Hydroelastic wake on a thin elastic sheet floating on water

被引：5

作者：

Ono-dit-Biot, Jean-Christophe ^{[1
]}

Trejo, Miguel ^{[2
]}

Loukiantcheko, Elsie ^{[1
]}

Lauch, Max ^{[1
]}

Raphael, Elie ^{[2
]}

Dalnoki-Veress, Kari ^{[1
,2
]}

Salez, Thomas ^{[3
,4
]}

机构：

[1] McMaster Univ, Dept Phys & Astron, 1280 Main St West, Hamilton, ON L8S 4M1, Canada

[2] PSL Res Univ, ESPCI Paris, UMR CNRS Gulliver 7083, F-75005 Paris, France

[3] Univ Bordeaux, CNRS, LOMA, UMR 5798, F-33405 Talence, France

[4] Hokkaido Univ, Global Inst Collaborat Res & Educ, Global Stn Soft Matter, Sapporo, Hokkaido 0600808, Japan

来源：

PHYSICAL REVIEW FLUIDS | 2019年 / 4卷 / 01期

关键词：

STEADILY MOVING SOURCE; ICE-SHEET; WAVES; FLUID; GRAVITY;

D O I：

10.1103/PhysRevFluids.4.014808

中图分类号：

O35 [流体力学]; O53 [等离子体物理学];

学科分类号：

070204 ; 080103 ; 080704 ;

摘要：

We investigate the hydroelastic waves created by a perturbation moving at constant speed along a thin elastic sheet floating at the surface of deep water. Using a high-resolution cross-correlation imaging technique, we characterize the waves as a function of the perturbation speed, for different sheet thicknesses. The general theoretical expression for the dispersion relation of hydroelastic waves includes three components: gravity, bending, and tension. The bending modulus and the tension in the sheet are independently measured. The experiments represent a direct test of the theory where all components, bending, stretching, and gravity, cannot be neglected. Excellent agreement is found between the experimental data and the theoretical expression.

引用

页数：14

共 50 条

[31] Hydroelastic analysis of water impact of flexible asymmetric wedge with an oblique speed [J].

Izadi, Mohammad ;

Ghadimi, Parviz ;

Fadavi, Manouchehr ;

Tavakoli, Sasan .

MECCANICA, 2018, 53 (10) :2585-2617

[32] Steady-state response of an infinite, free floating ice sheet to a moving load at constant velocity [J].

Qiu, J. ;

Wang, Z. Q. .

OCEAN ENGINEERING, 2024, 314

[33] Hydroelastic analysis of VLFS integrated with porous floating box breakwater using multi-domain boundary element method [J].

Hemanth, S. ;

Karmakar, D. .

MARINE STRUCTURES, 2025, 101

[34] Moving Particle Semi-implicit method coupled with Finite Element Method for hydroelastic responses of floating structures in waves [J].

Zhang, Guanyu ;

Zhao, Weiwen ;

Wan, Decheng .

EUROPEAN JOURNAL OF MECHANICS B-FLUIDS, 2022, 95 :63-82

[35] Hydroelastic analysis of surface piercing hydrofoil during initial water entry phase [J].

Javanmardi, N. ;

Ghadimi, P. .

SCIENTIA IRANICA, 2019, 26 (01) :295-310

[36] Dynamics of a thin elastic coating [J].

Ege, Nihal ;

Erbas, Baris ;

Kaplunov, Julius ;

Yucel, Hazel .

INTERNATIONAL JOURNAL OF ENGINEERING SCIENCE, 2025, 209

[37] Finite element-Multi-domain boundary element method for hydroelastic analysis of large floating pontoons with perforated plates [J].

Nguyen, H. P. ;

Wang, C. M. .

OCEAN ENGINEERING, 2022, 246

[38] Quantitative analysis of hydroelastic characters for one segment of hull structure entering into water [J].

Xie, Hang ;

Ren, Huilong ;

Li, Hui ;

Tao, Kaidong .

OCEAN ENGINEERING, 2019, 173 :469-490

[39] Hydroelastic slamming of flexible wedges: Modeling and experiments from water entry to exit [J].

Shams, Adel ;

Zhao, Sam ;

Porfiri, Maurizio .

PHYSICS OF FLUIDS, 2017, 29 (03)

[40] Viscous Control of Peeling an Elastic Sheet by Bending and Pulling [J].

Lister, John R. ;

Peng, Gunnar G. ;

Neufeld, Jerome A. .

PHYSICAL REVIEW LETTERS, 2013, 111 (15)

← 1 2 3 4 5 →