基于响应面分析的行波式能量吸收装置的参数优化

doi:10.12677/mos.2024.133224

期刊菜单

基于响应面分析的行波式能量吸收装置的参数优化
Optimization of Traveling-Wave Capability Absorption Parameters Based on Response Surface Analysis

DOI: 10.12677/mos.2024.133224, PDF, 国家自然科学基金支持
作者: 钱嘉斌, 黄典贵：上海理工大学能源与动力工程学院，上海
关键词: 行波式能量吸收；行波运动；数值模拟；响应面分析；Traveling Wave Energy Absorption； Traveling Wave Motion； Numerical Simulation； Response Surface Analysis

摘要: 针对行波式能量吸收装置，其能量吸收效率受多种因素影响。为优化其性能，本研究对单个行波板进行了建模与仿真分析。运用响应面法，以无量纲波幅、无量纲波速及波数为变量，能量吸收效率为响应目标，进行了参数优化设计。结果显示，各因素对能量吸收效率的影响程度依次为：无量纲波幅、无量纲波速、波数。经过响应面优化，得到最优参数组合为无量纲波幅0.111、无量纲波速0.601、波数4.518，此时能量吸收效率可达84.27%。为进一步验证优化参数的有效性，进行了数值模拟对比，结果显示响应面预测值与数值计算值之间的误差仅为0.821%，从而验证了响应面模型在行波式能量吸收装置优化设计中的有效性。

Abstract: For the traveling wave energy absorption device, there are many factors that affect its energy absorption efficiency. To optimize its performance, this study conducted modeling and simulation analysis on a single traveling wave plate. Using the response surface method, the dimensionless wave amplitude, dimensionless wave speed, and wave number were studied as variables, with energy absorption efficiency as the response target for parameter optimization design. The results showed that the impact of each factor on energy absorption efficiency was ranked as follows: dimensionless wave amplitude, dimensionless wave speed, and wave number. After response surface optimization, the optimal parameter combination was obtained with a dimensionless wave amplitude of 0.111, a dimensionless wave speed of 0.601, and a wave number of 4.518, at which point the energy absorption efficiency could reach 84.27%. To further verify the validity of the optimized parameters, a numerical simulation comparison was conducted, which showed that the error between the predicted value of the response surface and the numerical calculation value was only 0.821%, thus verifying the effectiveness of the response surface model in the optimization design of the traveling wave energy absorption device.

文章引用：钱嘉斌, 黄典贵. 基于响应面分析的行波式能量吸收装置的参数优化[J]. 建模与仿真, 2024, 13(3): 2453-2466. https://doi.org/10.12677/mos.2024.133224

参考文献

[1]	Herbert, G.M.J., Iniyan, S. and Sreevalsan, E. (2007) A Review of Wind Energy Technologies. Renewable and Sustainable Energy Reviews, 11, 1117-1145. [Google Scholar] [CrossRef]
[2]	Lighthill, M.J. (1969) Hydromechanics of Aquatic Animal Propulsion. Annual Review of Fluid Mechanics, 1, 413-446. [Google Scholar] [CrossRef]
[3]	Lighthill, M.J. (2006) Dynamics of a Dissociating Gas Part 2. Quasi-Equilibrium Transfer Theory. Journal of Fluid Mechanics, 8, 161-182. [Google Scholar] [CrossRef]
[4]	Wu, Y.T. (2006) Hydromechanics of Swimming Propulsion. Part 1. Swimming of a Two-Dimensional Flexible Plate at Variable Forward Speeds in an Inviscid Fluid. Journal of Fluid Mechanics, 46, 337-355. [Google Scholar] [CrossRef]
[5]	Lighthill, M.J. (1971) Large-Amplitude Elongated-Body Theory of Fish Locomotion. Proceedings of the Royal Society of London, 179, 125-138. [Google Scholar] [CrossRef]
[6]	童秉纲, 庄礼贤. 描述鱼类波状游动的流体力学模型及其应用[J]. 自然杂志, 1998, 20(1): 1-7.
[7]	Cheng, J.-Y., Zhuang, L.-X. and Tong, B.-G. (2006) Analysis of Swimming Three-Dimensional Waving Plates. Journal of Fluid Mechanics, 232, 341-355. [Google Scholar] [CrossRef]
[8]	Gao, L., Qin, H. and Li, P. (2021) Hydrodynamic Analysis of Fish’s Traveling Wave Based on Grid Deformation Technique. International Journal of Offshore and Polar Engineering, 31, 178-185. [Google Scholar] [CrossRef]
[9]	童秉纲, 王安平. 三维波动板加速运动的推进性能研究[J]. 空气动力学学报, 1991, 9(3): 285-293.
[10]	Huang, D. and Zhang, J. (2017) New Method for Harvesting Energy from Fluid Flow Based on Undulatory Motion. International Journal of Green Energy, 14, 540-547. [Google Scholar] [CrossRef]
[11]	Ji, F. and Huang, D. (2017) Effects of Reynolds Number on Energy Extraction Performance of a Two Dimensional Undulatory Flexible Body. Ocean Engineering, 142, 185-193. [Google Scholar] [CrossRef]
[12]	Ding, L., Li, H. and Huang, D. (2019) Parametric Research on Energy Extraction of a Waving Plate with Unequal Amplitude Traveling Wave Motion. Energy Sources Part A: Recovery Utilization and Environmental Effects, 42, 2063-2081. [Google Scholar] [CrossRef]
[13]	林燕, 黄典贵. 不同厚度不同系列波状运动翼型的能量吸收特性[J]. 热能动力工程, 2018, 33(12): 131-140. [Google Scholar] [CrossRef]
[14]	Sun, X., Zhang, J., Li, H., et al. (2019) Parametric Study of an Undulating Plate in a Power-Extraction Regime. Journal of Mechanical Science and Technology, 33, 255-268. [Google Scholar] [CrossRef]
[15]	张继化, 孙晓晶, 黄典贵. 行波波长及波速对获能特性的影响[J]. 能源研究与信息, 2021, 37(1): 46-53.
[16]	Qi, M., Ma, Q. and Huang, D. (2022) Influence of Lengthways Spacing and Phase Difference on Traveling Wave Energy Absorption Characteristics of Flexible Airfoils in a Diamond Array. Renewable Energy, 200, 98-110. [Google Scholar] [CrossRef]
[17]	Shen, L., Zhang, X., Dkp, Y., et al. (2003) Turbulent Flow over a Flexible Wall Undergoing a Streamwise Travelling Wave Motion. Journal of Fluid Mechanics, 484, 197-221. [Google Scholar] [CrossRef]
[18]	Nishio, S. and Nakamura, K. (2002) A Study on the Propulsive Performance of Fish-Like Motion Using Waving Wing Model. Journal of the Society of Naval Architects of Japan, 2002, 17-24. [Google Scholar] [CrossRef]
[19]	Nishio, S., Chen, Z., Doi, Y., et al. (2003) A133 Analysis of Fish-Like Propulsion. Journal of the Visualization Society of Japan, 23, 41-44. [Google Scholar] [CrossRef]

为你推荐

友情链接