基于船波相对运动的砰击压力和上浪载荷预报方法

本文基于船波相对运动理论,对舷侧砰击压力和甲板上浪载荷的数值及试验预报方法分别进行了研究.利用三维势流理论计算船舶与波浪之间的相对运动,可以得到船波相对速度及甲板上浪高度.对于砰击压力通过数值模拟方法得到砰击压力系数后结合船波相对速度来预报;对于上浪载荷则采用考虑船舶航速的溃坝模型结合甲板上浪高度来预报.此外,开展了船舶运动和砰击压力模型试验,船波相对运动由沿着模型横剖面布置在舷侧的浪高仪测量,并且测得了相应位置处的砰击压力.最后分别对船波相对运动和砰击压力的数值结果与试验数据进行了比较分析,同时基于船波相对运动给出了一种砰击持续时间计算方法.     

基于船波相对运动的船艏砰击仿真方法

在分析船波相对运动表达式的基础上计算船艏典型剖面的船波相对运动,探讨船艏入水过程中的砰击问题,对比船体某剖面3种入水仿真模型计算所得的砰击载荷,讨论三维外形和航行速度对船艏剖面砰击外载荷的影响。在该分析中,船体在规则波浪中的运动用基于三维势流理论的水动力软件AQWA计算获得,船波相对运动通过理论推导计算获得,用对船艏结构施加强迫运动的方式模拟船波相对运动的真实过程。采用An sys/Ls-Dyna软件的流固耦合分析进行入水仿真,流体划分为ALE体积网格,船艏视为刚体,划分为Lagrange有限元网格。对比结果表明：在三维模型中,相邻剖面引起剖面最大压力点处的液面变化对该点的砰击压力有增大效果,航速有增大剖面砰击压力的作用,减小船艏底部纵向斜升角有利于降低砰击压力。     

基于船波相对运动的船艏砰击仿真方法

在分析船波相对运动表达式的基础上计算船艏典型剖面的船波相对运动,探讨船艏入水过程中的砰击问题,对比船体某剖面3种入水仿真模型计算所得的砰击载荷,讨论三维外形和航行速度对船艏剖面砰击外载荷的影响。在该分析中,船体在规则波浪中的运动用基于三维势流理论的水动力软件AQWA计算获得,船波相对运动通过理论推导计算获得,用对船艏结构施加强迫运动的方式模拟船波相对运动的真实过程。采用An—sys／Ls—Dyna软件的流固耦合分析进行入水仿真,流体划分为ALE体积网格,船艏视为刚体,划分为Lagrange有限元网格。对比结果表明：在三维模型中,相邻剖面引起剖面最大压力点处的液面变化对该点的砰击压力有增大效果,航速有增大剖面砰击压力的作用,减小船艏底部纵向斜升角有利于降低砰击压力。     

船舶砰击强度计算方法研究

船舶在航行时发生砰击是一种高度非线性的物理现象。本文基于势流理论Rankine源法,研究用时域非线性方法计算船舶运动响应,获得船波垂向相对运动速度;并选取合适的砰击压力系数,计算船舶砰击载荷。最后用该方法评估了一艘集装箱船艏部砰击强度,验证了该方法的合理性。     

客滚船首尾部砰击计算研究

客滚船的特殊线型——艏部外飘幅度较大和艉部的扁平肥大型结构,在营运过程中易受到砰击载荷的作用。由于该类船舶砰击问题显著,故一直是业内研究的热点。以某客滚船为例,针对其艏艉结构进行砰击计算,采用计算量适中,且可实现砰击载荷预报的频域法,将砰击载荷映射到相应各部分的有限元计算模型上,经计算分析,得到艏艉结构在砰击压力下的应力结果,最终实现对客滚船砰击强度的安全评估。整个计算探讨过程,可供同类船舶的设计研究人员借鉴。     

船首外飘砰击设计载荷直接计算

文章结合三维线性势流理论和砰击速度的长期分析方法,求解出船体外飘位置的设计砰击速度;以首垂线和静水面交点处的设计砰击速度为目标值,给出了用于确定船首外飘砰击设计载荷的等效设计波,进而得到了设计状态下船体外飘剖面与波面相对运动关系;将船体剖面与波面间的相对运动关系等效转化为船体剖面与静水面的相对运动,利用显式有限元方法实现了外飘剖面砰击设计载荷的预报。针对直接计算方法中涉及的设计砰击速度、砰击压力和砰击压力系数,对比分析了文中结果和相应的规范值或试验值,论证了文中船舶外飘砰击压力设计载荷直接计算方法的合理性。     

