焊接初始缺陷对船体梁极限弯矩的影响

对焊接初始缺陷于船体梁极限弯矩的影响进行了研究.采用热传递分析得到焊接结构的温度场,进而采用热弹塑性分析得到结构的焊接残余应力和焊接变形.将得到的焊接变形及残余应力作为结构的初始缺陷,对船体梁的极限弯矩进行了比较计算.结果表明,焊接初始缺陷对船体梁极限弯矩的影响不宜忽略,热传递及热弹塑性分析的方法可较好地模拟船体梁极限弯矩分析中的焊接初始缺陷.     

联合弯矩作用下含裂纹船体结构剩余极限强度评估方法研究

裂纹损伤对于船体结构来说难以避免,将削弱结构的极限强度,所以研究含裂纹损伤船体结构的剩余极限强度意义重大.对于含裂纹舱段结构,现有的研究主要针对垂向弯矩作用下的剩余极限强度,对于联合弯矩作用下的研究还很欠缺.本文采用非线性有限元分析方法,研究了垂向弯矩和水平弯矩联合作用下含裂纹舱段的剩余极限强度.提出了计算含裂纹船舯舱段在联合弯矩作用下剩余极限强度的计算公式,通过对含裂纹箱型梁的有限元计算结果进行拟合,得到公式中待定系数的表达式.研究结果表明,本文提出的方法可以快速预测船体结构在联合弯矩作用下的剩余极限强度.     

6750箱集装箱船非线性波激振动和颤振响应分析

本文采用三维时域非线性水弹性方法分析了一艘6750箱集装箱船的水弹性响应以及运动和垂向弯矩特征。通过考虑入射波力、静水恢复力、砰击效应的非线性,研究了在恶劣海况下船体的非线性运动和垂向弯矩响应,同时分析了波激振动及颤振对垂向弯矩的影响。数值计算结果表明:(1)非线性入射波力对运动的影响较小,但是对垂向弯矩的影响较大,使得其有明显的倍频成分,同时中垂弯矩显著大于中拱弯矩。另外,非线性入射波力也引起了明显的非线性波激振动;(2)非线性静水恢复力对运动和载荷的影响均较大,但是没有引起明显的非线性响应。非线性计算的垂荡响应小于线性结果,而纵摇和垂向弯矩响应大于线性结果;(3)砰击效应对运动的影响较小,但对垂向弯矩的影响较大,砰击效应引起了显著的船体弹性高频振动,增大了载荷幅值,但是其引起的合成中垂和中拱幅值相差不大;(4)非线性水动力的作用主要引起垂向弯矩的倍频响应,包括倍频可能引起的二节点垂向弯矩弹性共振,而砰击效应主要引起船体二节点垂向弯矩共振;(5)本文的非线性水弹性响应计算结果与Kim给出的数值计算结果吻合很好。     

联合弯矩作用下含裂纹船体结构剩余极限强度评估方法研究（英文）

裂纹损伤对于船体结构来说难以避免,将削弱结构的极限强度,所以研究含裂纹损伤船体结构的剩余极限强度意义重大。对于含裂纹舱段结构,现有的研究主要针对垂向弯矩作用下的剩余极限强度,对于联合弯矩作用下的研究还很欠缺。本文采用非线性有限元分析方法,研究了垂向弯矩和水平弯矩联合作用下含裂纹舱段的剩余极限强度。提出了计算含裂纹船舯舱段在联合弯矩作用下剩余极限强度的计算公式,通过对含裂纹箱型梁的有限元计算结果进行拟合,得到公式中待定系数的表达式。研究结果表明,本文提出的方法可以快速预测船体结构在联合弯矩作用下的剩余极限强度。     

含月池开孔的FPSO水动力性能及波浪载荷研究

为研究月池开孔对FPSO水动力性能和波浪载荷的影响,基于三维势流理论和波浪诱导载荷理论,分析了不同的月池尺寸、不同的月池纵向位置以及不同的船体吃水时附加质量和附加阻尼的变化趋势。并进行了含月池开孔的FPSO波浪诱导载荷的长期预报,得到了截面垂向剪力和弯矩沿船长方向的分布规律,分析了月池尺寸对波浪诱导载荷的影响。结果表明含有月池的FPSO船体的垂向附加质量和附加阻尼会出现一个峰值,随月池尺寸增加而逐渐减小;月池处垂向剪力和垂向弯矩随月池尺寸增大有小幅度减小。     

