TY - JOUR AU - Mohammad Bana, AU - Moussa S. Elbisy , AU - Turki M. Alaboud, PY - 2021/12/30 Y2 - 2024/03/28 TI - WAVE INTERACTIONS WITH TRIPLE SUBMERGED JARLAN-TYPE PERFORATED BREAKWATERS JF - GEOMATE Journal JA - INTERNATIONAL JOURNAL OF GEOMATE VL - 21 IS - 88 SE - Articles DO - UR - https://geomatejournal.com/geomate/article/view/3119 SP - 1-11 AB - <p>This study examines wave interactions with triple submerged Jarlan-type perforated breakwaters consisting of two perforated front walls and a solid rear wall. A mathematical model based on an eigenfunction expansion method and a least-squares technique for Stokes second-order waves has been developed. The numerical results obtained for limiting cases for the single solid and single perforated breakwater, double submerged solid vertical plates, single solid and double perforated breakwater, and double Jarlan-type perforated breakwater are in agree reasonably well with previous studies and experimental results. The wave transmission <em>C<sub>T</sub></em>; reflection <em>C<sub>R</sub></em>, and energy-loss <em>C<sub>L</sub></em> coefficients, and the horizontal wave force exerted on the front <em>C<sub>Ff</sub></em> and rear <em>C<sub>Fr</sub></em> walls are examined. The results indicate that the location of the middle wall between the front and rear walls has little effect on <em>C<sub>R</sub></em>, <em>C<sub>T</sub></em>, and <em>C<sub>L</sub></em>. With the increasing value of porous effect parameter <em>G</em>, the values of <em>C<sub>R</sub></em>, <em>C<sub>T</sub></em>, and <em>C<sub>Fr</sub></em> first decreased, attained their minimum values, and then increased. However, the <em>C<sub>Ff</sub> </em>decreased monotonously with the increasing <em>G</em>. The <em>C<sub>R</sub></em> is maximum when <em>B/L</em> = 0.48<em>n</em>+0.07 while it is minimum when relative chamber width, <em>B/L</em> = 0.46<em>n</em>+0.26 where <em>n</em> equals to (0, 1, 2,...). It also shows that the triple sub-merged Jarlan-type perforated breakwater significantly reduced <em>C<sub>R</sub></em> values and enhanced the structure’s wave-absorbing ability compared with the double one. The optimum parameters recommended for engineering design were <em>G</em> = 0.1–0.2, relative sub-merged depth <em>d/h</em> = 0.1–0.2, and <em>B/L</em> = 0.3–0.4. For practical engineering, the proposed model can be used to predict the structure's response during the preliminary design stage.</p> ER -