SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4313200735> ?p ?o ?g. }

Showing items 1 to 100 of ±160 with 100 items per page.

W4313200735 endingPage "113394" @default.
W4313200735 startingPage "113394" @default.
W4313200735 abstract "The interaction of fluid flow with porous barriers has numerous practical applications, including as a partial barrier to water waves that damp some of the approaching energy at the same time as allowing environmental flow. However, surprisingly little effort has been expended on understanding the fundamentals of this interaction. Therefore, this study aims to model the interaction between waves and thin, upright porous barriers. This is undertaken by modelling the porous barrier empirically within a Smoothed Particle Hydrodynamics (SPH) framework that is then used to model wave flume experiments. Although detailed modelling of the interaction is possible at the laboratory scale, it is not feasible in practical settings where a barrier will contain many thousands of holes that cannot be individually modelled. The key information needed to model the barrier empirically is obtained from solitary wave-porous barrier interaction experiments. Our results indicate that, for each barrier, irrespective of the properties of the wave interacting with it, there is a coefficient value that is able to account adequately for the energy dissipation by the barrier. The reliability of the approach has been demonstrated by comparing SPH model predictions against companion sinusoidal wave-porous barrier experimental measurements. The SPH model was then used to determine the energy dissipation characteristics of porous barriers kept at different draught to water depth ratio, D/d, without reference to the wave flume experiments. Simulation results indicate that barriers are more effective in dissipating the incident wave energy if its draught is over 75% of the water depth." @default.
W4313200735 created "2023-01-06" @default.
W4313200735 creator A5002052300 @default.
W4313200735 creator A5042887539 @default.
W4313200735 creator A5053933755 @default.
W4313200735 creator A5060468191 @default.
W4313200735 creator A5088434014 @default.
W4313200735 date "2023-01-01" @default.
W4313200735 modified "2023-09-26" @default.
W4313200735 title "Solitary wave interaction with upright thin porous barriers" @default.
W4313200735 cites W1590001946 @default.
W4313200735 cites W1614843454 @default.
W4313200735 cites W1884545229 @default.
W4313200735 cites W1968312755 @default.
W4313200735 cites W1969426654 @default.
W4313200735 cites W1969692597 @default.
W4313200735 cites W1976355791 @default.
W4313200735 cites W1983532600 @default.
W4313200735 cites W1983899576 @default.
W4313200735 cites W1988210668 @default.
W4313200735 cites W1992473216 @default.
W4313200735 cites W1998013354 @default.
W4313200735 cites W2003919582 @default.
W4313200735 cites W2004650651 @default.
W4313200735 cites W2008756391 @default.
W4313200735 cites W2009759046 @default.
W4313200735 cites W2014331193 @default.
W4313200735 cites W2021344134 @default.
W4313200735 cites W2021879147 @default.
W4313200735 cites W2023110717 @default.
W4313200735 cites W2026690725 @default.
W4313200735 cites W2029081308 @default.
W4313200735 cites W2032533281 @default.
W4313200735 cites W2038075786 @default.
W4313200735 cites W2044602433 @default.
W4313200735 cites W2045496059 @default.
W4313200735 cites W2048231844 @default.
W4313200735 cites W2048391350 @default.
W4313200735 cites W2050447284 @default.
W4313200735 cites W2055537761 @default.
W4313200735 cites W2058962280 @default.
W4313200735 cites W2060029222 @default.
W4313200735 cites W2060742411 @default.
W4313200735 cites W2067434894 @default.
W4313200735 cites W2067870561 @default.
W4313200735 cites W2068016711 @default.
W4313200735 cites W2068807478 @default.
W4313200735 cites W2069004507 @default.
W4313200735 cites W2074967074 @default.
W4313200735 cites W2074999229 @default.
W4313200735 cites W2078383438 @default.
W4313200735 cites W2080977367 @default.
W4313200735 cites W2083512910 @default.
W4313200735 cites W2087679439 @default.
W4313200735 cites W2089263433 @default.
W4313200735 cites W2089809682 @default.
W4313200735 cites W2096337795 @default.
W4313200735 cites W2096852287 @default.
W4313200735 cites W2097474733 @default.
W4313200735 cites W2126233578 @default.
W4313200735 cites W2127689830 @default.
W4313200735 cites W2133905337 @default.
W4313200735 cites W2144210776 @default.
W4313200735 cites W2154549660 @default.
W4313200735 cites W2154683067 @default.
W4313200735 cites W2168414272 @default.
W4313200735 cites W2313906780 @default.
W4313200735 cites W2556900048 @default.
W4313200735 cites W2592330503 @default.
W4313200735 cites W2594687149 @default.
W4313200735 cites W2793211699 @default.
W4313200735 cites W2799515350 @default.
W4313200735 cites W2801979098 @default.
W4313200735 cites W2914127677 @default.
W4313200735 cites W2936876450 @default.
W4313200735 cites W2982680084 @default.
W4313200735 cites W2991828613 @default.
W4313200735 cites W3000220776 @default.
W4313200735 cites W3004541953 @default.
W4313200735 cites W3021622851 @default.
W4313200735 cites W3025675505 @default.
W4313200735 cites W3039826368 @default.
W4313200735 cites W3090561989 @default.
W4313200735 cites W3101822069 @default.
W4313200735 cites W3111074424 @default.
W4313200735 cites W3128671705 @default.
W4313200735 cites W3200211908 @default.
W4313200735 cites W3211151384 @default.
W4313200735 cites W3212169797 @default.
W4313200735 cites W332011103 @default.
W4313200735 cites W4213090343 @default.
W4313200735 cites W4256123700 @default.
W4313200735 cites W600393044 @default.
W4313200735 doi "https://doi.org/10.1016/j.oceaneng.2022.113394" @default.
W4313200735 hasPublicationYear "2023" @default.
W4313200735 type Work @default.
W4313200735 citedByCount "1" @default.
W4313200735 countsByYear W43132007352023 @default.