基于不同海域海况特点的通用型FPSO疲劳损伤分析

由于西非海域、墨西哥湾海域和巴西海域的海况特点存在明显差异,通用型FPSO在三个海域海况下的疲劳损伤呈现出较大差别,对通用型FPSO进行基于不同海域海况特点的疲劳损伤分析,结果表明,对于通用型FPSO,垂向弯矩对于船体结构疲劳强度的影响要比转矩的影响大得多,设计时应充分考虑垂向弯矩的影响;对于主船体关键热点,各海域不同系泊方式下的热点损伤均具有明显差异,其中多点系泊西非海域的疲劳损伤较大,巴西海域次之,墨西哥湾海域最小,内转塔系泊对应的疲劳损伤大于外转塔系泊,设计时应根据通用型FPSO的实际运行海域与系泊方式重点考虑损伤较大的海域与系泊方式。     

水下近场爆炸下船体梁鞭状运动数值模拟

基于Ls-dyna的ALE算法,对排水量为5 890 t的船体梁在315 kg TNT水下近距爆炸下的鞭状运动进行数值模拟,分析船体梁鞭状运动过程和药深对船体梁鞭状运动的影响,探究了船体梁鞭状运动与水下爆炸气泡脉动过程在时间上的同步性。研究表明：船体梁的第一次中拱、中垂运动与炸药的第一次膨胀、收缩过程在时间上基本同步,而船体梁的后续中拱、中垂运动与炸药的后续膨胀、收缩过程在时间上稍有延迟;随着药深增大,船体梁的第二次中拱、中垂运动逐渐增大,并在时间上逐渐延迟。     

6520 TEU集装箱船船体温度变形

以6 520TEU集装箱船为研究对象,分析大连、上海和广州等3个地区夏季和冬季多种环境温度下的船体变形,讨论日照因素对船体变形的影响。将船体简化为变剖面阶梯型薄壁梁,采用热传导理论求解船体剖面结构温度分布,并将温度载荷等效为船体梁弯矩和轴向力,计算船体温度变形。计算结果表明,船体温度变形在夏季呈中拱、冬季呈中垂,日照因素显著增加船体变形,船体左右舷不均匀日照将引起水平弯曲变形。     

油船实际装载操作中应校核极限强度

由于船体梁极限强度校核值不需要经船级社认可批准,不必纳入装载手册,仅需在设计阶段进行校核。实际设计工作中设计者会根据各自的需要和经验在结构吃水从出港到到港全程设计不同的中间状态,产生不同的实际操作最大静水弯矩值,供设计阶段校核船体梁极限强度的实际操作最大静水弯矩包络值值不且唯一性。文章以某实船为例进行计算分析,发现中间装载过程对弯矩包络值影响较大,不同的中间过程会产生不同的弯矩包络值,若以其中某组较小包络值作为设计阶段船体梁极限强度校核值,同时在船舶营运实际操作中又不对此船体梁极限强度进行校核,会给实际营运的的船舶带来安全隐患。为防止出现这一问题,建议将船体梁极限强度校核值作为强度衡准放入完工装载手册用以指导船长实际操作,确保所有实际操作状态的弯矩不得超过船体梁极限强度校核值。     

大型液化天然气船船体极限强度研究

船体极限强度是大型液化天然气(LNG)船海洋环境适应能力的显示指标,而薄膜型LNG船的船体结构具有大舱容和较强的箱形凸起甲板等特点。为了精确评估大型LNG船的船体极限承载能力,文中采用具有代表性的解析方法、简化方法、理想结构单元法和非线性有限元法进行比较研究。首先介绍了上述方法的基本原理和计算步骤。然后以大型LNG船的船中肋骨间结构为研究对象建立了精细的计算模型,并对计算结果进行了比较分析。最后,按法国船级社规范要求对大型LNG船极限强度进行了校核。研究结果表明,文中给出的计算方法适合于大型LNG船的船体极限强度评估,而凸起的箱形甲板显著提高了大型LNG船中垂和中拱极限弯矩比值。     

