INCREASING THE CARRYING CAPACITY OF REINFORCED CONCRETE DRIVEN PILES BY CHANGING THEIR CROSS SECTIONAL GEOMETRY
AbstractThe ultimate carrying capacity of a reinforced concrete driven pile is mainly obtained by calculating the product of its surface area multiplied by the adhesion stress between its shaft and the surrounding soil. For a certain type of soil its average frictional stress with concrete surfaces is taken equal to its value at mid depth of the pile. The surface area of a pile is the product of its cross sectional circumference multiplied by its length. Through this study it was shown that the circumference of a circular cross section is less by 13% compared to the circumference of an equivalent area square section. A suggested star cross section has been investigated; it was shown that it has an increase of 25% in its circumference compared to a square cross section having a similar area. By adapting the suggested star shape cross section driven pile, it is believed that its carrying capacity will be more than that of a square cross section pile by 25%. In other words; to develop the same required carrying capacity of a group of piles, the suggested star shape cross section driven piles can be driven to four fifths of the required depth of the current similar area square cross sectional piles.
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How to Cite
Darwish, A. M. (2014). INCREASING THE CARRYING CAPACITY OF REINFORCED CONCRETE DRIVEN PILES BY CHANGING THEIR CROSS SECTIONAL GEOMETRY. European Scientific Journal, ESJ, 9(10). https://doi.org/10.19044/esj.2013.v9n10p%p