碳钢、低合金钢全浸没海洋环境下最大点蚀深度简化模型

腐蚀是导致老龄船舶结构失效的主要原因之一。结合基本点蚀原理,文章对碳钢、低合金钢海水全浸没点蚀的主要影响因素、具体点蚀进程做了简要解释与评述。基于Melchers点蚀深度模型及其相关实验数据,文中提出一种简化形式的新型点蚀最大深度模型,并采用该模型对三组我国船舶结构常用碳钢、低合金钢的青岛海域全浸没点蚀试验观测数据进行分析。通过对比验证,证明采用Weibull函数表示点蚀最大深度随时间变化关系是合适的。此外,依据青岛、厦门、榆林海域碳钢试验数据,文中还对海水环境因素,如:溶解氧浓度、平均温度、盐度、PH值等,以及钢材成分变化对新型最大点蚀深度模型各参数的影响进行了初步探讨,得出了相应的函数关系式及相关结论。     

船舶结构钢海洋环境点蚀模型研究之二:实船蚀坑形态与径深比时变模型

文章基于点蚀生长原理与实船蚀坑形态检测数据,对船舶受点蚀构件的两类主要蚀坑的形态、形成机制及其随船龄演化情况作了大致描述.认为遭受点蚀船舶构件的蚀坑形态与其所处位置、服役时间等密切相关;两类蚀坑形态差异的原因在于其各自点蚀进程中的具体控制因素及相应的影响程度存在较大区别.论述证明将点蚀蚀坑径深比处理成随时间变化的函数是有理论和事实依据的;并与点蚀深度模型相结合,依据Yamamoto实测散货船货舱区肋骨蚀坑数据建立了相应的蚀坑径深比时变模型.     

点蚀损伤船体结构板的极限剪切屈曲强度研究

腐蚀损伤导致船体结构板的极限承载能力大幅度下降。文章采用腐蚀体积描述板的点蚀损伤程度,模拟船体结构板的点蚀损伤形态,在点蚀损伤板模型中变化板的厚度、点蚀数目、点蚀直径以及点蚀分布等要素,实施系列有限元数值模拟计算,在进行理论分析的基础上,采用统计学方法,建立了点蚀损伤板极限剪切屈曲强度的评估方法,得到了点蚀损伤板极限剪切屈曲强度的计算公式。从而确立了基于腐蚀体积的点蚀损伤船体结构板极限剪切屈曲强度的评价技术,可为在役海船点蚀损伤后的安全性评估提供有效的技术手段。     

腐蚀疲劳点蚀演化及腐蚀疲劳裂纹成核机制研究

作为一种不可逆的热力学过程,腐蚀疲劳的点蚀演化伴随着体系能量的耗散。文章基于热力学原理,对腐蚀疲劳点蚀演化过程中的能量问题进行探索性研究。引入双变量点蚀模型,建立点蚀演化过程中体系热力学势函数,推导了点蚀形状参数在演化过程中的变化方程,并分析了体系应变能、表面能和电化学能对点蚀演化形貌的影响机制及规律。根据裂纹成核位错机理建立了腐蚀疲劳裂纹成核临界条件的能量准则,并与应力强度因子准则进行比较,分析结果验证了能量准则的合理性。     

点蚀损伤钢板在空爆冲击波载荷作用下的动态响应研究

为探讨固支点蚀损伤钢板结构在空爆冲击波载荷作用下的动态响应,利用有限元分析软件Ansys/LSDYNA,开展了空爆冲击波对固支点蚀钢板板的毁伤作用数值模拟计算,探讨了点蚀损伤深度、点蚀损伤分布密度及点蚀损伤分布位置对固支钢板结构在空爆冲击波载荷作用下动态响应的影响。结果表明,点蚀损伤深度、点蚀损伤分布密度均对板的动态承载能力有较显著影响,而点蚀损伤分布位置则影响非常小。     

轴向压力下含点蚀损伤加筋板极限强度研究

点蚀损伤常发生于船体结构,将会造成结构的局部缺失而影响船舶结构的安全性.针对船体结构的基本构件加筋板,采用非线性有限元法研究轴向压力下点蚀损伤对其极限强度的影响,考虑点蚀位置、直径、数目、深度、点蚀损失体积等影响因素,分析船体加筋板极限应力和屈曲失效模式,获得结构的极限强度,拟合影响因素和加筋板极限强度的关系曲线,定性分析了点蚀损伤对加筋板的破坏.结果表明,点蚀损伤削减了加筋板极限强度;点蚀影响因素(点蚀直径、数目、深度、损失体积)对含点蚀损伤加筋板极限强度的影响近似呈现非线性的二次单调函数关系.     

