基于改进能量包线随机平均法求解窄带谱激励下船舶随机参激横摇响应

doi:10.19423/j.cnki.31-1561/u.2022.04.030

船舶 ›› 2022, Vol. 33 ›› Issue (04): 30-39.DOI: 10.19423/j.cnki.31-1561/u.2022.04.030

基于改进能量包线随机平均法求解窄带谱激励下船舶随机参激横摇响应

刘亚柳, 刘利琴, 刘依伦

天津大学水利工程仿真与安全国家重点实验室天津 300072

收稿日期:2022-05-12 修回日期:2022-05-16 发布日期:2023-03-17
作者简介:刘亚柳（1994-）,女,博士研究生。研究方向：船舶参数激励横摇运动。刘利琴（1977-）,女,博士,教授。研究方向：船舶与海洋工程结构物动力学。刘依伦（1996-）,男,硕士研究生。研究方向：结构物载荷及动力响应。
基金资助:
天津市交委项目（2018-b2）

An Improved Stochastic Averaging Method of Energy Envelope to Solve the Ship Parametric Rolling Response Excited by Narrow-Band Waves

LIU Yaliu, LIU Liqin, LIU Yilun

State Key Laboratory of Hydraulic Engineering Simulation and Safety, Tianjin University, Tianjin 300072, China

Received:2022-05-12 Revised:2022-05-16 Published:2023-03-17

摘要/Abstract

摘要： 国际海事组织（IMO）制定了第二代完整稳性衡准,其中包括参数激励横摇。在第3层直接稳性评估中,研究横摇运动响应和稳性最直接的方法是数值模拟。但由于船舶倾覆是小概率事件,因此解析分析手段依然十分必要。能量包线随机平均法能够准确求解白噪声激励下的随机运动响应,但实际工程中真实的海浪为窄带谱。针对随机平均法求解的适用性研究表明,对于非白噪声激励,要满足系统的阻尼和激励强度足够小、激励带宽足够大的条件。基于以上背景,研究了窄带谱激励下能量包线随机平均法的改进方法。在原有的能量包线随机平均法基础上借鉴标准随机平均法引入相角,保留了原有的能量包线随机平均法可以考虑非线性恢复力的优点,同时放宽了原有方法所要求的理想白噪声激励限制,使其可以为窄带随机激励。求解Fokker-Planck-Kolmogorov（FPK）方程得到的横摇角稳态概率分布与蒙特卡洛法对比良好。改进后的能量包线随机平均法能够准确计算真实海浪激励下船舶随机参数激励横摇响应,对船舶横摇稳性进行评估,为船舶安全航行提供指导。

关键词: 参数激励横摇, 窄带谱, 能量包线随机平均法, FPK方程

Abstract: The International Maritime Organization (IMO) developed the second generation of intact stability criteria, which includes the parametric rolling. In the direct stability assessment, numerical simulation is the most direct method to study the rolling response and stability. However, the analytical analysis method is still necessary because ship capsize is a rare event. The stochastic averaging method of energy envelope can accurately solve the random motion response under the excitation of white noise. However, real waves in the practical engineering correspond to a narrow-band spectrum. The research on the applicability of the stochastic averaging method shows that the system damping and the excitation intensity should be small enough and the excitation bandwidth should be large enough for the non-white noise excitation. An improved method of the stochastic averaging method of energy envelope under the narrow-band spectral excitation is studied based on the above situation. The phase angle is introduced into the original stochastic averaging method of energy envelope by referring to the standard stochastic averaging method. The nonlinear restoring force can be considered, and the limitation of the ideal white noise excitation required by the original method is relaxed to make it possible for the narrow-band excitation. The stationary probability density function (PDF) of the roll angle obtained by solving the Fokker-Planck-Kolmogorov (FPK) equation agrees well with that of the Monte Carlo method. The improved stochastic averaging method of energy envelope can accurately calculate the rolling response of the ship under the excitation of real waves and evaluate the ship roll stability. It can provide guidance for the safe navigation of the ship.

Key words: parametric rolling, narrow-band spectrum, stochastic averaging method of energy envelope, Fokker-Planck-Kolmogorov (FPK) equation

中图分类号:

U661.2⁺2

刘亚柳, 刘利琴, 刘依伦. 基于改进能量包线随机平均法求解窄带谱激励下船舶随机参激横摇响应[J]. 船舶, 2022, 33(04): 30-39.

LIU Yaliu, LIU Liqin, LIU Yilun. An Improved Stochastic Averaging Method of Energy Envelope to Solve the Ship Parametric Rolling Response Excited by Narrow-Band Waves[J]. Ship & Boat, 2022, 33(04): 30-39.

