High-fidelity CFD simulation of wave run-up for single/multiple surface-piercing cylinders in regular head waves
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- 作者:Sung-Hwan Yoon1 ; Dong-Hwan Kim1 ; Hamid Sadat-Hosseini ; Jianming Yang ; Frederick Stern ; frederick-stern@uiowa.edu" class="auth_mail" title="E-mail the corresponding author
- 关键词:CFD ; Run-up ; Wave diffraction ; Vortex shedding
- 刊名:Applied Ocean Research
- 出版年:2016
- 出版时间:September 2016
- 年:2016
- 卷:59
- 期:Complete
- 页码:687-708
- 全文大小:7332 K
文摘
The capabilities of CFDShip-Iowa V4.5 and V6.2 simulations for wave run-up for single/multiple surface-piercing cylinders in regular waves are assessed in conjunction with the ITTC OEC Workshop on VIV and Wave Run-up held in Nantes, France October 17⿿18, 2013. Statistical convergence and grid/domain/turbulence model sensitivity studies show uncertainty UI values are less than 1% for both the experiment/simulation data and grid/domain/turbulence model sensitivities are less than the facility bias UFB. Simulations are qualitatively validated using UFB and error E between experiment and simulation. Errors for single/four cylinder(s) are comparable with UFB and average error 
for the other CFD data of the workshop participants. Results from both V4.5 and V6.2 agree well with experiment and also show capabilities to apply for complex/large-scale problem and to describe detailed wave breaking/spraying for V4.5 and V6.2, respectively. Study on run-up profile shows mean wave elevations are similar to free surface elevations for a cylinder in a steady current. For wave steepness/wave length effect, 2nd to 1st harmonic ratio on the cylinder weather face decreases with steepness for short wave, but increases for long wave. Wave diffraction analysis shows that 2nd/3rd to 1st harmonic ratio in diffracted wave contour reach up to 18⿿41%/9⿿16% respectively. Due to interaction between cylinders, crest/trough heights increase 5⿿17%/4⿿10% for 4C, respectively. Study on vortex shedding shows short wave has insufficient time to develop periodic vortex shedding compared to long wave.
for the other CFD data of the workshop participants. Results from both V4.5 and V6.2 agree well with experiment and also show capabilities to apply for complex/large-scale problem and to describe detailed wave breaking/spraying for V4.5 and V6.2, respectively. Study on run-up profile shows mean wave elevations are similar to free surface elevations for a cylinder in a steady current. For wave steepness/wave length effect, 2nd to 1st harmonic ratio on the cylinder weather face decreases with steepness for short wave, but increases for long wave. Wave diffraction analysis shows that 2nd/3rd to 1st harmonic ratio in diffracted wave contour reach up to 18⿿41%/9⿿16% respectively. Due to interaction between cylinders, crest/trough heights increase 5⿿17%/4⿿10% for 4C, respectively. Study on vortex shedding shows short wave has insufficient time to develop periodic vortex shedding compared to long wave.