江海直达船艏部结构入水砰击试验

新一代江海直达船主要呈宽扁型且吃水较浅,由江入海航行时会发生船艏底部和外飘砰击,严重的砰击会造成船舶主动失速甚至结构损伤,影响船舶与人员安全。传统的理论和相关经验公式很难预报宽扁肥大的艏部结构的砰击载荷。相较于传统的简化模型试验方法,本文基于相似理论设计了与某新型江海直达船艏部结构相似的三维木质模型。采用落水试验的方法进行了一系列的不同落水高度及不同入水角度的入水砰击试验。研究江海直达船艏部结构所受砰击载荷特点,得到砰击压力峰值及其分布规律,同时发现了小角度入水情况下(入水攻角α5°)的空气垫效应,空气垫延缓并减小了砰击压力峰值。此外还回归了0°~15°入水攻角下的底部砰击压力预报公式,可供结构设计时参考砰击载荷的选取。     

大型集装箱船舷侧外飘砰击特性研究

基于概率随机理论研究大型集装箱船舷侧外飘砰击特性,预报不同海况和航速情况下船舶非线性运动响应时历,采用Chuang理论计算船艏舷侧区域的外飘砰击压力,对随机海浪下集装箱船外飘砰击概率、砰击压力极值沿船长和高度方向空间分布规律进行分析,在直接预报的基础上给出载荷的确定方法。     

Ro-Ro船首门砰击载荷设计值的确定

本文结合非线性切片理论与Stavovy-Chuang砰击理论，给出了一种预报船舶艏部砰击压力的方法，并就某Ro-Ro船的水池模型试验结果与理论预报结果进行了比较。证实了方法的可靠性；结合砰击压力的作用特点，提出了Ro-Ro型船艏部砰击压力设计值的直接设计计算方法。并与有关国内外规范设计值进行了比较和分析，给出了可用于指导首门局部结构设计的设计压力值。     

砰击载荷作用下船艏结构瞬态响应研究

砰击现象对高速舰船艏部局部结构破坏相当严重,对舰船和人员的安全构成较大威胁,然而由于砰击载荷的瞬态性和强非线性,其计算理论还很不成熟,舰船艏部结构在砰击作用下的应力响应更鲜有人研究。基于此,利用设计波下确定的砰击压力极值,结合以往试验测定的砰击压力随时间的变化关系,计算得到砰击压力的时空分布,然后将其施加在船艏精细有限元模型上,利用中心差分法进行数值计算,并对计算中一些关键参数的设置值做不同尝试,得到了较理想的艏部结构应力响应历程。     

Efficient calculation of slamming pressures on ships in irregular seas

An efficient method for calculation of the slamming pressures on ship hulls in irregular waves is presented and validated for a 290-m cruise ship. Nonlinear strip theory was used to calculate the ship–wave relative motions. The relative vertical and roll velocities for a slamming event were input to the slamming calculation program, which used a two-dimensional boundary element method (BEM) based on the generalized 2D Wagner formulation presented by Zhao et al. To improve the calculation efficiency, the method was divided into two separate steps. In the first step, the velocity potentials were calculated for unit relative velocities between the section and the water. In the next step, these precalculated velocity potentials were used together with the real relative velocities experienced in a seaway to calculate the slamming pressure and total slamming force on the section. This saved considerable computer time for slamming calculations in irregular waves, without significant loss of accuracy. The calculated slamming pressures on the bow flare of the cruise ship agreed quite well with the measured values, at least for time windows in which the calculated and experimental ship motions agreed well. A simplified method for calculation of the instantaneous peak pressure on each ship section in irregular waves is also presented. The method was used to identify slamming events to be analyzed with the more refined 2D BEM method, but comparisons with measured values indicate that the method may also be used for a quick quantitative assessment of the maximum slamming pressures.     

船艏底部砰击压力概率预报方法研究

在Ochi概率统计方法的基础上探索一种适合于非常规船型船艏底部砰击压力的概率预报方法。该方法在时域中计算船舶在波浪中的运动响应,基于Msc.Dytran计算砰击压力系数,在此基础上采用蒙特卡罗法对砰击压力的概率特性进行预报。分析了砰击时的船波相对速度和波面倾角对压力系数的影响。研究结果表明,船舶在静水和波浪中的砰击压力特性有很大差异,在波峰与波谷处发生砰击时产生的砰击压力大于在波面其它位置产生的压力值,相对速度对砰击压力系数的影响在波面不同位置呈现出不同的特点。     

Numerical and experimental analysis of bow flare slamming on a Ro–Ro vessel in regular oblique waves

