一种结构垂向冲击载荷测量方法分析研究

某些作用在舰船结构上的瞬态动载荷,由于受到客观条件限制（比如空间狭小）,不方便直接通过压力传感器获得其大小,而该载荷对于船体结构设计又关系重大,如何取得外载荷曲线便成了十分关键的问题。针对实船某承受特殊冲击载荷的基座结构,通过测量其结构动应变,利用材料应变-应力关系曲线得出了冲击载荷的时间历程曲线,最后用有限元法对该冲击载荷测量曲线进行验证。结果表明,当结构应变率小于3mm/mm/s时,可采用静态材料应变-应力关系曲线对结构冲击载荷进行测量计算,从而为此类结构外载荷测量方法提供参考。     

基于混合法的内部结构声分析

有限元法（FEM）是广泛接受的分析耦合结构声（SA）系统动力响应的预报工具。由于随频率增加计算模型也增加导致基于单元的方法在实际中约束在低频段。一种替代方法是基于间接Trefftz法的基于波动方法（WBM）。但WBM的不足之处在于高计算效率只针对中度复杂的几何模型。为了利用两者的优势：FEM的广泛应用和WBM的高收敛特性,提出了混合FE-WB预报法（FEM-WBM）。基本原理是将FE模型中较大且几何简单的部分采用WBM代替。得到的耦合模型仍具有较少的自由度。简要描述了FEM、WBM以及混合FEM-WBM的理论基础。最后将该方法应用于一个简单的结构声模型,理论分析结果与数值仿真计算结果吻合较好,该混合方法有潜力覆盖中频段。     

边坡稳定性分析的广义Bishop法

鉴于简化B ishop法作为一种简单实用且精度较高的极限平衡方法却仅限于分析圆弧破坏的缺陷,提出将B ishop法应用于任意滑裂面的广义方法.基于极限平衡理论和简化B ishop法的简化条件,推导其用于一般滑裂面破坏的边坡安全系数计算公式.通过实例分析考证比较该法的精度,并提出取矩中心的确定方法,以保证竖向力简化假设下的精度,为土坡稳定性分析提供了一种简单通用的方法.     

集装箱吊具开闭锁机构的系统分析

介绍了集装箱码头岸桥吊具开闭锁机构电气、液压、机械三大系统的工作原理以及它们相互之前的关系,通过吊具开闭锁机构日常的故障深入地分析了这三大系统重要特点,并介绍了该机构一些隐性故障的预防以及解决方法。     

时间反演在浅海波导环境中的应用研究

本文基于伪谱方法对浅海波导环境中的时间反演聚焦和时间反演主动声纳进行了计算,给出了声源频率为100Hz的正演和反演声场分布的演化过程。     

块石基床爆夯技术在重力式码头的应用及质量控制

爆夯技术近年在重力式码头抛石基床上得到广泛应用,本文结合福建某重力式码头基床、地基及水文的实际情况,总结块石基床水下爆炸夯实技术的设计、施工工艺、质量控制及爆破的安全控制,以供类似工程参考。     

浅谈粉煤灰路基的施工

在江汉平原,人均耕地面积较少,土地肥沃,取土进行路基填筑会减少大量的耕地。本标段充分利用陈年积压、占用大量良田的二期粉煤灰进行路基填筑,既还建了良田,又解决了环境污染。结合工程实际,介绍了先填筑粉煤灰再填筑包边土路基的施工方法。     

Two-dimensional numerical simulation and experiment on strongly nonlinear wave–body interactions

A constrained interpolation profile (CIP)-based Cartesian grid method for strongly nonlinear wave–body interaction problems is presented and validated by a newly designed experiment, which is performed in a two-dimensional wave channel. In the experiment, a floating body that has a rectangular section shape is used. A superstructure is installed on the deck and a small floating-body freeboard is adopted in order to easily obtain water-on-deck phenomena. A forced oscillation test in heave and a wave–body interaction test are carried out. The numerical simulation is performed by the CIP-based Cartesian grid method, which is described in this paper. The CIP scheme is applied in the Cartesian grid-based flow solver. New improvements of the method include an interface-capturing method that applies the tangent of hyperbola for interface capturing (THINC) scheme and a virtual particle method for the floating body. The efficiency of the THINC scheme is shown by a dam-breaking computation. Numerical simulations on the experimental problem for both the forced oscillation test and the wave–body interaction test are carried out, and the results are compared to the measurements. All of the comparisons are reasonably good. It is shown, based on the numerical examples, that the present CIP-based Cartesian grid method is an accurate and efficient method for predicting strongly nonlinear wave–body interactions.     

Database of sail shapes versus sail performance and validation of numerical calculations for the upwind condition

A database of full-scale three-dimensional sail shapes is presented with the aerodynamic coefficients for the upwind condition of International Measurement System (IMS) type sails. Three-dimensional shape data are used for the input of numerical calculations and the results are compared with the measured sail performance. The sail shapes and performance were measured using sail dynamometer boat Fujin. This is a boat of 10.3-m length overall in which load cells and CCD cameras were installed to simultaneously measure the sail forces and shapes. At the same time, the sailing conditions of the boat, e.g., boat speed, heel angle, wind speed, and wind angle, were measured. The sail configurations tested were: mainsail with 130% jib, mainsail with 75% jib, and mainsail alone. Sail shapes were measured at several vertical positions for the shape parameters defined by: chord length, maximum draft, maximum draft position, entry angle at the luff, and exit angle at the leech, all of which finally yield three-dimensional coordinates of the sail geometry. The tabulated shape data, along with aerodynamic coefficients, are presented in this article. In addition, numerical flow simulations were performed for the measured sail shapes and the sailing conditions to investigate the capability and limitations of the methods through detailed comparison with the measurements. Two numerical methods were used: a vortex lattice method (VLM) and a Reynolds-averaged Navier–Stokes (RANS)-based computational fluid dynamics method. The sail shape database, in association with the numerical results, provides a good benchmark for the sail performance analysis of the upwind condition of IMS type sails.     

Water entry of a bow-flare ship section with roll angle

The two-dimensional water entry of a bow-flare ship section with constant roll angle, or heel angle, was studied by using a boundary element method. The fully nonlinear free surface conditions and exact body boundary conditions were satisfied. Nonviscous flow separation from the knuckles of the section or from the curved bottom could be simulated. The numerical calculations were compared with existing experimental results. First, the effects of roll angle were investigated and then the characteristics associated with large roll angles were examined in particular. The evolution of the free surfaces and the pressure distributions on the section surface are illustrated and the influence of nonviscous flow separation from the leeward section surface is discussed.