316L不锈钢液货管发生点蚀的原因分析

通过分析316L奥氏体不锈钢管材发生点状腐蚀的特性,揭示316L不锈钢在海洋环境下造成点蚀的主观因素及客观因素,以及如何保养316L不锈钢管延长其使用寿命,完善不锈钢材料在船舶领域使用的规范性。文章介绍了不同质量分数氯离子的溶液及不同环境温度316L奥氏体材料的腐蚀速率,得出随着氯离子质量分数的增加及环境温度升高材料加速腐蚀的特性。     

船舶柴油机缸套的穴蚀分析

缸套穴蚀是船舶柴油机汽缸套常见的一种损伤形式，这对船舶柴油机工作的可靠性和使用寿命有很大影响。缸套穴蚀主要形式是局部的蜂窝状的孔穴和麻点，而缸套穴蚀的成因机制主要有电化学腐蚀、空泡腐蚀等。随着柴油机转速、有效压力、比功率的提高，相应的比重量逐渐降低，其结构日益紧凑和零部件壁厚减薄，船舶柴油机缸套穴蚀破坏日益引起人们的关注。文章论述了柴油机主要部件、冷却水系统、柴油机工况等因素对穴蚀的影响，最后指出预防穴蚀的基本措施和检修方法。     

考虑点腐蚀影响的船体板疲劳寿命评估

针对疲劳现象对点腐蚀极为敏感的问题,基于点腐蚀蚀坑处的应力集中系数,计算了含点腐蚀船体板单元的疲劳寿命。结果发现:对于半球形蚀坑,蚀坑处应力集中系数随蚀坑深度的增加而增大,两者基本上呈线性关系;当蚀坑深度为0,即无点腐蚀时,累积损伤度约为1,结构的疲劳寿命约等于设计寿命,这与客观事实是相符的,验证了基于应力集中系数计算结构疲劳寿命的合理性;当蚀坑深度仅为0. 2倍板厚时,含2种蚀坑的板单元疲劳寿命迅速减小到原寿命的47%、9%和23%;当蚀坑深度达到板厚时,板单元被蚀穿。这一结果说明结构的疲劳寿命随蚀坑深度的增大急剧减小,结构的疲劳寿命对点腐蚀极为敏感。     

点蚀损伤板在复杂受力状态下的极限强度研究

采用非线性有限元软件模拟船底板单面点腐蚀,通过对边缘载荷系数比、蚀坑分布、直径、深度的改变,经过一系列的数值计算分析,结果表明横向载荷和侧压对板的极限强度影响不可忽略,计算板的极限承载能力时需要考虑计及侧压与横向载荷。在复杂受力状态下,就单考虑蚀坑深度时,板表面的蚀坑深度在0~0.5t区间变化时,极限强度相应的折减率比大于1/2板厚时更大,极限强度对蚀坑深度更加敏感。腐蚀面积不能有效表征腐蚀程度,当DOP系数相同时,点蚀后板的最小横截面决定了极限强度的大小。     

考虑腐蚀影响的船舶结构可靠性研究现状与展望

对近年来考虑腐蚀影响的船舶结构可靠性计算各主要研究层面的研究现状做了介绍与评述.通过这一综述可以发现:此领域研究工作重心已由考虑线性、非线性均匀腐蚀的影响逐步向局部腐蚀尤其是点腐蚀方向转变.今后的研究重点为以下三个方面,即:①发展符合基本腐蚀机理、与实测腐蚀数据较为吻合的点腐蚀多指标模型;②确定蚀点几何参数在各类荷载条件下对构件强度的影响;③深入评估腐蚀与疲劳的相互作用对结构可靠性计算的影响.     

钢筋坑蚀对混凝土柱偏压性能的影响

坑蚀是混凝土钢筋锈蚀的主要形式之一。与钢筋均匀锈蚀相比,钢筋坑蚀具有显著的不确定性和更大的截面损失等特点,对混凝土构件的性能具有一定的影响。借助Monte Carlo模拟,分析了锈蚀钢筋混凝土柱的偏压抗力性能,研究了钢筋坑蚀对混凝土偏压柱承载能力的影响。结果表明,钢筋坑蚀的随机性对柱的可靠性有很大影响,钢筋坑蚀构件承载力的下降速度比均匀锈蚀更快,对柱的耐久性具有潜在危害。     

热带海洋大气环境中3004系列铝和铜电化腐蚀行为研究(英文)

The galvanic corrosion behaviour of aluminium 3004 and copper with different area ratios were studied in the tropical marine atmosphere at Tuticorin harbour over a period of 426 days. The area ratios of AAl : ACu, studied were 1:1, 1:2, 1:4, 1:8, 2:1, 4:1 8:1. The galvanic corrosion behaviour of metals was studied in terms of relative increase in the corrosion rate of aluminium due to galvanic coupling with copper, relative decrease in the corrosion rate of copper due to galvanic coupling with aluminium, and the susceptibility of aluminium to pitting owing to galvanic coupling with copper. The galvanic potential and galvanic current of the system were monitored. Pits of different dimensions ranging from mild etchings to perforations were experienced on the borders and the surfaces of the interface of aluminium in contact with copper. The weathering parameters and the environmental pollutants which have a major role in influencing the galvanic corrosion of metals were also monitored. The corrosion products resulting from galvanic corrosion were analysed using XRD and the pitting on aluminium resulting from galvanic corrosion has been highlighted in terms of pit depth, size and density of pit, using a high resolution microscope.     