Ultimate strength of container ships subjected to combined hogging moment and bottom local loads part 1: Nonlinear finite element analysis

This paper is the first of two companion papers concerning the ultimate hull girder strength of container ships subjected to combined hogging moment and bottom local loads. In the midship part of container ships, upward bottom local loads are usually larger than the downward ones. This leads to the increase of biaxial compression in the outer bottom plating and the reduction of the ultimate hull girder strength in the hogging condition. In this Part 1, the collapse behavior and ultimate strength of container ships under combined hogging moment and bottom local loads are analyzed using nonlinear finite element method. Buckling collapse behavior of bottom stiffened panels during the progressive collapse of a hull girder is closely investigated. It has been found that major factors of the reduction of ultimate hogging strength due to bottom local loads are (1) the increase of the longitudinal compression in the outer bottom and (2) the reduction of the effectiveness of the inner bottom, which is on the tension side of local bending of the double bottom. The obtained results will be utilized in the Part 2 paper to develop a simplified method of progressive collapse analysis of container ships under combined hogging moment and bottom local loads.     

Reliability analysis of a bulk carrier in ultimate limit state under combined global and local loads in the hogging and alternate hold loading condition

The alternate hold still-water loading in hogging combined with wave loading is critical for the safe design of bulk carriers. The ultimate longitudinal strength of the hull girder of bulk carriers in this condition has been found to be considerably reduced by the action of local lateral pressure loads. In the present paper, an interaction equation based on the ultimate hull girder strength assessment obtained by nonlinear finite element analyses is adopted to consider the relationship between ultimate longitudinal bending capacity and average external sea pressure over the bottom. This interaction equation is used as the basis for the failure function. The annual probability of failure is obtained by FORM analysis considering two typical load cases, namely, pure longitudinal hogging bending moment and combined global hogging bending moment and local lateral pressure loads. The effect of heavy weather avoidance on the failure probability is evaluated. The results show that the local lateral pressure has a significant influence on the annual probability of failure of bulk carriers in the hogging and alternate hold loading condition.     

基于完整船体极限强度和搁浅剩余强度的协调共同结构规范对比分析

文章基于Smith法,根据国际船级社协会发布的2013版协调共同结构规范(HCSR)中破损模型、失效模式和载荷模型,考虑材料屈服、结构单元屈曲及后屈曲的特性,应用FORTRAN程序设计语言编写船体极限强度计算程序,以某76000吨散货船为算例,对完整船体的极限强度进行计算,对搁浅状态下破损船体的剩余强度进行计算并校核承载能力。通过在中拱和中垂工况下与其他规范的对比验证,2013版HCSR指定的剩余强度校核公式及船体梁载荷计算公式中选取的安全系数要求更高,校核更严格。     

Ultimate strength of container ships subjected to combined hogging moment and bottom local loads,Part 2: An extension of Smith's method

This paper is the second of two companion papers concerning the ultimate hull girder strength of container ships subjected to combined hogging moment and bottom local loads. The nonlinear finite element analysis in Part 1 has shown that local bending deformation of a double bottom due to bottom lateral loads significantly decreases the ultimate hogging strength of container ships. In this Part 2, extending Smith's method for pure bending collapse analysis of a ship's hull girder, a simplified method of progressive collapse analysis of ultimate hogging strength of container ships considering bottom local loads is developed. The double bottom is idealized as a plane grillage and the rest part of the cross section as a prismatic beam. An average stress-average strain relationship of plate/stiffened plate elements employed in Smith's method is transformed into an average stress-average plastic strain relationship, and implemented in the conventional beam finite element as a pseudo strain hardening/softening behaviors. The extended Smith's method is validated through a comparison with nonlinear finite element analysis.     

