共查询到19条相似文献,搜索用时 343 毫秒
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油轮艏部结构碰撞特性研究 总被引:1,自引:0,他引:1
在船舶碰撞中,船艏是主要作用方.船艏结构的碰撞特性是影响船-船碰撞过程中被撞船舷侧结构损伤程度的决定因素.为减少碰撞事故损失,应从碰撞的观点对船艏结构的特性进行研究,提出一种研究船艏的碰撞特性的方法及表征船艏碰撞特性的特征量,据以改进船艏设计.根据船艏结构本身的碰撞破损过程,对船艏结构碰撞力与破损深度的关系、艏部构件在碰撞过程中的损伤形态和能量耗散进行了研究,指出碰撞力曲线是船艏结构的一种固有特性.提出了碰撞力面积密度曲线的概念,它可以用于定量表达船艏结构对其它结构的破坏能力.利用有限元数值模拟方法计算了一艘4万吨船艏的碰撞损坏实例,显示了上述碰撞特征并讨论了提高碰撞数值模拟计算精度的方法. 相似文献
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计及船体梁载荷影响的船舶舷侧结构碰撞性能 总被引:1,自引:1,他引:0
以被撞船舷侧结构作为研究对象,建立了两船发生侧向对中垂直碰撞的非线性有限元模型。并以此为基础,进行了被撞船舷侧结构碰撞数值仿真研究,得到了能量-碰撞船位移以及碰撞力-碰撞船位移的关系曲线;研究了预载荷对船舶舷侧结构碰撞性能的影响。数值仿真结果表明,由于船体梁载荷的作用,船舶结构碰撞性能受到一定程度的削弱。 相似文献
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[目的]旨在研究船舶靠泊时“船体-护舷-码头”的动态耦合作用。[方法]采用非线性有限元方法,建立舷侧与护舷结构有限元模型,模拟船舶靠泊过程中速度、应力、能量的动态演化过程。[结果]结果表明:护舷与码头接触最紧密时,船舶速度降为零,护舷结构动态变形和相互作用力最大;船舶靠泊时,护舷呈现出较强的吸能能力,约占船舶初始总动能的70%,船体结构得到很好的保护。[结论]进一步分析表明:随着初始靠泊速度的提高,护舷效能呈降低趋势;所研究目标船的极限靠泊速度为2.5 kn,推荐安全靠泊速度为2.0 kn,研究结果可为船舶靠泊速度限制和船体结构吸能设计提供参考。 相似文献
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基于我国第七次北极科学考察获得的夏季北极海冰空间分布情况,模拟真实碎冰分布,采用LS-DYNA软件中的流固耦合方法,研究在船舶航速、碎冰尺度、碎冰厚度及碎冰密集度等因素影响下船舶-碎冰碰撞的船体结构响应。结合试验数据得到船体结构的应力、吸能和碰撞力。结果表明:船舶-碎冰的主要碰撞区域为艏部及舷侧的水线附近;在船舶航行于碎冰域时,船体结构的应力、吸能和碰撞力的峰值随碎冰域的船舶航速、碎冰尺度、碎冰厚度及碎冰密集度的增加而增加,但分布情况不同。研究结果为船舶在极地冰区航行提供一定的安全性参考。 相似文献
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超大型油船双壳舷侧结构的碰撞性能研究 总被引:14,自引:2,他引:12
应用非线性有限元数值仿真方法研究了超大型油船双壳舷侧结构的碰撞性能,分析了各个构件的损伤模式和吸能特性,获得了碰撞力,能量吸收和损伤变形的时序结果,并给出具有指导意义的一般性结论。 相似文献
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船-桥碰撞力学问题研究现状及非线性有限元仿真 总被引:4,自引:0,他引:4
归纳研究了船舶与桥梁碰撞力学的几种典型计算方法,并对各自的特点进行了分析。文中借助DYTRAN非线性有限元程序,以一艘4万吨级的油船与长江上某一斜拉索桥发生正向碰撞为例,演示了有限元法仿真计算船-桥碰撞问题的一般过程。反映了船-桥碰撞过程中船艏、桥梁承合、桥面和拉索的力与变形的时间历程,得到了具有指导意义的结论。 相似文献
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随着世界上海洋平台的增多,船舶与海洋平台的碰撞事故也随之变多,碰撞事故往往产生巨大损失.为了研究其碰撞规律,本文基于有限元软件Ansys/Ls-Dyna,研究分析不同速度下供应船尾部与半潜式海洋平台的碰撞,碰撞中的流体采用附加质量法处理.为确保计算结果精度,对碰撞的局部区域进行网格细化.计算结果表明,正碰时平台内部结构单元首先发生破坏(内部结构指水平强框处单元),外板失效所需能量比内部结构大;当撞击速度小于破坏速度时,单元没有破坏,但当船回弹时,外板上的板单元产生振动,应力和能量产生短时间波动. 相似文献
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船舶碰撞缓冲型球鼻艏概念探讨--球鼻曲率对碰撞的影响 总被引:1,自引:0,他引:1
船舶碰撞事故中,被撞油船船侧的破裂会引起严重的海洋污染,故油船双层船壳设计成为防止被撞油船破损的有效措施。但随着海上运输船舶的数目及尺度的日益增大,双层船壳已不能满足防止船侧破损的要求。本文提出了缓冲型球算般的构思。在船舶相撞的过程中,球鼻艏曲率的尖锐程度影响被撞船船侧的损伤程度,故提出并讨论了表征球鼻艏碰撞特性的标志性参数。通过对不同曲率的球鼻艏一系列的碴撞数值仿真计算,详细描述了外形曲率对球鼻艏的变形形态、碰撞力、碰撞力密度及能量吸收的影响,指出船舶采用钝形的球鼻艏能有效减小碰撞时的穿透损伤。 相似文献
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During ship collisions part of the kinetic energy of the involved vessels immediately prior to contact is absorbed as energy dissipated by crushing of the hull structures, by friction and by elastic energy. The purpose of this report is to present an estimate of the elastic energy that can be stored in elastic hull vibrations during a ship collision.When a ship side is strengthened in order to improve the