点蚀板在纵向压力下的极限强度研究

本文着眼于老龄化船舶结构上的局部点状腐蚀和整体点状腐蚀,利用非线性有限元软件分析了超过100个船体板结构的极限强度。研究了蚀坑形状、蚀坑位置、蚀坑大小、蚀坑深度和板的柔度对含局部点状腐蚀船体板的极限强度的影响,蚀坑分布、板的柔度和腐蚀体积对含点状腐蚀船体板的极限强度的影响。拟合出了单面、双面局部点状腐蚀下的船体板极限强度折减公式,单面、双面点状腐蚀下的船体板极限强度折减公式。并得到同时适用于局部和整体点状腐蚀板极限强度的公式。     

国外混凝土结构耐久性监测传感器在国内工程中的适用性*

采用动电位极化和线性极化技术研究了国内普通钢筋、阳极梯监测传感器所用普通钢筋和ECI-2传感器所用普通钢筋的点蚀临界浓度和点蚀后的腐蚀速率。研究结果表明：ECI-2传感器所用普通钢筋的点蚀临界氯离子浓度与国内普通钢筋相似,点蚀速率略小于国内普通钢筋;阳极梯传感器所用的普通钢筋的点蚀临界氯离子浓度要高于国内普通钢筋,点蚀速率要明显低于国内普通钢筋。因此,在用这两种传感器进行国内工程耐久性监测时应对监测结果进行修正。     

Galvanic corrosion behaviour of aluminium 3004 and copper in tropical marine atmosphere

The galvanic corrosion behaviour of aluminium 3004 and copper with different area ratios were studied in the tropical marine atmosphere at Tuticorin harbour over a period of 426 days. The area ratios OfAAI： Acu, studied were l：l, 1：2, l：4, 1：8, 2：1, 4：1 ＆ 8：1. The galvanic corrosion behaviour of metals was studied in terms of relative increase in the corrosion rate of aluminium due to galvanic coupling with copper, relative decrease in the corrosion rate of copper due to galvanic coupling with aluminium, and the susceptibility of aluminium to pitting owing to galvanic coupling with copper, The galvanic potential and galvanic current of the system were monitored. Pits of different dimensions ranging from mild etchings to perforations were experienced on the borders and the surfaces of the interface of aluminium in contact with copper. The weathering parameters and the environmental pollutants which have a major role in influencing the galvanic corrosion of metals were also monitored. The corrosion products resulting from galvanic corrosion were analysed using XRD and the pitting on aluminium resulting from galvanic corrosion has been highlighted in terms of pit depth, size and density of pit, using a high resolution microscope.     

Effect of pitting corrosion on local strength of hold frames of bulk carriers (2nd Report)—Lateral-distortional buckling and local face buckling

Pitting corrosion is typical corrosion observed on coated hold frames of bulk carriers which exclusively carry coal and iron ore. In order to secure the safety of these types of bulk carriers, it is important to understand the effect of pitting corrosion on local strength of hold frames.

In order to investigate this effect, a series of 4- and 3-point bend tests on structural models which consist of web, shell and face plates has been carried out. Artificial pitting was created on the web plate to simulate pitting. In the 4-point bend tests, two equal concentrated loads have been applied vertically at the one-third points of simply supported models so that compression load due to bending would act on the face plate. In this testing condition, lateral-distortional buckling occurred before reaching the ultimate strength and local buckling of the face plate was observed after reaching the ultimate strength. The effect of web plate pitting on the lateral-distortional buckling strength was found to be small but the ultimate strength decreases with increase in the degree of pitting intensity. In the 3-point bend tests, concentrated load has been applied vertically at the center of simply supported models so that compression load due to bending would act on the face plate. In this testing condition, local face buckling occurred just after reaching the ultimate strength. The ultimate strength is found to be decreasing with increase in the degree of pitting intensity.

A series of non-linear FE analyses has been performed to simulate the deformation behavior observed in the tests. It has been revealed that even in the case of randomly distributed pitting corrosion the ultimate strength of the structural models was almost the same as that of the structural models with uniform corrosion corresponding to the average thickness loss.     

Effect of pitting corrosion on the ultimate strength of steel plates subjected to in-plane compression and bending

Corrosion pits with a circular cone shape are typically observed on coated hold frames of aged bulk carriers which carry exclusively coal and iron ore. In order to ensure the safety of these types of bulk carrier, it is necessary to understand the effect of pitting corrosion on the local strength of hold frames. In order to investigate this effect, a series of nonlinear finite-element (FE) analyses has been performed with pitted plates subjected to in-plane compressive loads and bending moments. It has been shown that the ultimate compression load or bending moment of pitted plates is smaller than that of uniformly corroded plates in terms of average thickness loss, and that predictions of the ultimate strength using the average thickness loss at the minimum cross section would be conservative. In order to establish a method of evaluating strength reduction due to pitting corrosion, it is important to identify the failure mode that would be most detrimentally affected by pitting corrosion. It was found that the reduction of the ultimate compressive load or bending moment due to pitting corrosion is smaller than that of the tensile strength in terms of equivalent thickness.