高速公路IP语音调度系统的设计与实现

介绍针对高速公路调度指挥设计的IP语音调度系统，通过IP语音技术解决高速公路调度指挥中通信方面存在的问题。论述系统的设计与结构，并对主要功能的实现原理和实现方法进行了介绍。     

《中国舰船研究》创刊10周年发展回顾及文献计量学分析

《中国舰船研究》创办10年来,持续推进品牌建设,期刊影响力不断扩大,在行业内树立了精品期刊形象。为促进期刊进一步发展,回顾期刊创办的历史和具体定位,介绍办刊的实践与发展,并采用文献计量学的方法揭示该刊影响因子和被引频次的增长情况,分析论文专业分布和高被引论文的特征,利用普赖斯公式与H指数相结合的方法确定核心作者队伍,并对作者所在机构的分布情况进行统计分析,以定量的方式给出该刊的发展现状。研究表明,该刊拥有一支较有代表性、具有较高影响力的核心作者队伍,形成了军工背景、总体集成、理论与工程应用相结合的办刊特色,未来应进一步壮大核心作者队伍,扩大稿源单位。     

汽车用电机铁心加工技术的发展

简单回顾交流发电机定子冲片加工工艺的发展过程,在此基础上介绍了当代新能源汽车用驱动电机定子铁心加工技术的现状,主要介绍了T形冲片分总成的加工方法。     

I型金属夹层结构连接构件强度特性研究及灵敏度分析

  目的  为探索波纹夹层板弯曲问题的计算方法,求解波纹夹层板的弯曲变形与应力,提出一种等效刚度法。  方法  将波纹夹层板中间芯层等效成正交异性体,应用卡氏定理求解芯层的等效弹性模量,最后应用层合板理论计算夹层板的整体刚度。依据夹层板的整体刚度,求解正交异性板的弯曲平衡方程,计算出夹层板的弯曲变形分布;通过求出的变形,应用虎克定律,即可推导夹层板的弯曲应力分布。  结果  通过算例验证,与文献[7]的方法相比,本文方法计算的刚度误差为−6.98%;与有限元法相比,本文方法计算的夹层板变形最大误差为−2.01%,应力最大误差为3.63%。  结论  这种分层累加计算整体刚度的方法,不仅可避免完全直接采用文献[7]的方法计算刚度时的复杂繁琐推导,而且用于弯曲计算还可获得较好的精度。     

Ice impact response and energy dissipation characteristics of PVC foam core sandwich plates: Experimental and numerical study

In this paper, the dynamic responses and energy dissipation characteristics of polyvinyl chloride (PVC) foam core sandwich plates under ice impact are investigated. The ice impact tests of PVC foam core sandwich plates were conducted by employing the horizontal impact experimental apparatus. The finite element simulations were conducted to analyze the dynamic response of PVC foam core sandwich plates based on soil and concrete material model for ice impactor. It was demonstrated that numerical results were in good agreement with experimental results. The deformation modes of the top facesheets were coupling of local indentation with global bending deformation, while the deformation modes of bottom facesheets were overall bending deformation. The permanent deformation of face sheets show that the impact resistance of sandwich plate is better than that of equivalent weight hull plate (EWHP). In addition, based on the actual navigation environment of ship, the effect of impact angle and ice floe shape on dynamic response and energy dissipation are analyzed.     

Fluid-structure-material coupling analysis for a floating laminated structure consisting of high-stiffness panels and a soft core

This paper presents a fluid-structure-material coupling analysis for the interaction between water waves and a very large floating laminated structure (VLFLS), which is consisted of two enhanced ultrahigh-performance concrete (UHPC) panels and a middle lightweight foamed rubber core. The representative volume element (RVE) method is used to design the mechanical properties of enhanced UHPC and foamed rubber, and the parameterized formulas are presented to reveal the dependency between macroscale mechanical properties and mesoscale hierarchical characteristics. By idealizing the rubber core as a uniformly distributed spring layer, an eighth-order differential equation of motion of the laminated structure is derived. In the context of linear potential flow theory, a hydroelastic analytical model is developed for the floating laminated structure with finite length under wave action. In the process of solving velocity potentials, a complicated dispersion equation for the wave motion below the laminated structure is derived, and this equation contains two pairs of conjugate complex roots with positive real parts. The various hydrodynamic quantities, including reflection coefficient, transmission coefficient, deflection, shear force, and bending moment, are calculated. The hydroelastic model is confirmed by considering the convergence of calculation results and the energy conservation of wave propagation. The coupled effects of wave action, material characteristics, structural parameters, and edge conditions on the hydroelastic and mechanical response of the floating laminated structure are clarified to provide important information regarding the optimal design of such structures.