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Showing 3 results for Random Waves
Ramin Vafaeipour Sorkhabi, Mohammad Ali Lotfollahi-Yaghin, Mohammad H Aminfar,
Volume 2, Issue 8 (1-2012)
Abstract
The wave induced internal forces in the body of a seawall have a random temporal change. Since the incident waves have various periods, studying the behavior of a seawall under the variable wave periods can be considered to be of major importance. In order to investigate the effect of wave period on the produced internal forces, three seawalls have been modeled and analyzed subjected to sea waves. The first model is a vertical seawall, while the second and third ones are inclined seawalls with uniform and dual slopes, respectively. The water depth and wave height have been considered to be fixed during the performed analyses, while different values have been assigned to the wave period, ranging from 0.1 to 3 sec, with the increments of 0.05 sec. In each analyzed model, the maximum values of base shearing force and flexural moment have been extracted from the corresponding time histories of internal forces. A modal analysis has also been performed on each model from which the natural period of the wall’s oscillation has been obtained. The results show that when the wave period is shorter than the structure’s natural period of oscillation, increase of the wave period leads to increase of the base shearing force and flexural moment while under the waves having peak periods longer than the structure’s natural period of oscillation, increase of the period results in the decrease of base internal forces.
Maryam Rahbani, Mehdi Esmaeili, Ali Karami Khaniki,
Volume 8, Issue 31 (10-2017)
Abstract
The aim of present study is to estimate the wave-induced force acting on a vertical rigid, a semi-porous and a porous caisson-type seawalls using physical modeling. For this purpose, random sea waves in wide range of wave heights and periods, with variety of water depth were considered for the experimental test. Comparison of the measured values of maximum wave forces (Fmax) for three walls revealed that the wave-induced forces acting on the semi-porous and porous seawalls were more than the impermeable plane seawall. These increaments were calculated as about 28% and 46%, respectively. The semi-porous and porous seawalls showed better performance in wave energy dissipation and in wave reflection decreases in comparison with the rigid impermeable seawall. In addition, it was found that the Fmax increased with the increase of the wave steepness (Hs/Lp) and the decrease of the relative water depth (d/Lp). Based on the lab measurements and multiple regression analysis, new empirical equations have been proposed to predict the maximum wave force acting on each of the above mentioned seawalls.
Dr Arash Dalili Osgouei, Dr Ramin Vafaei Poursorkhabi, Ahmad Maleki, Dr Hamid Ahmadi,
Volume 10, Issue 40 (1-2020)
Abstract
Abstract
The purpose of this study is to obtain the base shear force and overturning moment of the jacket at the three wave heights of 20, 23 and 28 cm. In this regard, the model of the jacket structure is constructed at a height of 4.55 meters, 402 meters in length and 4 meters in depth of water, exposed to random waves of the sea and is subjected to the JONSWAP spectrum in the flume of Fars National Marine Laboratory (NIMALA). Based on the results obtained, in all examinations, deep water conditions prevail. Considering the effective wave, for the wave height decreases from 28 to 23 cm, 14.17%, 23 to 20 cm, 52.9%, 28 to 20 cm, 74.57%, reduction of the base shear; and for the decrease of wave height reduction from 28 to 23 cm, 33.79%, 23 to 20 cm, 17.06%, 28 to 20 cm, and 56.63%, overturning moment reduction were obvious.
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