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SPSM and its application in cylindrical shells 总被引:1,自引:0,他引:1
In naval architectures, the structure of prismatic shell is used widely. But there is no suitable method to analyze this kind of structure. Stiffened prismatic shell method (SPSM) presented in this paper, is one of the harmonic semi-analytic methods. Theoretically, strong stiffened structure can be analyzed economically and accurately. SPSM is based on the analytical solution of the governing differential equations for orthotropic cylindrical shells. In these differential equations, the torsional stiffness, bending stiffness and the exact position of each stiffener are taken into account with the Heaviside singular function. An algorithm is introduced, in which the actions of stiffeners on shells are replaced by external loads at each stiffener position. Stiffened shells can be computed as non-stiffened shells. Eventually, the displacement solution of the equations is acquired by the introduction of Green function. The stresses in a corrugated transverse bulkhead without pier base of an oil tanker are computed by using SPSM. 相似文献
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爆炸荷载作用下的舰船防护舱壁的承载能力(英文) 总被引:1,自引:0,他引:1
大型水面舰船的防护舱壁需要设计成工作在薄膜应力状态下.利用能量法推导了在爆炸荷载作用下防护舱壁塑性大变形的计算公式、探讨了防护舱壁的最大承载能力,对防护舱壁的设计要求进行了讨论.与国外发表的有关试验结果进行了计算比较,结果表明该方法具有一定的应用价值. 相似文献
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研究船体剩余强度和进行生命力评估时,首先要确定武器命中舰体的位置及破口尺寸,进而确定破口参数。由于命中武器的种类不同,命中舰体的部似也不同,舰体破口尺寸的大小也各异。因此,确定舰体遭受武器命中后的破口参数是一件十分复杂的事情。对近代各类大型水面舰艇遭受武器攻击后的破口进行了统计分析,并对舰体破口参数的选取给出了参考建议。 相似文献
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加装箱形抗损结构的舰船主船体剩余强度分析 总被引:1,自引:0,他引:1
作战舰船必须具备承受反舰武器打击的能力。以GBU-12B/B激光制导炸弹直接命中船体主甲板为研究背景,比较分析舰船在遭受打击前后船体强度的变化,并提出在舰船主甲板下加装箱形抗损结构的方案。通过对甲板破口处进行有限元建模,计算该处的应力。分析箱形抗损结构对提高船体剩余强度的影响。研究结果表明,加装箱形抗损结构能够提高舰船剩余强度,进而提高舰船生命力。 相似文献
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