Experimental and numerical investigation of the uplift capacity of plate anchors in geocell-reinforced sand

Experimental and numerical investigation of the uplift capacity of plate anchors in geocell-reinforced sand

Plate anchors are frequently used to provide resistance against uplift forces. This paper describes the reinforcing effects of a geocell-reinforced soil layer on uplift behavior of anchor plates. The uplift tests were conducted in a test pit at near full-scale on anchor plates with widths between 15...

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Bibliographic Details
Published in:Geotextiles and geomembranes Vol. 46; no. 6; pp. 801 - 816
Main Authors: Rahimi, M., Moghaddas Tafreshi, S.N., Leshchinsky, B., Dawson, A.R.
Format: Journal Article
Language:English
Published: Essex Elsevier Ltd 01-12-2018
Elsevier BV
Subjects:
Anchors
Backfill
Experiments
Geocell layer
Geosynthetics
Geotechnical fabrics
Mathematical models
Numerical analysis
Peak load
Plate anchor
Reinforcement
Residual stress
Sand & gravel
Soil layers
Stress concentration
Stress distribution
Uplift
Uplift load
Uplift resistance
Upward displacements
Upward displacements
Geosynthetics
Plate anchor
Geocell layer
Numerical analysis
Uplift load
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Summary:Plate anchors are frequently used to provide resistance against uplift forces. This paper describes the reinforcing effects of a geocell-reinforced soil layer on uplift behavior of anchor plates. The uplift tests were conducted in a test pit at near full-scale on anchor plates with widths between 150 and 300 mm with embedment depths of 1.5–3 times the anchor width for both unreinforced and geocell-reinforced backfill. A single geocell layer with pocket size 110 mm × 110 mm and height 100 mm, fabricated from non-perforated and nonwoven geotextile, was used. The results show that the peak and residual uplift capacities of anchor models were highest when the geocell layer over the anchor was used, but with increasing anchor size and embedment depth, the benefit of the geocell reinforcement deceases. Peak loads between 130% and 155% of unreinforced conditions were observed when geocell reinforcement was present. Residual loading increased from 75% to 225% that of the unreinforced scenario. The reinforced anchor system could undergo larger upward displacements before peak loading occurred. These improvements may be attributed to the geocell reinforcement distributing stress to a wider area than the unreinforced case during uplift. The breakout factor increases with embedment depth and decreased with increasing anchor width for both unreinforced and reinforced conditions, the latter yielding larger breakout factors. Calibrated numerical modelling demonstrated favorable agreement with experimental observations, providing insight into detailed behavior of the system. For example, surface heave decreased by over 80% when geocell was present because of a much more efficient stress distribution imparted by the presence of the geocell layer.
ISSN:0266-1144
1879-3584
DOI:10.1016/j.geotexmem.2018.07.010