Analysis of Friction Induced Thermo-Mechanical Stresses on a Heat Exchanger Pile in Isothermal Soil

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

doi:10.1007/s10706-014-9821-0

Cited by 43 publications

(25 citation statements)

References 23 publications

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“…The Young's modulus and the thermal expansion coefficient of the tested pile were 40 GPa and 8·5 me/°C respectively. The shaft friction along the pile shaft was modelled using elastic perfectly plastic interface elements with stiffness as presented by Ozudogru et al (2015). As presented in Figures 4(b) and 4(c), the axial thermal strains and loads along the tested pile estimated using the proposed hybrid model agree with those approximated using the full 3D finite-element model and also with the results of the field test.…”

Section: Validation Of the Finite-element Modelmentioning

confidence: 55%

“…The second step considers validating the hybrid thermomechanical modelling technique against the full 3D finite-element models used by Ozudogru et al (2015) to mimic the results of a thermomechanical field load test on a free-head heat sink pile (Amatya et al, 2012). In this field test, an energy pile -55 cm Non-uniform thermal strains and stresses in energy piles Abdelaziz and Ozudogru dia.…”

Section: Validation Of the Finite-element Modelmentioning

confidence: 99%

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Non-uniform thermal strains and stresses in energy piles

AbdelazizSherif

Ozudogru

2016

Environmental Geotechnics

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2This paper presents the non-uniform thermally induced strains and stresses that develop in the cross-sections of energy piles when subjected to operational energy demands. The thermal operation of energy piles depends on the thermal demands of the supported building. These thermal demands vary seasonally, daily and even hourly, which generates non-uniform temperature changes over the pile's cross-section throughout the lifetime of the system. Therefore, non-uniform thermal strains and stresses develop over the cross-section of energy piles. Numerical analyses performed in this study indicate that the maximum temperature changes and the thermally induced strains and stresses occur near the location of the ground loops. Further, contradicting the current understanding that heating the piles creates only thermal compressive stresses, while cooling them creates only thermal tensile stresses;tensile and compressive thermal stresses were found to coexist during heating and cooling over the same pile crosssection due to the non-uniform temperature changes. Furthermore, the magnitude of the tensile stresses that develop due to non-uniform temperature changes is crucial when the reinforcing cage is cut short of the pile toe.Finally, ignoring the non-uniform temperature changes while processing the temperatures and strains measured in full-scale tests will result in errors in approximated thermal stresses.

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Section: Validation Of the Finite-element Modelmentioning

confidence: 55%

Section: Validation Of the Finite-element Modelmentioning

confidence: 99%

Non-uniform thermal strains and stresses in energy piles

AbdelazizSherif

Ozudogru

2016

Environmental Geotechnics

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“…Ouyang et al (2011) and Bailie (2013) used the load-transfer method which simulates thermal effects as a mechanical expansion of the beam representing the pile. The finite-element method was adopted by Ozudogru et al (2015), where the focus was on the modelling of the pile-soil interface without simulating the heat transfer in the soil, as well as Yavari et al (2014b) and Yavari et al (2015), who performed uncoupled analyses where the soil was modelled as linear elastic-perfectly plastic. Recently, Abdelaziz and Ozudogru (2016) combined the finite-element method, to simulate the heat transfer in the pile and the soil, with the load transfer approach, to approximate the thermal stresses.…”

Section: Introductionmentioning

confidence: 99%

Numerical modelling of thermo-active piles in London Clay

Gawecka

Taborda

Potts

et al. 2017

Proceedings of the Institution of Civil Engineers - Geotechnica

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Thermo-active foundations utilise heat energy stored in the ground to provide a reliable and effective means of space heating and cooling. Previous studies have shown that the effects of temperature changes on their response are highly dependent on their interaction with the surrounding ground. Consequently, it is necessary to consider this interaction and include both the thermal and mechanical behaviour of the ground in design. This paper addresses this issue by performing state-of-the-art finite-element analyses using the Imperial College Finite Element Program, which is capable of simulating the fully coupled thermo-hydro-mechanical behaviour of porous materials. First, the Lambeth College pile test is analysed to demonstrate the capability of the adopted modelling approach to capture the observed response under thermo-mechanical loading. Subsequently, a detailed study is carried out, demonstrating the impact of capturing the fully coupled thermo-hydro-mechanical response of the ground, the use of appropriate boundary conditions and the uncertainty surrounding thermal ground properties. It is demonstrated that the modelling approach has a large impact on the computed results, and therefore potentially on the design of thermo-active piles. Conversely, the effects of thermal conductivity and permeability of the soil are shown not to influence the pile behaviour significantly.

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“…Murphy and McCartney (2014) studied the thermal and thermo-mechanical response of two energy piles during operation of a heat pump used for heating and cooling an 8-story building. Ozudogru et al (2014b) used a load transfer model to evaluate the role of side shear stresses in the axial stress distribution in energy piles. Chakraborty and Saggu (2014) used the results from a field study on energy piles to calibrate a thermo-elastic finite element analysis, and extrapolated the findings to study the cyclic response of energy piles.…”

Section: This Special Issue Of Geotechnical and Geologicalmentioning

confidence: 99%

“…These challenges include the roles of cyclic heating and cooling, which was revealed in the work of Chakraborty and Saggu (2014) and Murphy and McCartney (2014). As testing of full-scale energy piles can be expensive, the roles of physical modeling and numerical modeling of these systems needs to be expanded in future years to understand basic mechanisms of energy piles (Kramer et al 2014;Ozudogru et al 2014b;Chakraborty and Saggu 2014;Wang et al 2014;Yu et al 2015). These challenges also include the role of unsaturated conditions, which can have significant impacts on the heat exchange behavior of heat exchangers (Dong et al 2014;Likos 2014;Wu et al 2014) as well as the thermo-mechanical behavior of energy piles and other thermo-active foundations (Houston et al 2014;Wang et al 2014).…”

Section: This Special Issue Of Geotechnical and Geologicalmentioning

confidence: 99%