Use of Geogrids and Recycled Rubber in Railroad Infrastructure for Enhanced Performance

Indraratna, Buddhima; Qi, Yujie; Ngo, Ngoc Trung; Rujikiatkamjorn, Cholachat; Neville, Tim; Ferreira, Frederico; Shahkolahi, Amir

doi:10.3390/geosciences9010030

Cited by 43 publications

(21 citation statements)

References 61 publications

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“…In an engineering context, recent emerging issues have led to the design of new materials in the form of a mixture of soil particles with rubber pieces (made from discarded tires). Such composite material exhibits new and fascinating mechanical properties, such as better stress relaxation [16][17][18][19], seismic isolation [20][21][22][23], and foundation damping [16,19,24,25], while reducing the weight of the structures or increasing the packing fraction of the granular composites. The range of applications for rigid-deformable composites is potentially broad and opens the door to an extensive field of fundamental topics that are still poorly studied.…”

Section: Introductionmentioning

confidence: 99%

Compaction of mixtures of rigid and highly deformable particles: A micromechanical model

et al. 2020

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We analyze the isotropic compaction of mixtures composed of rigid and deformable incompressible particles by the nonsmooth contact dynamics approach. The deformable bodies are simulated using a hyperelastic neo-Hookean constitutive law by means of classical finite elements. We characterize the evolution of the packing fraction, the elastic modulus, and the connectivity as a function of the applied stresses when varying the interparticle coefficient of friction. We show first that the packing fraction increases and tends asymptotically to a maximum value φ max , which depends on both the mixture ratio and the interparticle friction. The bulk modulus is also shown to increase with the packing fraction and to diverge as it approaches φ max . From the micromechanical expression of the granular stress tensor, we develop a model to describe the compaction behavior as a function of the applied pressure, the Young modulus of the deformable particles, and the mixture ratio. A bulk equation is also derived from the compaction equation. This model lays on the characterization of a single deformable particle under compression together with a power-law relation between connectivity and packing fraction. This compaction model, set by well-defined physical quantities, results in outstanding predictions from the jamming point up to very high densities and allows us to give a direct prediction of φ max as a function of both the mixture ratio and the friction coefficient.

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Section: Introductionmentioning

confidence: 99%

Compaction of mixtures of rigid and highly deformable particles: A micromechanical model

et al. 2020

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“…Geosynthetics have been widely used as a reinforcement material in several geotechnical engineering applications, such as roadway and railway layers and embankments Ashmawy and Bourdeau, 1995;Lee and Wu, 2004;Ravi et al, 2014;Ferreira et al, 2016a;Nimbalkar and Indraratna, 2016;Indraratna et al, 2018Indraratna et al, , 2019Ngo et al, 2018;Byun and Tutumluer, 2019;Tatsuoka, 2019). In such applications, the interaction mechanism between the geosynthetic and the surrounding material is of primary importance.…”

Section: Introductionmentioning

confidence: 99%

Pullout Behavior of Different Geosynthetics—Influence of Soil Density and Moisture Content

Ferreira

Vieira

Lopes

2020

Front. Built Environ.

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Geosynthetics have increasingly been used as reinforcement in permanent earth structures, such as road and railway embankments, steep slopes, retaining walls, and bridge abutments. The understanding of soil-geosynthetic interaction is of primary importance for the safe design of geosynthetic-reinforced soil structures, such as those included in transportation infrastructure projects. In this study, the pullout behavior of three different geosynthetics (geogrid, geocomposite reinforcement, and geotextile) embedded in a locally available granite residual soil is assessed through a series of large-scale pullout tests involving different soil moisture and density conditions. Test results show that soil density is a key factor affecting the reinforcement pullout resistance and the failure mode at the interface, regardless of geosynthetic type or soil moisture content. The soil moisture condition may considerably influence the pullout response of the geosynthetics, particularly when the soil is in medium dense state. The geogrid exhibited higher peak pullout resistance than the remaining geosynthetics, which is associated with the significant contribution of the passive resistance mobilized against the geogrid transverse members to the overall pullout capacity of the reinforcement.

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“…Furthermore, since good quality natural aggregates are becoming increasingly scarce and associated environmental legislation is becoming more stringent, finding sustainable and innovative ways of recycling various types of industry wastes (used tyre derivatives, CW, plastics, glass etc.) for developing civil infrastructure will become crucial (Arulrajah et al, 2020a(Arulrajah et al, , 2020bIndraratna et al, 2018Indraratna et al, , 2019aNaeini et al, 2020;Suddeepong et al, 2020). The commercial use of these engineered fills (SFS and CW) above the groundwater level has already been approved by the Environment Protection Authority of the state of New South Wales (NSW EPA, 2014a, 2014b), indicating insignificant leachate potential and toxicity.…”

Section: Introductionmentioning

confidence: 99%

Advances in ground improvement using waste materials for transportation infrastructure

Indraratna

Tawk

et al. 2022

Proceedings of the Institution of Civil Engineers - Ground Impr

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Recycling waste materials for transport infrastructure such as coal wash (CW), steel furnace slag (SFS), fly ash (FA) and recycled tyre products is an efficient way of minimising the stockpiles of waste materials while offering significant economic and environmental benefits, as well as improving the stability and longevity of infrastructure foundations. This paper presents some of the most recent state-of-the-art studies undertaken at the University of Wollongong, Australia on the use of waste materials such as (a) CW-based granular mixtures (i.e. SFS + CW, CW + FA) for port reclamation and road base/subbase and (b) using recycled tyre products (i.e. rubber crumbs, tyre cell, under-sleeper pads and under-ballast mats) to increase track stability and reduce ballast degradation. Typical methods of applying these waste materials for different infrastructure conditions are described and the results of comprehensive laboratory and field tests are presented and discussed. Cite this articleIndraratna B, Qi Y, Tawk M et al. Advances in ground improvement using waste materials for transportation infrastructure.

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Use of Geogrids and Recycled Rubber in Railroad Infrastructure for Enhanced Performance

Cited by 43 publications

References 61 publications

Compaction of mixtures of rigid and highly deformable particles: A micromechanical model

Compaction of mixtures of rigid and highly deformable particles: A micromechanical model

Pullout Behavior of Different Geosynthetics—Influence of Soil Density and Moisture Content

Advances in ground improvement using waste materials for transportation infrastructure

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