crashworthiness it has been argued in the scientific literature that a non-trivial part of the energy released for structural deformation during the collision can be absorbed as elastic energy in global ship hull vibrations, such that with strong ship sides less energy has to be spent in crushing of the striking ship bow and/or the struck ship side.In normal ship–ship collision analyses both the striking and struck ship are usually considered as rigid bodies where structural crushing is confined to the impact location and where local and global bending vibration modes are neglected. That is, the structural deformation problem is considered quasi-static. In this paper a simple uniform free–free beam model is presented for estimating the energy transported into the global bending vibrations of the struck ship hull during ship–ship collisions. The striking ship is still considered as a rigid body. The local interaction between the two ships is modeled by a linear load–deflection relation.The analysis results for a simplified model of a struck coaster and of a large tanker show that the elastic energy absorbed by the struck ship normally is small and varies from 1 to 6% of the energy released for crushing. The energy stored as elastic global hull girder vibrations depends on the ship mass, the local stiffness of the side structure, and of the position of contact. The results also show that in case of highly strengthened ship sides the maximum global bending strains during collisions can lead to hull failure. 相似文献
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A number of authors have proposed probabilistic risk based ship design for ship–ship collision, conditional to the local trading area of a vessel. The probability of collision and consequences are determined based on the traffic conditions in which a vessel is expected to operate. This paper investigates the adequacy of currently available models for impact scenarios, i.e. models linking the traffic conditions to the conditions at the moment of collision. An exploratory statistical model is presented to establish such a link. A probabilistic risk based design case study is performed for a fleet of RoPax vessels trading on a specified route in the Gulf of Finland. The available impact scenario models from the literature are compared with the developed probabilistic evasive maneuvering model. The results show that the impact scenario models have a very significant influence to the calculated hull breach probabilities. No well-justified impact scenario models are presently available and also the presented probabilistic evasive maneuvering model is burdened with uncertainty. Hence, to move toward a probabilistic risk based ship design paradigm for ship–ship collision in a local trading area, more focus and research is needed to establish a credible link. 相似文献