Particle–scale interactions and energy dissipation mechanisms in sand–rubber mixtures

Fonseca, J.; Riaz, Arshad; Bernal-Sanchez, Juan; Barreto, Daniel; McDougall, John; Miranda, Marina; Marinelli, Aikaterini; Dimitriadi, Vasiliki

doi:10.1680/jgele.18.00221

Cited by 22 publications

(5 citation statements)

References 26 publications

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“…However, when mixed with rubber, damping is induced not only by the friction between sand and rubber particles but also by the deformation of the rubber particles, cf. Fonseca et al (2019). As a result, increasing the rubber content in the mixtures leads to an increase of the damping ratio as well.…”

Section: Intermediate Strain Responsementioning

confidence: 96%

Resonant Column Tests on Mixtures of Different Sands with Coarse Tyre Rubber Chips

Banzibaganye

Vrettos

2022

Geotech Geol Eng

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The dynamic behaviour of unsaturated sand rubber chips mixtures at various gravimetric contents is evaluated through an experimental study comprising resonant column tests in a fixed-free device. Chips were irregularly shaped with dimensions ranging from 5 to 14 mm. Three types of sand with different gradation have been considered. Relative density amounted to 0.5 for all specimens. Due to the large size of the chips, the diameter of the specimens had to be equal to 100 mm, which in turn required a re-calibration of the device assuming a frequency-dependent drive head inertia. The effects of confining stress, rubber chips content, and sand gradation on shear modulus and damping ratio are determined over wide ranges of the shear strain. At small strains, as known for sands, increasing the confining stress stiffens the mixtures. Increasing the rubber chips content reduces significantly the shear modulus and increases the damping ratio. At higher strains, increasing the confining stress or the rubber content flattens the reduction of the shear modulus with strain. Damping at high strains does not show any appreciable dependence on rubber content. Unloading–reloading sequences are used to assess shear modulus degradation and threshold strains. Finally, design equations are derived from the test results to predict the dynamic response of the composite material.

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Section: Intermediate Strain Responsementioning

confidence: 96%

Resonant Column Tests on Mixtures of Different Sands with Coarse Tyre Rubber Chips

Banzibaganye

Vrettos

2022

Geotech Geol Eng

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“…mainly compressibility) of the rubber-soil mixtures (e.g. Edil and Bosscher, 1994;Rao and Dutta, 2006;Lee et al, 2007, Fonseca et al, 2019Sheikh et al, 2012). These studies show that inter-particle sliding, grain rearrangement and distortion, as well as void-filling capacity of individual rubber particles contribute as key factors to the deformation mechanisms of rubber-soil mixtures.…”

Section: Introductionmentioning

confidence: 93%

The effect of adding rubber crumbs on the cyclic permanent deformation of waste mixtures containing coal wash and steel furnace slag

Qi¹,

Indraratna²

2023

Géotechnique

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Among the numerous studies into the dynamic loading behaviour of rubber crumbs-soil/waste mixtures, the main focus is on how the content of rubber crumbs (Rb%) affects the damping ratio, shear modulus and total deformation. However, the research into the influence of Rb% on the permanent strain rate ([Formula: see text]) and the deformation mechanism under repeated loading is very limited. In this current study, the cyclic deformation response for the waste mixtures of steel furnace slag (SFS), coal wash (CW) and rubber crumbs (RC) are analysed and the test results reveal that Rb% has a significant influence on the initial [Formula: see text] and the slope of the permanent axial strain rate line (PASRL), while cyclic deviator stress (qcyc,max) mainly affects the initial [Formula: see text]. The influence of Rb% and qcyc,max on [Formula: see text] of the waste mixture is incorporated in an empirical model, which enables to predict the permanent deformation mechanism of SFS+CW+RC mixtures with broader ranging amounts of RC and higher cyclic deviator stresses.

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“…clay, nano-stabilising agent and biopolymer nuclei) through the network, where the size of the edge of the network is determined from CSD, informed by μCT [59]; b criteria, whether a base particle would move through the constriction, whether it would be trapped, and when it would be retained in the void space [59]; c an example of determining CSD as a function of 15% percentile of particle size [58] processes involve complex interactions with the grains themselves and the pore space amongst them; such interactions are practically impossible to be studied in absence of advanced imaging tools. μCT has also been used to study the interaction between rigid and soft particles in sand-rubber mixtures as a means for improving the properties/behaviour of sands [63]. Not only can the grains be visualised via processed X-ray images, but the kinematics and interactions of the grains can be quantified using software, such as the python-based Software for Practical Analysis of Materials (SPAM, [64]).…”

Section: Microcomputed Tomography (µCt)mentioning

confidence: 99%

Recent Advances in Nature-Inspired Solutions for Ground Engineering (NiSE)

Assadi-Langroudi

O’Kelly

Barreto

et al. 2021

Int. J. of Geosynth. and Ground Eng.

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The ground is a natural grand system; it is composed of myriad constituents that aggregate to form several geologic and biogenic systems. These systems operate independently and interplay harmoniously via important networked structures over multiple spatial and temporal scales. This paper presents arguments and derivations couched by the authors, to first give a better understanding of these intertwined networked structures, and then to give an insight of why and how these can be imitated to develop a new generation of nature-symbiotic ground engineering techniques. The paper draws on numerous recent advances made by the authors, and others, in imitating forms (e.g. synthetic fibres that imitate plant roots), materials (e.g. living composite materials, or living soil that imitate fungi and microbes), generative processes (e.g. managed decomposition of construction rubble to mimic weathering of aragonites to calcites), and functions (e.g. recreating the self-healing, selfproducing, and self-forming capacity of natural systems). Advances are reported in three categories of Materials, Models, and Methods (3Ms). A novel value-based appraisal tool is also presented, providing a means to vet the effectiveness of 3Ms as standalone units or in combinations.

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Particle–scale interactions and energy dissipation mechanisms in sand–rubber mixtures

Cited by 22 publications

References 26 publications

Resonant Column Tests on Mixtures of Different Sands with Coarse Tyre Rubber Chips

Resonant Column Tests on Mixtures of Different Sands with Coarse Tyre Rubber Chips

The effect of adding rubber crumbs on the cyclic permanent deformation of waste mixtures containing coal wash and steel furnace slag

Recent Advances in Nature-Inspired Solutions for Ground Engineering (NiSE)

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