180m甲板货/下水驳B42的详细有限元分析

Fikri Bashar Yalchiner, R. Agrawal, F. Kamal, Oussama Takieddine
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摘要

在这项研究中,描述了一艘180米甲板货物/发射驳船B42的详细有限元分析方法,用于32,000吨的上层负载,并给出了结果。在过去,对大型焊接钢结构(如甲板货物/下水驳船)使用有限元法(FEM)是相当具有挑战性的,因为工程师必须观察求解精度和数值效率之间的平衡。然而,最近有限元软件包中求解器算法的改进和计算机中核心处理器数量的增加使工程师能够在有限元模型中包含更多细节,从而可以精确地模拟结构的刚度和质量。在本研究中,整个驳船在ANSYS软件中使用包括纵梁、加强筋、法兰、底板、滑轨和伸出臂在内的壳体元件进行建模。分析了两种最关键的载荷情况;第一个是最大占用条件,发生在上层甲板装载序列中,上层甲板完全在驳船甲板上,朝向船尾。第二种载荷是最大下垂的情况下,顶部是在驳船甲板上运输的最终位置。详细的有限元分析结果证实了驳船的结构完整性,表明所有应力和位移都低于所有荷载情况下的允许极限。通过对整个驳船的详细建模,观察到两个主要优点。首先,与壳梁模型相比,该模型具有更快的预处理时间。其次,在这种情况下,增加全局有限元模型中关键位置的网格密度相当于一个子模型。因此,消除了单独分析任何细节的需要。
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Detailed Finite Element Analysis of 180 M Deck Cargo / Launch Barge B42
In this study, a detailed finite element analysis methodology of a 180 m deck cargo/launch barge B42 for 32,000 MT topside load is described and results are presented. Using Finite Element Method (FEM) for large welded steel structures such as a deck cargo/launch barge has been quite challenging in past because the engineer had to observe the balance between solution accuracy and numerical efficiency. However, recent improvements in solver algorithms in FEM packages and increasing core processor numbers in computers enable engineers to include a lot more details to their FE model so that accurate stiffness and mass of the structure can be simulated. In this study, the entire barge is modelled in ANSYS Software using shell elements including longitudinal beams, stiffeners, flanges, base plates, skid tracks and outriggers. Two most critical load cases were analyzed; the first is the maximum hogging condition which occurs in the topside loadout sequence where the topside is entirely on barge deck towards stern. The second load being the maximum sagging case where the topside is at the final location on the deck of barge for transportation. Results of the detailed FE analysis confirmed the structural integrity of the barge showing all the stresses and displacements are below allowable limits for all load cases. Two main advantages were observed through detailed modelling of the entire barge. Firstly, a faster preprocessing time is as compared to shell-beam models. Secondly, increasing the mesh density in critical locations in global FE model will be equivalent to a sub-model in this case. Thus, eliminating the need for analyzing any detail separately.
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