A method for the prediction of slamming loads on ship hulls is presented and validated for a 20-knot, 120-m car carrier. A nonlinear strip theory is used to calculate the relative motions of ship and wave. The relative vertical and roll velocities for a slamming event are given as input to the slamming calculation program, which is based on a generalized two-dimensional Wagner formulation and solved by the boundary element method. The method is fast and robust. Model tests of a car carrier have been carried out in regular head, bow, and bow quartering waves of various heights. Slamming on two panels in the upper part of the bow flare has been studied. It has been found that the water pile-up around the bow due to the forward speed of the vessel significantly increases the slamming pressures. A simplified way of including this effect is presented. When the calculated slamming pressures are corrected for 3D effects, they compare well with the measured data. Since the effect of the wave elevation due to the forward speed and the effect of three-dimensional flow act in opposite directions, excluding both of them produced results that also agreed quite well with the experiments, especially for the most severe slamming events.     

船舶表面点砰击压力的预报方法

本文基于线性切片理论,结合船舶在波浪中运动时历的数值模拟方法,考虑船舶表面点的运动与波浪的相位关系,给出了船舶表面点的入水速度的预报方法,再运用二维剖面入水砰击压力与入水速度之间的关系,对船舶表面入水点的砰击压力进行了预报.最后,给出了一条船的计算实例.     

参数横摇下大型集装箱船外飘砰击的近似计算方法（英文）

Since the research of flare slamming prediction is seldom when parametric rolling happens, we present an efficient approximation method for flare slamming analysis of large container ships in parametric rolling conditions. We adopt a 6-DOF weakly nonlinear time domain model to predict the ship motions of parametric rolling conditions. Unlike previous flare slamming analysis, our proposed method takes roll motion into account to calculate the impact angle and relative vertical velocity between ship sections on the bow flare and wave surface. We use the Wagner model to analyze the slamming impact forces and the slamming occurrence probability. Through numerical simulations, we investigate the maximum flare slamming pressures of a container ship for different speeds and wave conditions. To further clarify the mechanism of flare slamming phenomena in parametric rolling conditions, we also conduct real-time simulations to determine the relationship between slamming pressure and 3-DOF motions, namely roll, pitch, and heave.     

超大型 VLCC 波激振动和砰击振动模型试验研究

船舶的波激振动和砰击振动对船舶结构的安全性有较大影响。文章以一艘超大型 VLCC 为研究对象,通过变截面梁分段模型试验方法对船舶在规则波和不规则波中波激振动和砰击振动响应进行了比较分析,介绍了船模波浪载荷试验中模型的设计原则,通过静水试验得到了船体梁垂向振动频率特性、振动阻尼和静水兴波弯矩等参数,通过规则波和不规则波试验分析了波高、波浪周期和装载状态等因素对波激振动和砰击振动的影响。该文的研究结果对大型船舶的结构设计具有一定的指导意义。     

弹性船体波激响应时域过程的数值模拟

本文从入射波的波浪现实出发，用非线性水弹性积分─微分法进行船体运动和结构动响应的时间历程模拟，直接将试验测量结果与理论计算在时域内作比较，这有利于揭示砰击和上浪等非线性瞬态作用导致冲荡响应的力学机理。这种模拟及其验证方法避免了对理论和试验结果的统计特性进行比较时，因子样长度的限制和数据处理过程所带来的不确定性，比峰值比较更能说明波激响应数学模型的精确性和可靠性。     

基于显式有限元方法的二维楔形刚体入水砰击载荷并行计算预报

局部砰击载荷是在船舶首部结构设计时重点关注的问题。文章基于显式有限元方法,选用任意拉格朗日—欧拉算法(ALE),针对某30°二维楔形刚体入水砰击问题,开展了数值预报工作。针对模型网格密度开展了收敛性分析。数值预报的加速度、砰击压力等时域结果与已公开发表的模型实验的结果进行了比较,吻合非常好。鉴于在微机上数值计算时间比较长的问题,文中探讨了并行计算技术在模拟中的应用。     

Wave impact on a horizontal elastic plate

The objective is to find slamming-induced local stresses in the steel or aluminum wetdeck of a multihull vessel. This is studied theoretically by representing the wetdeck as a beam model and accounting for dynamic hydroelastic effects. Two numerical methods are used, one being a simplified asymptotic solution. Satisfactory agreement between the two methods is reported. Experimental drop tests of horizontal elastic plates of steel and aluminum are also reported, and the results from the experiments agree well with the numerical computations. This study reveals, both numerically and experimentally, that slamming-induced local stresses are strongly influenced by dynamic hydroelastic effects. The maximum bending stresses are insensitive to where waves hit, the curvature of the waves, and maximum pressures. Measured maximum pressures are very sensitive to external conditions, and cannot be used as a measure of maximum local bending stresses. A simple procedure for local design stresses due to wetdeck slamming is outlined.