排序方式: 共有70条查询结果,搜索用时 234 毫秒
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要根据客户定制的参数设计出符合订单要求的个性化起重机车轮组产品,原有人工设计方法的设计周期较长、产品误差较大,基于知识工程和参数化设计的理论,利用对Solid Works软件的二次开发,构建用于起重机车轮组的三维快速参数化设计模型。通过Access数据库存储的系统设计信息和定制参数等基础数据,以Visual Basic编程语言驱动整个设计系统的运行,可大大提高设计工作的效率,进一步规范相关设计准则,以满足客户对起重机车轮组的设计要求。 相似文献
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针对船舶建造中的锚链筒设计物理状态下的拉锚试验,以某49000 DWT成品油轮为研究对象,对其进行拉锚试验仿真,验证仿真系统的科学性和可行性.该仿真系统运用Solid Works软件实现从设计、建模到仿真的一般方法,对船舶锚以及锚链等标准件建立数据库模型,导入或者建立船艏模型,然后装配,添加约束力,进行拉锚试验仿真. 相似文献
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加强海事执法队伍建设是实践科学发展观,加快水运发展,构建和谐社会的迫切需要。海事执法队伍建设中还存在一些突出的问题,本文结合本职工作实际对海事执法工作提出要求。 相似文献
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河口整治工程中施工程序的重要性 总被引:1,自引:0,他引:1
以长江口南北港分汊口护滩限流工程为例,分析了在河口整治工程中科学安排施工程序的必要性;介绍了该工程施工程序的研究成果、具体做法和初步效果,表明科学、合理的施工程序对贯彻整治意图、确保河势稳定、实现整治效果和控制工程投资具有重要作用。 相似文献
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采用基于弹性层状体系理论的BISAR软件,计算了多种实际沥青路面结构不同深度处路基荷载应力,并对计算结果进行了统计分析,提出了一定标准下不同等级公路沥青路面路基工作区深度推荐值:对于高速、一级公路及路面结构较优、重载车辆比例较小的二级公路,路基工作区深度推荐值取1.4m;对于以货运为主或重载车辆比例较大的二级及二级以下公路,路基工作区深度推荐值取1.8m,可为选择路基或地基处理深度以及措施提供参考. 相似文献
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《Vehicle System Dynamics: International Journal of Vehicle Mechanics and Mobility》2012,50(11):871-885
This article presents a model for solving solid–fluid interactions in vehicles carrying liquids. A tractor–semitrailer model is developed by incorporating suspension systems and tire dynamics. Owing to the solid–fluid interaction, equations of motion for the vehicle system are coupled. To simplify the complicated solution procedure, the coupled equations are solved separately using two different codes. Each code is analyzed separately; but as the parameters of the two codes depend on each other, the codes must be connected at the end of each time step. To determine the dynamic behavior of the system, different braking moments are applied. As the braking moments increase, braking time decreases. However, it turns out that increasing the braking moment to more than a certain level produces no significant results. It is also shown that vehicles carrying fluids need a greater amount of braking moments in comparison to vehicles carrying solids during braking. In addition, as the level of the fluid inside the tanker increases, from one-third to two-third of the tanker’s volume, the sloshing forces applied to the tanker’s walls increase. It was also concluded that the strategy used in this article to solve for the solid–fluid interaction by incorporating vehicle dynamic effects represents an effective method for determining the dynamic behavior of vehicles carrying fluids in other critical maneuvers. 相似文献
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