Performance assessment of wave equation analysis for driven steel H-piles in IGM

The standard penetration test (SPT) split-spoon sampler is too small for investigations in gravelly soils. For this reason, several researchers have developed scaled-up versions of the SPT, commonly referred to as "large penetration tests" (LPT), and attempted to correlate the measured blow counts to SPT blow counts. Several LPTs have been in use worldwide; each with different drill rods, sampler dimensions, and hammer energies; hence existing published LPTSPT correlations differ for each system. This paper summarizes the LPT data in the literature and presents a fundamental method for predicting LPTSPT correlations. The proposed method is based on wave equation analyses of SPT and LPT and considers variations in test equipment, penetration resistance, and energy. It is shown that the method provides a unified approach for assimilating the various published LPTSPT correlations. Additional SPT and LPT data were collected at a sand research site to check the proposed method and to expand the LPT database. The observed and predicted correlation factors are shown to be in good agreement. The proposed correlation method will be useful as a logical framework for the comparison of LPT data collected throughout the world. Additional research will be required to extend this procedure to gravel sites.Key words: large penetration test, LPT, fundamental correlation method, wave equation analysis, grain size effects.

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Wave Equation Analysis of a Vibratory Hammer-Driven Pile

10.4043/5396-ms ◽

1987 ◽

Cited By ~ 1

Author(s):

K.M. Chua ◽

S. Gardner ◽

L.L. Lowery

Keyword(s):

Wave Equation ◽

Equation Analysis ◽

Driven Pile

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Deformation and Stability Analysis of Ultra-Thin Lubricant Films by the Long Wave Equation: Analysis Considering the van der Waals Force and Gas Pressure at the Liquid Surface

World Tribology Congress III, Volume 1 ◽

10.1115/wtc2005-63629 ◽

2005 ◽

Cited By ~ 2

Author(s):

Shigehisa Fukui ◽

Kazuya Yorino ◽

Kiyomi Yamane ◽

Hiroshige Matsuoka

Keyword(s):

Wave Equation ◽

Liquid Film ◽

Liquid Surface ◽

Thin Liquid Film ◽

Van Der Waals ◽

Wave Theory ◽

Long Wave ◽

Equation Analysis ◽

Vdw Force ◽

Time Evolution Equation

To examine deformations of ultra-thin but continuum liquid film, the long wave theory was employed, which is the time-evolution equation for the shape and deformation of the thin liquid film and includes the surface tension and surface forces such as the van der Waals (vdW) force. By solving the linearized long wave equation considering the vdW pressure and gas pressures at the lubricant surface, deformations of the ultra-thin lubricant film caused by air pressure were obtained. Stability/instability of the liquid surface was analyzed as the growth and decay problem of the infinitesimal deformation of the liquid surface.

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CAPWAP and Refined Wave Equation Analyses for Driveability Predictions and Capacity Assessment of Offshore Pile Installations

Volume 7: Offshore Geotechnics; Petroleum Technology ◽

10.1115/omae2009-80163 ◽

2009 ◽

Cited By ~ 3

Author(s):

Frank Rausche ◽

Matt Nagy ◽

Scott Webster ◽

Liqun Liang

Keyword(s):

Wave Equation ◽

Bearing Capacity ◽

Dynamic Monitoring ◽

Capacity Assessment ◽

Pile Driving ◽

Soil Resistance ◽

Driving Dynamic ◽

Deep Foundation ◽

Driving System ◽

Equation Analysis

Open ended pipe piles have to be driven in the offshore environment primarily as platform support piles or as conductor pipes. In either case, deep penetrations have to be achieved. In preparation of these potentially difficult installations, equipment selection and stress control is done by a predictive wave equation analysis. During pile driving, dynamic monitoring combined with CAPWAP signal matching analysis is a preferred method for bearing capacity assessment. After the fact, if dynamic measurements were not provided during pile driving, a wave equation analysis can again help perform a post-installation analysis for bearing capacity assessment, assuming a variety of parameters. Wave equation analyses require a variety of input parameters describing hammer and driving system performance and the pseudo-static and dynamic behavior of the soil. Measurements taken during the installation yield immediate results about hammer and pile performance. Soil resistance parameters can be extracted by careful signal matching analysis. Unfortunately, the measurement and associated analysis results cannot be used without further modification in the wave equation analysis, because the wave equation approach requires simplifications in hammer, driving system and soil models. Thus, a final step is the so-call Refined Wave Equation Analysis which combines all results obtained and produces a best possible match between measurements and analyses. This paper describes the process of the three analysis phases utilizing typical offshore pile installation records. The paper also gives guide lines for this analysis process as well as a summary of limitations. An important part of the paper includes recommendations for and discussion of the modeling of the soil resistance near the open ended pipe bottom. Finally, the paper discusses how the results should be used for greatest benefit of the deep foundation industry.

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Applications of Wave -Equation Analysis to Offshore Pile Foundations

10.4043/1055-ms ◽

1969 ◽

Author(s):

Carl H. Bender ◽

Charles G. Lyons ◽

Lee L. Lowery

Keyword(s):

Wave Equation ◽

Pile Foundations ◽

Equation Analysis

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Improving the quality of input data for the wave equation analysis of driven piles

Canadian Geotechnical Journal ◽

10.1139/t80-027 ◽

1980 ◽

Vol 17 (2) ◽

pp. 286-291

Author(s):

Silvano Marchetti

Keyword(s):

Wave Equation ◽

Input Data ◽

Driven Piles ◽

Velocity Pulse ◽

Peak Voltage ◽

Equation Analysis ◽

Model Pile ◽

The Impact ◽

Voltage Indicator

This note describes a velocity sensor for monitoring directly the particle velocity of driven piles during the impact. A typical velocity pulse obtained by the sensor mounted on a model pile is shown and commented upon.The sensor coupled to a peak voltage indicator forms a very simple and inexpensive system for measuring the peak pile velocity. A procedure is outlined for using the measured value of the peak pile velocity for improving the quality of the input data for the wave equation analysis.

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