参考文献

[1] 李红霞. 纵浪和斜浪中船舶非线性运动特性研究[D].天津:天津大学, 2008.
[2] ESPARZA I, FALZARANO J.Nonlinear rolling motion of a statically biased ship under the effect of external and parametric excitation[C]// ASME 1993 Design Technical Conferences,1993.
[3] SILVA S, SOARES C G.Prediction of parametric rolling in waves with a time domain non-linear strip theory model[J]. Ocean Engineering,2013(4):453-469.
[4] MATSUDA A, HASHIMOTO H, UMEDA N.Capsizing due to bow-diving in following waves[J]. International Shipbuilding Progress,2004(2): 121-134.
[5] BELENKY V, WEEMS K.Probabilistic properties of parametric roll[J]. Springer New York,2012.
[6] 朱位秋. 随机平均法及其应用[J]. 力学进展,1987(3): 342-352.
[7] ROBERTS J B.Effect of parametric excitation on ship rolling motion in random waves[J]. Journal of Ship Research,1982(4):246-253.
[8] MARUYAMA Y, MAKI A, DOSTAL L, et al.Improved stochastic averaging method using Hamiltonian for parametric rolling in irregular longitudinal waves[J]. Journal of Marine Science and Technology,2022(1):186-202.
[9] DOSTAL L, KREUZER E, NAMACHCHIVAYA N.Non-standard stochastic averaging of large-amplitude ship rolling in random seas[J]. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences,2012(2148):4146-4173.
[10] CHAI W, DOSTAL L, NAESS A, et al.A comparative study of the stochastic averaging method and the path integration method for nonlinear ship roll motion in random beam seas[J]. Journal of Marine Science and Technology,2018(4):854-865.
[11] LIU Y L, LIU L Q, DOSTAL L, et al.The applicability of stochastic averaging method to solve the ship rolling response excited by narrow-band waves[J]. Ocean Engineering,2022,251:111109.
[12] 胡岩国. 改进的能量包线随机平均法与基于积分变换的平均FPK方程精确求解技术[D]. 沈阳:东北大学,2015.
[13] BULIAN G.On an improved Grim effective wave[J]. Ocean Engineering,2008(17-18):1811-1825.
[14] 鲁江,马坤,黄武刚. 规则波中船舶复原力变化计算[J].武汉理工大学学报:交通科学与工程版,2011(5):901-905.
[15] DOSTAL L, KREUZER E. Probabilistic approach to large amplitude ship rolling in random seas[J]. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science1989-1996,2011(10):2464-2476.
[16] WANG L Y, TANG Y G, LI Y, et al.Studies on stochastic parametric roll of ship with stochastic averaging method[J]. China Ocean Engineering,2020(2):10.
[17] 徐明. 碰振/滞迟随机系统的响应与可靠性研究[D]. 杭州:浙江大学,2013.

编辑推荐

Metrics

联系电话：（021）63161688-105006
传真：（021）63151255
E-mail：chuanbo@maric.com.cn

基于改进能量包线随机平均法求解窄带谱激励下船舶随机参激横摇响应

An Improved Stochastic Averaging Method of Energy Envelope to Solve the Ship Parametric Rolling Response Excited by Narrow-Band Waves

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 13

编辑推荐

Metrics

[1]	徐佳. 客滚船的破舱稳性计算[J]. 船舶, 2022, 33(02): 29-35.
[2]	刘震, 何进辉, 封培元, 张海彬, 周耀华. 钻井船参数横摇和过度加速度薄弱性衡准实船验证分析研究[J]. 船舶, 2021, 32(06): 9-15.
[3]	王宇飞, 吴睿锋, 朱韬. 水面舰船初稳性高指标要求研究[J]. 船舶, 2020, 31(04): 11-14.
[4]	初绍伟. 三维物探船稳性优化设计[J]. 船舶, 2020, 31(02): 9-14.
[5]	章泉, 王朝. 25 m沿海高速客船破损稳性分析[J]. 船舶, 2022, 33(01): 57-65.
[6]	曲德才, 于立伟, 王树青, 马宁. 基于直接计数法的船舶横甩发生概率估计探究[J]. 船舶, 2022, 33(04): 40-54.
[7]	叶沈阳, 陈思源, 何适, 张宝吉. 考虑波浪漂移力的渔船骑浪/横甩计算和临界区域规避[J]. 船舶, 2022, 33(04): 55-62.
[8]	祁江涛, 鲁江. 尾斜浪中纯稳性丧失直接评估方法研究[J]. 船舶, 2022, 33(04): 63-74.
[9]	许桑铭, 黄志云, 高志亮. 破损船舶横摇水动力系数特性及插值方法研究[J]. 船舶, 2022, 33(04): 75-81.
[10]	段菲, 马宁, 顾解忡, 周耀华. 带月池船舶的过度加速度失效模式衡准适用性研究[J]. 船舶, 2022, 33(04): 88-97.
[11]	王永功, 刘颜硕, 李红霞. 风浪联合作用下翼型风帆助推船舶稳性分析[J]. 船舶, 2022, 33(04): 98-104.
[12]	刘永涛, 封培元. 波浪中接驳小艇船体和浮冰块的耦合动力学特性数值研究[J]. 船舶, 2022, 33(04): 105-115.
[13]	刘义, 夏召丹, 汤雅敏, 张杰杰, 范佘明. 基于陀螺减摇装置的船舶横摇减摇研究[J]. 船舶, 2022, 33(04): 124-131.