共查询到17条相似文献,搜索用时 282 毫秒
1.
2.
3.
4.
5.
介绍美国海军用以考核舰船设备抗冲击性能的动态设计分析方法(DDAM),利用Ansys软件对某舰用升降装置进行建模,并基于DDAM方法对其进行计算和抗冲击性能分析,分析结果可为舰用升降装置抗冲击设计和评估提供参考. 相似文献
6.
7.
增压锅炉作为船体内较为重要的设备之一,其抗冲击性能直接关系到舰船的生命力和战斗力。论文基于ABAUQS软件Dynamic/Explicit模块,用船体-设备一体化和非一体化两种分析方法对增压锅炉进行水下爆炸载荷作用下冲击响应进行时域分析。非一体化分析时设备载荷输入来自一体化分析设备基座的响应结果,经过BV规范的方法转换成的等效加速度三角波。设备-船体一体化分析和非一体化分析的增压锅炉响应对比分析结果表明非一体化分析时设备的响应偏小,用于分析设备的抗冲击能力偏于危险,建议采用舰船-设备一体化分析方法对舰船设备进行抗冲击能力分析。 相似文献
8.
9.
燃气轮机作为现代舰船常用的主动力装置,其抗冲击能力是影响舰船生命力的重要因素之一.介绍了一种对舰用燃气轮机抗冲击性的数字仿真技术评估方法,通过对在冲击载荷下的舰用燃气轮机有限元模型进行仿真计算分析,得出燃气轮机抗冲击能力临界线,对其冲击安全性进行评估,可用于舰用燃气轮机抗冲击能力的设计或校核. 相似文献
10.
GJB-1060.1-91中舰船设备抗冲击性能动态设计分析方法(DDAM)是通过设备的应力评估其抗冲击性能,不能满足特定场合需要通过加速度响应评估设备抗冲击性能的需求。基于DDAM方法设计了船舶风机双层隔振装置的冲击谱,通过遗传算法和改进的递归数字滤波法得到冲击谱相应的时域信号,并进行了验证。结果表明,合成的时域冲击信号转换后的冲击谱与DDAM方法设计的冲击谱有很好的一致性,并且隔振系统在时域冲击信号和冲击谱激励下的最大应力误差为9.1%。基于冲击谱的时域信号计算了船舶风机双层隔振装置的应力和加速度冲击响应,拓展了GJB-1060.1-91中舰船设备抗冲击性能分析方法的工程应用。 相似文献
11.
12.
13.
14.
15.
YAO Xiong-liang FENG Lin-han ZHANG A-man ZHOU Qi-xin 《船舶与海洋工程学报》2007,6(4):18-26
The non-linear finite element software ABAQUS was used to simulate the dynamic response of a marine supercharged boiler when subjected to impact loading. Shock resistance was analyzed by the time-domain simulation method. After exhaustive simulations,the effect of air pressure induced by different working conditions on the shock response of a supercharged boiler was reviewed,leading to conclusions about the variability of structural response with different loading parameters. In order to simulate the real impulsive environments of supercharged boilers,the integration of equipment and ship structure was then primarily used to analyze shock response. These distinctly different equipment shock test methods,run under equivalent work conditions,were compared and the causes of discrepancy were analyzed. The main purpose of this paper is to present references for the anti-shock design of marine supercharged boilers. 相似文献
16.
17.
Shock resistance capacity of the shipboard equipment especially for large ones, has been a strong concern of navies all over the world for a long time. The shipboard equipment have previously generally been studied separate from hull structure before. In this paper the coupling elastic effect between equipment and hull structure is taken into account. With the ABAQUS software, the integrated model of the equipment coupled with the hull structure is established to study the dynamic response of the shipboard equipment to the shock wave load as well as the bubble pulsation load. In order to verify the numerical method, the simulated results are compared to the experimental data, which are from a specific underwater explosion on an actual ship. On this basis, by changing the charge location, attack angle, equipment installation location and other parameters, the characteristics of dynamic response under different conditions can be obtained. In addition, the results of the integrated calculation and the non-integrated one are compared and the characteristic parameters which affect the equipment shock response are analyzed. Some curves and conclusions are obtained for engineering applications, which provides some insights into the shock resistance of shipboard equipment. 相似文献