Your search keyword '"Teresa M. Bodas Freitas"' showing total 9 results

1. A Numerical Study of the Behavior of Micropile Foundations under Cyclic Thermal Loading

Author

Arianna Lupattelli, Peter J. Bourne-Webb, Teresa M. Bodas Freitas, and Diana Salciarini

Subjects

shallow geothermal energy, micropile, foundations, finite element analysis, heating and cooling, thermo-mechanical analysis, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Micropiles are small-diameter foundation elements that are widely used in building refurbishment to reinforce existing foundations or provide new foundations where access for construction is difficult. Thermally-activated (TA) micropiles could be useful as an efficient means of providing cost-effective ground-coupling when shallow geothermal energy systems are considered in building rehabilitation. It is well-established that thermal activation of pile foundations results in thermo-mechanical interactions between the pile and the surrounding soil. These thermally-induced effects need to be examined to ensure that they do not adversely impact the load transfer function of the micropile. Numerical analysis is able to produce reliable predictions of thermo-mechanical behavior of TA piles, and this study applied this technique to examine the cyclic thermal behavior of micropiles, isolated and in groups. For the situations considered in this study, it is shown that during cyclic thermal activation, irrecoverable movements are unlikely to be significant in design terms, if the initial mobilization of the shaft resistance is low. Though stable, cyclic thermal movement amplitudes are large enough that they should be considered in design. The study highlights that large changes in thermal stress can develop and be locked-in to the response of long flexible piles, and that these should be verified in design. Further, as pile spacing reduces, thermal interference results in a loss of heat exchange capacity per pile, which has to be considered in the design of large groups of TA micropiles. Therefore, TA micropiles can offer an efficient and secure means of providing ground coupling in shallow geothermal energy systems.

Published

2023

2. The influence of initial shaft resistance mobilisation in the response of seasonally, thermally-activated pile foundations in granular media

Author

Teresa M Bodas Freitas, Peter John Bourne-Webb, Arianna Lupattelli, and Diana Salciarini

Subjects

Pile foundations, Soil–structure interaction, Thermal analysis, Shallow geothermal energy, Computers in Earth Sciences, Geotechnical Engineering and Engineering Geology, Safety, Risk, Reliability and Quality

Published

2022

3. Effect of Domain Size in the Modelled Response of Thermally-Activated Piles

Author

Martina Zito, Teresa M. Bodas Freitas, P.J. Bourne-Webb, and Donatella Sterpi

Subjects

Energy geostructures, Work (thermodynamics), Mechanical load, soil-structure interaction, numerical analysis, business.industry, Numerical analysis, Structural engineering, Domain (software engineering), Initial distribution, Soil structure interaction, Energy geostructures, pile foundations, soil-structure interaction, numerical analysis, business, Pile, pile foundations, Geology

Abstract

The application of thermally-activated pile foundations has received significant attention in the last decade with a number of large- and small-scale tests having been undertaken. Alongside these physical studies, a number of investigations utilising numerical analysis have been undertaken to examine the behaviour of single piles and pile groups. Focussing on studies examining single piles, it is apparent that a variety of differing domain dimensions have been used. The work presented in this paper had the objective of systematically examining the influence of the domain size and how it affects the predicted thermo-mechanical response of the pile. It shows that the domain size has an important impact on the initial distribution of mobilised shaft friction due to applied mechanical load which then impacts on the subsequent thermo-mechanical response.

Published

2021

4. A novel approach to the evaluation of contact thermal resistance at soil-structure interfaces

Author

P.J. Bourne-Webb, Teresa M. Bodas Freitas, and João Diogo Figueira

Subjects

lcsh:GE1-350, Aggregate (composite), business.industry, 020209 energy, Geothermal energy, Thermal resistance, 02 engineering and technology, Renewable energy, 020401 chemical engineering, Heat transfer, Heat exchanger, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering, business, Energy source, Process engineering, lcsh:Environmental sciences, Efficient energy use

