Estimating soil/pile set-up
File(s)
Date
2003-09Author
Wagner, Alan
Edil, Tuncer
Komurka, Van
Publisher
Wisconsin Highway Research Program
Metadata
Show full item recordAbstract
Abstract
Soil/pile set-up is time-dependent increase in pile capacity, and can contribute significantly to long-term pile
capacity. If it were possible to incorporate the effects of set-up during design, it may be possible to reduce pile
lengths, reduce pile sections (use smaller-diameter or thinner-wall pipe piles, or smaller-section H-piles), or
reduce the size of driving equipment (use smaller hammers and/or cranes). Any one, or a combination, of these
reductions should result in cost savings. Accordingly, this research investigated, through a thorough review of
the literature and the state of the practice, if it is possible and practical to estimate set-up during design, using
information obtained during a relative routine subsurface exploration program. A literature search was
conducted; a references list is provided.
Set-up is predominately associated with an increase in shaft resistance. The complete mechanisms contributing
to set-up are not well understood, but the majority of set-up is likely related primarily to dissipation of excess
porewater pressures within, and subsequent remolding and reconsolidation of soil, which is displaced and
disturbed during pile driving. After excess porewater pressures have dissipated, aging may account for
additional set-up. A number of empirical relationships have been proposed to estimate or predict set-up, and
have demonstrated reasonable success in a number of studies. Empirical relationships are limited in
widespread application by the relationships having been based on combined (shaft and toe) resistance
determinations, inter-dependence of back-calculated or assumed variables, and the complexity of the
mechanisms contributing to set-up.
A number of exploration-phase field tests offering potential value in predicting set-up have been identified: SPTTorque
test, SPT-Uplift test, piezocone testing, dilatometer testing, and vane shear testing. Of these, the SPTTorque
test appears to offer the most-favorable combination of applicability of results, ease and simplicity of
performing the test, and cost. It is recommended that SPT-Torque testing be performed on a number of sites
where satisfactory set-up data is available to determine if a meaningful relationship exists between the ?set-up?
which develops on a split-barrel sampler, and the set-up which develops on a driven pile, in various soil strata. If
a meaningful relationship is determined, SPT-Torque tests could be added to routine subsurface exploration
programs to measure sampler/soil set-up in various soil strata, and predict production pile set-up.
Subject
Pile driving
Torque
Shafts (Machinery)
Field tests
Pile foundations
Estimating
Piles (Supports)
Pore water pressures
Permanent Link
http://digital.library.wisc.edu/1793/6881Type
Technical Report
Description
58 p.