Abstract:
ABSTRACT
Offshore foundations are often subjected to huge environmental
cyclic lateral loads due to ocean waves, current and wind, which could
exceed their capacity, in addition to its fundamental function to
transmit the vertical loads of self-weight of structures into the deep
soil strata. The repetitive nature of such loading with the presence of
vertical loads produces a gradual alteration in the head displacement
and bearing capacity of the piles. This sometimes may produce
catastrophic consequences. A cumulative displacement and bending
moment lead to a problems in the pile foundations represented by
serviceability problem due to the extra displacement of the piles and
failure structurally when the bending moment value reach to the point
of yield. In order to investigate the influence of combined loading on
the pile-soil interaction performance, a cyclic loading system has been
developed. Through this multi-purpose system, lateral sinusoidal
loading could be applied on the head of an instrumented model pile
with strain gauges at various amplitudes and frequencies under stresscontrolled
mode.
A series of 72 laboratory tests are performed to investigate the
single pile response when subjected to combined loads, by illustrating
the variation of horizontal and vertical displacements as well as
bending moment along the pile depth. Moreover, numbers of
parameters are studied, including: cross section shape of the pile
X
(circular and square), slenderness ratio L/D (25 and 40), magnitude
and frequency (0.067, 0.1 and 0.2 Hz) of the cyclic load. All tests are
achieved in dry sand with one relative density (R.D.) 70% (i.e. dense).
One hundred cycles are used1 in each test to represent1 repetitive of
environmental loading on offshore1 structures during the storm wave.
Results obtained from the experimental tests under the
combined load confirm that the lateral displacement and bending
moment along pile decrease with increasing the vertical load level, the
rate of reduction reach to 73 % and 46 % for displacement and
maximum bending moment after 100 cycles respectively. Exactly the
contrary, but it may cause problem with respect to allowable
settlement. For piles under the influence of combined loads regardless
vertical load level, the displacements (vertical and lateral) and bending
moment increase with increasing the magnitude of cyclic load ratio
(CLR), the difference in the rate of increase reaches to 82%. Although
the square and circular pile sections had nearly the same outside
dimensions, the square pile provides lateral deflection that is 12 to 42
% lower than a circular pile for the same amount of cyclic load.
Besides, there is an observable influence of slenderness ratio (L/D)
and frequency on the values of displacements (lateral and vertical) and
bending moment. Most of these values under the effect of the pure
cyclic load are higher than those observed in combined loads for all
frequencies (i.e. 0.067, 0.1 and 0.2 Hz). Furthermore, the increasing in
the number of cycles under the influence of high cyclic lateral loads
and frequency (i.e. 0.2 Hz.) has a greater influence on the behavour of
the pile compared on low cyclic lateral loads and frequencies (i.e.
0.067 and 0.1 Hz).