Abstract

Considering the need to reduce our dependence on unsustainable energy sources and reducing the carbon footprint associated with building climate control, shallow geothermal energy represents an attractive sustainable technology for providing renewable heating and cooling. The temperature field generated around ground-coupled heat exchangers, and thus their energy efficiency, fundamentally depends on the heat transfer mechanism and the thermal properties of the materials involved. While the thermal properties of materials that make up the system can be defined with some certainty, little is known about the impact of contact thermal resistance at the soil-structure interface. Contact thermal resistance will reduce heat exchange efficiency and increase mechanical impacts associated with temperature changes within energy geo-structures. This paper describes a laboratory test method to quantify the contact thermal resistance of soil-concrete interfaces. The methodology is first evaluated using numerical analysis, and then validated against a test using a limestone aggregate concrete and fine, silica sand at differing levels of compaction.

Published

2020

5. Effect of thermal boundary conditions on the response of thermally-activated floating piles in a cohesive material

Author

P.J. Bourne-Webb, Martina Zito, Teresa M. Bodas Freitas, and Donatella Sterpi

Subjects

lcsh:GE1-350, Work (thermodynamics), Numerical analysis, 0211 other engineering and technologies, Foundation (engineering), Boundary (topology), 02 engineering and technology, Thermal, Range (statistics), Geotechnical engineering, 021108 energy, Transient (oscillation), Pile, lcsh:Environmental sciences, Geology, 021101 geological & geomatics engineering

Abstract

The application of thermally-activated foundations has received significant attention in the last decade with a number of large- and small-scale tests having been undertaken. Alongside these physical studies, a number of investigations utilising numerical analysis have been undertaken. The majority of analyses are transient with durations from a few hours up to 10 years. A broad range of thermal boundary and initial conditions have been applied in these analyses, and only a limited number of studies have explicitly considered the surface boundary imposed by an overlying structure, let alone considered what effect variations in the operational temperatures of the structure might have on the foundations. The work presented in this paper had the objective of systematically examining these assumptions and the effect they have on the predicted response of a thermally-activated pile foundation, and if important, which is the most appropriate set of conditions to use.

Published

2020

6. Thermal performance of seasonally, thermally-activated floating pile foundations in a cohesive medium

Author

Martina Zito, Donatella Sterpi, Teresa M. Bodas Freitas, and P.J. Bourne-Webb

Subjects

Renewable energy, business.industry, Geothermal energy, Numerical analysis, 0211 other engineering and technologies, Foundation (engineering), 020101 civil engineering, Shallow geothermal energy, Pile foundations, Soil-structure interaction, Thermal analysis, Renewable energy, 02 engineering and technology, Shallow geothermal energy, Thermal expansion, 0201 civil engineering, Pile foundations, Soil structure interaction, 021105 building & construction, Thermal, Soil-structure interaction, Geotechnical engineering, Thermal analysis, business, Pile, Geology, Civil and Structural Engineering

Abstract

The thermal-activation of pile foundations for use within shallow geothermal energy systems has received much attention with a number of studies having reported full- and small-scale testing and/or numerical analysis. Various conditions in terms of pile type, ground profiles and thermal loading, have been considered in these studies, leading to a broad understanding of the thermo-mechanical behaviour of thermally-activated pile foundations. One area that requires further attention is the clarification of the foundation response under seasonal cyclic thermal loading. This study systematically assesses the impact of cyclic thermal loading in relation to the initial mechanical loading, for isolated floating piles and pile groups in a cohesive soil medium. For piles where the shaft resistance dominates the pile total resistance, it was found that irrecoverable movement will be small and thermal stress and pile head movements change in a cyclic and regular manner. It is shown that the effect of the coefficient of thermal expansion of the soil, is much reduced from that suggested in studies using constant thermal loads applied over long periods. The effect of the overlying building was explored and it is shown that thermal-activation of the pile foundation mitigates the effect of the imposition of a higher average temperature at the surface.

