Showing 2 results for Karimpour-Fard
A. Eslami, I. Tajvidi, M. Karimpour-Fard,
Volume 12, Issue 1 (Transaction B: Geotechnical Engineering, January 2014)
Abstract
Three common approaches to determine the axial pile capacity based on static analysis and in-situ tests are presented,
compared and evaluated. The Unified Pile Design (UPD), American Petroleum Institute (API) and a SPT based methods were
chosen to be validated. The API is a common method to estimate the axial bearing capacity of piles in marine environments,
where as the others are currently used by geotechnical engineers. Seventy pile load test records performed in the northern
bank of Persian Gulf with SPT profile have been compiled for methods evaluation. In all cases, pile capacities were measured
using full scale static compression and/or pull out loading tests. As the loading tests in some cases were in the format of proof
test without reaching the plunging or ultimate bearing capacity, for interpretation the results, offset limit load criteria was
employed. Three statistical and probability based approaches in the form of a systematic ranking, called Rank Index, RI, were
utilized to evaluate the performance of predictive methods. Wasted Capacity Index (WCI) concept was also applied to validate
the efficiency of current methods. The evaluations revealed that among these three predictive methods, the UPD is more
accurate and cost effective than the others.
Sandro Machado, Mehran Karimpour-Fard, Miriam Carvalho, Orencio Villar, Atila Caldas,
Volume 12, Issue 3 (Transaction B: Geotechnical Engineering, July 2014)
Abstract
Municipal Solid Waste (MSW) materials are among the most complicated materials for geotechnical engineering as their composition includes an organic fraction, which suffers loss of mass over time, and a fibrous part, which acts as reinforcement, governing the MSW shear behavior. Because of these characteristics MSW can be described as a viscous material which shows time dependent behavior. Since the decomposition of MSW leads to gas and leachate generation, the changes in the MSW’s mechanical behavior could be linked to gas emission and leachate production from landfills. This paper deals with the characteristics of MSW materials to provide the necessary data for efficient and safe landfill design, construction and operation. The MSW physical characteristics such as composition, water content and organic content at varying ages, field and laboratory measurements of methane generation and leachate production, MSW compressibility behavior and its shear strength are covered. By presenting these data the authors hope to promote a better understanding of the mechanical behavior of MSW and provide useful data for use in landfill management tasks.