Effects of Fines Content on Hydraulic Conductivity and Shear Strength of Granular Structural Backfill

For cast-in-place abutments and retaining walls, structural backfill is preferred to be free-draining, which generally implies less than 5% fines content. This fines content is expected to eliminate the need to design for hydrostatic pressures. The availability of high-quality structural backfill wi...

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Veröffentlicht in:	Transportation research record 2014-01, Vol.2462 (1), p.1-6
Hauptverfasser:	Gomez, Brian W., Dewoolkar, Mandar M., Lens, John E., Benda, Christopher C.
Format:	Artikel
Sprache:	eng
Schlagworte:	Backfill Confining Density Fluid dynamics Fluid flow Hydraulics Hydrostatic pressure Retaining walls Shear strength
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container_title	Transportation research record
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creator	Gomez, Brian W. Dewoolkar, Mandar M. Lens, John E. Benda, Christopher C.
description	For cast-in-place abutments and retaining walls, structural backfill is preferred to be free-draining, which generally implies less than 5% fines content. This fines content is expected to eliminate the need to design for hydrostatic pressures. The availability of high-quality structural backfill with naturally low fines content is declining. This situation warrants an evaluation of whether granular backfill materials with greater than 5% fines content could be successfully used in practice. Flexible wall, hydraulic conductivity tests on a granular structural backfill with 0%, 5%, 10%, 15%, 20%, and 25% nonplastic fines content were conducted at 41, 83, and 124 kPa (6, 12, and 18 psi) confining pressures followed by consolidated drained triaxial compression tests for obtaining associated drained shear strength parameters of these gradations. The 15.2-cm (6-in.) diameter specimens were prepared at optimum moisture content and 95% of maximum standard Proctor density. To enable a comparison with respect to modified Proctor maximum densities, modified Proctor tests were also performed for all base soil–fines content mixtures. The experimental results were compared with relevant studies found in the literature. This research indicates that a nonplastic fines content up to 10% may be justified in structural backfill specifications for retaining walls and abutments.
doi_str_mv	10.3141/2462-01
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subjects	Backfill Confining Density Fluid dynamics Fluid flow Hydraulics Hydrostatic pressure Retaining walls Shear strength
title	Effects of Fines Content on Hydraulic Conductivity and Shear Strength of Granular Structural Backfill
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