Published

2021

7. Characterization of the geological and geotechnical conditions at the village of Monsanto

Author

Ricardo Prazeres, Carlos Neto de Carvalho, Isabel Fernandes, João Calvão, and Teresa M. Bodas Freitas

Subjects

lcsh:GE1-350, 010504 meteorology & atmospheric sciences, Granitic rock, Uniaxial compression, Classification of discontinuities, 010502 geochemistry & geophysics, Field survey, 01 natural sciences, Characterization (materials science), Geotechnical engineering, Rock mass classification, Shear strength (discontinuity), lcsh:Environmental sciences, Geology, 0105 earth and related environmental sciences

Abstract

The stability of slopes and hillsides involving rock or soil masses depends crucially on the occurring geological and geotechnical conditions. The village of Monsanto, municipality of Idanha-a-Nova, is located on a granitic inselberg. The tourist interest of the village lies largely in the fusion of the granitic rock mass with the man-made constructions and in the aesthetics of several granitic boulders scattered throughout the village. In the present work the geological and geotechnical characterization of the rock mass has been carried out, namely by the field survey of the entire intervention area and by a set of laboratory tests on samples collected in the field (ultrasound propagation velocity and the uniaxial compression test). Based on this information, the shear strength of the discontinuities was estimated and a kinematic analysis was performed using the Dips 7.0 commercial software, with the objective of defining the predominant sets of joints and identifying the most probable failure mechanisms in each hillside.

Published

2019

8. The effect of creep on the short-term bearing capacity of pre-loaded footings

Author

Lidija Zdravković, David M. Potts, and Teresa M. Bodas Freitas

Subjects

business.industry, Stiffness, Structural engineering, Dissipation, Geotechnical Engineering and Engineering Geology, Finite element method, Computer Science Applications, Pore water pressure, Creep, Shallow foundation, Hardening (metallurgy), medicine, Geotechnical engineering, Bearing capacity, medicine.symptom, business, Geology

Abstract

This paper presents a numerical study on the short-term bearing capacity of preloaded footings on soft clay. In practice, this situation needs to be addressed when re-using an existing foundation for a new building or when extra load is to be transmitted to an existing foundation. Previous studies have estimated the bearing capacity in this situation, allowing simply for the increase in the soil undrained strength due to the increase in effective stresses imposed by the preload. However, field and laboratory observations corroborate that there is a continuous increase in the stiffness and strength soil properties with time, even after the dissipation of the excess pore water pressures generated during the initial loading is complete. This paper quantifies the short-term bearing capacity of existing foundations allowing for the occurrence of creep deformations and associated soil hardening. The problem is investigated by means of a series of plane-strain coupled finite element analyses of a 2 m wide rough strip footing, in which the foundation soil is modelled using an overstress based elastic-viscoplastic model. The study investigates the effect of the level of preload, the applied loading rate, the creep characteristics of the foundation soil (magnitude and creep law type) and the footing geometry. It is shown that the time dependent nature of soil (e.g. occurrence of creep) accounts for a significant increase in bearing capacity.

Published

2012

9. A time dependent constitutive model for soils with isotach viscosity

Author

David M. Potts, Teresa M. Bodas Freitas, and Lidija Zdravković

Subjects

Creep, Viscoplasticity, Isotropy, Scalar (mathematics), Stress space, Constitutive equation, Geotechnical engineering, Mechanics, Stress conditions, Finite element program, Geotechnical Engineering and Engineering Geology, Computer Science Applications, Mathematics

Abstract

This paper presents a three-dimensional elastic viscoplastic constitutive model that is able to reproduce the time dependent behaviour of soils with isotach viscosity. This constitutive law is based on the overstress theory and incorporates some important features, namely: (i) a non-linear creep law with a limit for the amount of creep deformation under isotropic stress conditions; (ii) a flexible loading surface that is capable of reproducing a wide range of shapes in p ′ − J stress space and incorporates the Matsuoka–Nakai failure criterion in the deviatoric stress space and (iii) assumes that the viscoplastic scalar multiplier is constant on a given loading surface to ensure that critical state conditions are reached. A full description of the model, its governing equations and implementation in a finite element program are presented. The model is then used to simulate the results of laboratory tests, highlighting the model’s abilities and shortcomings in reproducing the time dependent behaviour of soft clays. Furthermore, the paper investigates the importance of accounting for creep non-linearity and the consequences of isotach viscosity on the critical state line.

Published

2011