Deformation and failure modes of drystone retaining walls

Powrie, W.; Harkness, R. M.; Zhang, X.; Bush, David I.

doi:10.1680/geot.2002.52.6.435

Cited by 33 publications

(22 citation statements)

References 5 publications

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“…Consequently, 3DEC allows geotechnical or construction problems to be solved by a mixed discrete-continuum approach [13]. In the past, this code was used to get more insight into the behavior of plane DSRWs where pathologies observed on site and the behavior of specific DSRWs toward failure could have been reproduced [7,9,10,14].…”

Section: Basic Aspects About 3decmentioning

confidence: 99%

“…Harkness [7] modeled Burgoyne's field experiments using UDEC code (DEM, ITASCA code) [8], confirming the qualitative results Burgoyne obtained. Also based on Burgoyne's tests, Powrie et al [9] and later Claxton et al [10], performed numerical simulations, studying the influence of the mechanical properties and geometry of blocks on the wall stability. Recently, Oetomo et al [11] modeled the behavior of slope DSRWs by two methods.…”

Section: Introductionmentioning

confidence: 99%

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3D failure of a scale-down dry stone retaining wall: A DEM modelling

Quezada

Vincens

Mouterde

et al. 2016

Engineering Structures

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Dry stone retaining walls are vernacular structures that can be found in many places around the world and were mainly built to reduce slope erosion and to allow agricultural practices. Their stability is essentially warranted by the global wall weight and the capacity of individual blocks to develop friction at contact. The arrangement of these hand-placed blocks contributes also to the stability of the wall. A new interest arose in these structures in the last years, first due to the necessity to repair damages inherent to any built heritage, but also to their possible advantages regarding sustainability. Several studies have tried to address the behavior of slope dry stone retaining walls, whereas few conclusive studies have been performed concerning road dry stone retaining walls. In this latter case, the loading implies, apart from the backfill, the existence of a concentrated force on the backfill surface. The failure of such masonry work is accompanied by true three-dimensional deformations. This study is a first attempt to provide a better understanding of the mechanical behavior of road dry stone retaining walls. It involves a small-scale prototype with clay bricks for the wall, and steel blocks, acting as a concentrated loading on the backfill surface at a given distance from the inward wall face. Steel blocks have been superposed until wall failure. A numerical study based on these experiments is then performed by means of a mixed discrete-continuum approach. The numerical model was able to retrieve the average value of the concentrated force triggering failure found in the experiences, except when the concentrated loading is very close to the wall. Nevertheless, the results provided by this study are considered as encouraging even if further work is required to definitely state about the validity of such a numerical technique for the study of actual road dry stone retaining walls.

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Section: Basic Aspects About 3decmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

3D failure of a scale-down dry stone retaining wall: A DEM modelling

Quezada

Vincens

Mouterde

et al. 2016

Engineering Structures

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“…This ultimate loading height, h þ s , is the minimum value of h s over all virtual velocity fields, which verifies equation (2) ( 1, 0, 0) Ϫ Full-scale field trials on drystone retaining walls Aim of experiments. The experimental programmes undertaken in 2002-2003(Villemus, 2004) and 2007-2008(Colas, 2009) at the ENTPE aimed to provide a better understanding of drystone two-dimensional behaviour by way of calibration and validation simulations. Full-scale trials are essential to take into account the strong heterogeneity of drystone masonry, as well as the specificities of soil-structure interaction.…”

Section: Presentation Of Model and Experimental Datamentioning

confidence: 99%

“…Second, when dealing with drystone retaining structures, it is necessary to take into account the backfill and the soil-structure interaction, which means that soil mechanics must be accounted for. Simulations on drystone constructions fall into two categories: (a) macro-mechanical approaches, where the masonry is treated as a continuous medium (Arya & Gupta, 1983;Cooper, 1986;Villemus et al, 2007;Mundell et al, 2009); and (b) micro-mechanical approaches (finite-or distinct-element methods), where the wall is represented as a combination of blocks (Dickens & Walker, 1996;Harkness et al, 2000;Powrie et al, 2002;Zhang et al, 2004;Claxton et al, 2005). In addition, only a few recent experiments have been undertaken on drystone retaining structures (Villemus et al, 2007;Mundell et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Assessing the two-dimensional behaviour of drystone retaining walls by full-scale experiments and yield design simulation

Colas¹,

Morel²,

Garnier³

2013

Géotechnique

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International audienceDrystone walling is a widespread form of construction that utilises local materials. It has received growing interest over the past few years, owing to the recognition of its rich heritage in the framework of sustainable development. However, the growth of dry masonry has been slowed by the lack of scientific evidence proving its reliability. The authors have previously established a model based on yield design to assess drystone wall stability. This theoretical approach has been supplemented by field experiments on full-scale drystone retaining walls that were backfilled until failure with a cohesionless soil. These field experiments followed a first set of experiments in 2002-2003 in which the walls were loaded using hydrostatic pressure. The aim of these experimental programmes was to achieve better understanding of drystone masonry behaviour under loading, and of its failure mode. The present paper consists of a comparative analysis of these theoretical and experimental results, and provides a richer understanding of drystone retaining wall phenomenology. Further perspectives on this work are presented in the conclusion

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“…Indeed, the user has the possibility to glue rigid circular bodies together generating more complex bodies. The approach considered in this work is different from previous numerical studies [9,10,19,20] which coupled a discrete method for blocks and a continuum model for backfill. At each time-step, the calculation runs in alternate between contact-force law and law of motion.…”

Section: Modeling Of Dsrws With a Particle-based Methodsmentioning

confidence: 99%

Modeling the 2D behavior of dry‐stone retaining walls by a fully discrete element method

Oetomo

Vincens

Dedecker

et al. 2015

Num Anal Meth Geomechanics

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Modeling the 2D behavior of drystone retaining walls by a fully discrete element method AbstractThe dry-stone retaining walls (DSRW) have been tipped as a promising solution for sustainable development. However, before recently, their behavior is relatively obscure. In this study, DEM approach was applied to simulate the plane strain failure of these walls. A commercial DEM package (PFC2D TM ) was used throughout this study. The authors used a fully discrete approach, thus both the wall and the backfill were modeled as discrete elements. The methodology for obtaining the micromechanical parameters was discussed in detail; this includes the three mechanical sub-systems of DSRWs: wall, backfill and interface. The models were loaded progressively until failure, and then the results were compared with the full-scale experimental results where the walls were loaded respectively with hydrostatic load and backfill. Despite its complexity and its intensive calculation time, DEM model can then be used to validate a more simplified approach.

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Deformation and failure modes of drystone retaining walls

Cited by 33 publications

References 5 publications

3D failure of a scale-down dry stone retaining wall: A DEM modelling

3D failure of a scale-down dry stone retaining wall: A DEM modelling

Assessing the two-dimensional behaviour of drystone retaining walls by full-scale experiments and yield design simulation

Modeling the 2D behavior of dry‐stone retaining walls by a fully discrete element method

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