Your search keyword '"Hong-Sheng Zhan"' showing total 2 results

1. Numerical Study of Hydrodynamic Characteristics of a Three-Dimensional Oscillating Water Column Wave-Power Device

Author

Jun-Lin Zhu, Peng Tang, Hong-Sheng Zhang, and Peng-Bo Zheng

Subjects

wave energy converter, oscillation, wave force, wave–structure interaction, water waves, Naval architecture. Shipbuilding. Marine engineering, VM1-989, Oceanography, GC1-1581

Abstract

The impact of wave-induced forces on the integrity of stationary oscillating water column (OWC) devices is essential for ensuring their structural safety. In our study, we built a three-dimensional numerical model of an OWC device using the computational fluid dynamics (CFDs) software OpenFOAM-v1912. Subsequently, the hydrodynamic performance of the numerical model is comprehensively validated. Finally, the hydrodynamic performance data are analyzed in detail to obtain meaningful conclusions. Results indicate that the horizontal wave force applied to the OWC device is approximately 6.6 to 7.9 times greater than the vertical wave force, whereas the lateral wave force is relatively small. Both the horizontal and vertical wave forces decrease as the relative water depth increases under a constant wave period and height. In addition, the highest dynamic water pressure is observed at the interface between the water surface and device, both within and outside the front wall of the gas chamber. The dynamic water pressure at different locations on the front chamber increases and subsequently decreases as the wave frequency increases.

Published

2024

2. Numerical simulation of bichromatic wave propagation based on the paddle- and modified mass source wave-maker methods

Author

Zhou-Hao Zhang, Hong-Sheng Zhang, Peng-Bo Zheng, and Min-Yi Chen

Subjects

paddle wave-maker method, modified mass source wave-maker method, bichromatic waves, wave-wave interaction, Fluent software, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

A second-order numerical wave-maker is realized by combining the paddle wave-maker theory proposed by Schäffer for physical experiments with the Fluent software. The numerical results from the paddle wave-maker method are compared with the results from the modified mass source wave-maker method, the theoretical solutions, and the physical experimental data. The numerical model based on the paddle wave-maker method is verified, and the applicable scopes of the two wave-maker methods are discussed. The paddle wave-maker method is not suitable for bichromatic wave combinations that include shallow-water waves. However, within their common applicable range, the numerical results from the paddle wave-maker method are better than those from the modified mass source wave-maker method, at least for the grid divisions adopted in this study. The effects of the incident wave parameters on the nonlinear wave-wave interaction are also analyzed.

Published

2024