点蚀损耗对船体梁极限强度的影响（英文）

The paper focuses on the assessment of the hull girder ultimate strength,combined with random pitting corrosion wastage,by the incremental-iterative method.After a brief review about the state of art,the local ultimate strength of pitted platings under uniaxial compression is preliminarily outlined and subsequently a closed-form design formula is endorsed in the Rule incremental-iterative method,to account for pitting corrosion wastage in the hull girder ultimate strength check.The ISSC bulk carrier is assumed as reference ship in a benchmark study,devoted to test the effectiveness of the incremental-iterative method,by a comparative analysis with a set of FE simulations,performed by Ansys Mechanical APDL.Four reference cases,with different locations of pitting corrosion wastage,are investigated focusing on nine combinations of pitting and corrosion intensity degrees.Finally,a comparative analysis between the hull girder ultimate strength,combined with pitting corrosion wastage,and the relevant values,complying with the Rule net scantling approach,is performed.Based on current results,the modified incremental-iterative method allows efficiently assessing the hull girder ultimate strength,combined with pitting corrosion wastage,so revealing useful both in the design process of new vessels and in the structural health monitoring of aged ships.     

Prediction of hull girder moment-carrying capacity using kinematic displacement theory

The hull girder moment capacity of a very large crude oil carrier (VLCC) called Energy Concentration (EC), for which many benchmark studies have been carried out using the simple progressive collapse method (SPCM), is predicted. In this study, three approaches are used to represent the load-shortening behavior, so-called average compressive strength, of a stiffened panel, comprising the hull section: 1) kinematic displacement theory (KDT); 2) nonlinear finite element analysis (FEA); and 3) simple formulas in the common structural rule (CSR) for tankers. Load-shortening curves for various kinds of stiffened panels in EC are compared for five different scenarios with variations of load-shortening approaches and initial imperfections. In order to verify the effect of load-shortening on the prediction accuracy of the hull girder moment-carrying capacity, load-shortening curves are imported into an SPCM-based in-house program called Ultimate Moment Analysis of Damaged Ships (UMADS). Comparison of the hull girder ultimate strength for general heeling conditions, including hogging and sagging conditions, reveals that the load-shortening curves significantly affect the hull girder moment-carrying capacities. Based on our comparison of these capacities with other benchmark results, it is concluded that nonlinear FEA provided the most conservative results, KDT provided the second most conservative results, and the CSR formulas predicted the upper bound.     

Ultimate hull girder strength of a bulk carrier under combined global and local loads in the hogging and alternate hold loading condition using nonlinear finite element analysis

For bulk carriers in hogging, the most critical situation is the alternate hold loading (AHL) condition with odd numbered holds loaded with high density cargoes and even numbered holds empty. The effect of the local lateral pressure loads should be considered in the assessment of ultimate hull girder strength in the hogging and AHL conditions. In the present paper the ultimate strength of a Capesize bulk carrier hull girder under combined global and local loads in the hogging and AHL condition is extensively and systematically investigated using nonlinear finite element (FE) analysis with ABAQUS software. Since the bulk carrier used as a reference vessel in this study is an old design we also studied the effect of modified scantlings by multiplying the plate thickness in the bottom structure by a design modification factor (DMF). In particular, it should be noted that a DMF of 1.4 gives a design in accordance with the new CSR rules. Based on the results obtained by nonlinear FE analyses, a practical interaction equation is established between global hogging bending capacity and average external sea pressure over the bottom.     

散货船隔舱重载下极限强度简易计算方法研究

散货船在装载矿石等重货时,通常只装载在奇数货舱内,这就是所谓的隔舱重载工况。在这种工况下,中间舱的双层底结构除受到总纵弯曲作用外,还会受到邻舱重货引起的局部弯曲作用,而且该局部弯曲的作用会降低中拱状态下船体梁的极限强度。文章提出了一种简易计算方法,顶边舱结构和底边舱结构可以看作两根梁,双层底结构可视作正交异性板,运用双梁理论和正交异性板理论可推导出局部弯曲的影响。然后,考虑该局部弯曲的作用,用Smith法计算船体梁的极限强度。最后,将文中方法计算的结果与FEM结果进行比较,并对结果进行了分析。