarina 2014). Although investigated using numerical simulations for energy piles in idealized soil layers, this cyclic thermal mechanism is not well understood at a field scale.…”

Section: Introductionmentioning

confidence: 99%

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Axial and Radial Thermal Responses of a Field-Scale Energy Pile under Monotonic and Cyclic Temperature Changes

Faizal

Bouazza

Haberfield³

et al. 2018

J. Geotech. Geoenviron. Eng.

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The axial and radial thermal responses of a field-scale energy pile installed in dense sand and subjected to monotonic and cyclic temperatures are examined. It is found that the axial thermal strains in the pile are more restricted to thermal expansion/contraction compared to radial thermal strains. The radial thermal strains are close to that of a pile expanding/contracting freely, indicating minimal resistance from the surrounding soil in the radial direction. As a result, very low magnitudes of radial thermal stresses developed in the pile compared to axial thermal stresses. The pile-soil radial contact stresses estimated from cavity expansion analysis are up to 12 kPa for a pile temperature change of 22.5 o C and are likely negligible for the range of commonly-encountered operating temperatures of energy piles installed in dense sand. During cyclic heating and cooling, unstable changes in axial and radial thermal strains were observed initially during initial cycles indicating a ratcheting response. The changes in strains became more stable over further cycles, without significant changes in side friction, pile-soil contact stresses, or strength of the dense sand.

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Section: Introductionmentioning

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Axial and Radial Thermal Responses of a Field-Scale Energy Pile under Monotonic and Cyclic Temperature Changes

Faizal

Bouazza

Haberfield³

et al. 2018

J. Geotech. Geoenviron. Eng.

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“…However, the temperature change of pile foundations during heating and cooling may lead to some irreversible volumetric strain for the surrounding soils [4,5]. It would also cause the changes in the toe resistance and shaft friction along the pile, which would affect the serviceability and stability of pile foundations [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

Thermomechanical Behavior of Energy Pile Embedded in Sandy Soil

Huang

Peng

et al. 2018

Mathematical Problems in Engineering

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The traditional energy pile (solid energy pile) has been implemented for decades. However, the design of different kinds of energy piles is still not well understood. In this study, a series of model tests were performed on an aluminum pipe energy pile (PEP) in dry sandy soil to investigate the thermal effects on the mechanical behaviors of pipe energy pile. The thermal responses of the PEP were also analyzed. Steady temperatures of the PEP under different working conditions were also compared with that of the solid energy pile. Different loading tests were carried out on four pipe energy piles under three different temperatures of 5, 35, and 50 ∘ C, respectively. The bearing capacity change can be interpreted through the load-displacement curves. Experiment results were also compared with the solid energy pile to evaluate bearing capacities of the PEP and the solid energy pile under different temperature conditions. The mobilized shaft resistance was also calculated and compared with the solid energy pile data and the results show that the PEP has a similar load transfer mechanism with the solid energy pile. It could also be found that, for PEPs under working load, plastic displacement would appear after a whole heating cycle.

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Section: Introductionmentioning

confidence: 99%

“…These temperature changes can affect the stress state at the pile-soil interface and the shear strength of the soil that affects the tip resistance (Olgun et al, 2014). Recent studies on the impact of thermal loading at pile-soil interface indicate that the bearing capacity of the pile is not significantly affected (Suguang et al, 2014, Di Donna, 2014, GSHP Association, 2012, Mimouni, 2014, Olgun et al, 2014. Xiao et al (2014) and Di Donna (2014) have analyzed monotonic temperature variations in the range from 6°C to 50°C-60°C and have concluded that higher temperatures increase the strength of the clay-concrete contact and that the sand-concrete interface is not affected by the monotonic temperature changes.…”

Section: Introductionmentioning

confidence: 99%

Numerical Investigation on the Thermo-mechanical Behavior of a Quadratic Cross Section Pile Heat Exchanger

Pagola¹,

Madsen²,

Jensen³

et al. 2017

Proceedings of the IGSHPA Technical/Research Conference and Expo 2017

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Pile heat exchangers are traditional foundation piles with built in heat exchangers. As such, the footing of the building both serves as a structural component and a heating/cooling supply element. The existing geotechnical design standards do not consider the nature of thermo-active foundations and, therefore, there is a need to develop guidelines to design them properly. This paper contributes by studying the thermo-mechanical behavior of the precast piles which are 15-meter long and have a quadratic cross section and a W-shape pipe heat exchanger. This article aims to numerically assess the additional changes in the pile load transfer generated by its heating and cooling. In addressing this objective, a preliminary multi-physical finite element analysis is conducted which serves as a tool for exploring: i) the thermally induced mechanical stresses within the concrete and on the pile-soil axial and shaft resistances; ii) the maximum upward/downward displacements. A one-year time span is considered under operational and extreme thermal boundary conditions. The results show that a typical geothermal utilization of the energy foundation does not generate significant structural implications onthe geotechnical capacity of a single energy pile. However, ground thermal loads need to be considered in the design phase to account for potential extreme temperature changes, which could generate thermal stresses that equalize the mechanically generated ones.

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Thermo-mechanical radial expansion of heat exchanger piles and possible effects on contact pressures at pile–soil interface

Cited by 88 publications

References 18 publications

Axial and Radial Thermal Responses of a Field-Scale Energy Pile under Monotonic and Cyclic Temperature Changes

Axial and Radial Thermal Responses of a Field-Scale Energy Pile under Monotonic and Cyclic Temperature Changes

Thermomechanical Behavior of Energy Pile Embedded in Sandy Soil

Numerical Investigation on the Thermo-mechanical Behavior of a Quadratic Cross Section Pile Heat Exchanger

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