A simple formulation for predicting the ultimate strength of ships

The aim of this study is to derive a simple analytical formula for predicting the ultimate collapse strength of a single- and double-hull ship under a vertical bending moment, and also to characterize the accuracy and applicability for earlier approximate formulations. It is known that a ship hull will reach the overall collapse state if both collapse of the compression flange and yielding of the tension flange occur. Side shells in the vicinity of the compression and the tension flanges will often fail also, but the material around the final neutral axis will remain in the elastic state. Based on this observation, a credible distribution of longitudinal stresses around the hull section at the overall collapse state is assumed, and an explicit analytical equation for calculating the hull ultimate strength is obtained. A comparison between the derived formula and existing expressions is made for largescale box girder models, a one-third-scale frigate hull model, and full-scale ship hulls.List of symbols A _B total sectional area of outer bottom - A _B total sectional area of inner bottom - A _D total sectional area of deck - A _S half-sectional area of all sides (including longitudinal bulkheads and inner sides) - a _s sectional area of a longitudinal stiffener with effective plating - b breadth of plate between longitudinal stiffeners - D hull depth - D _B height of double bottom - E Young's modulus - g neutral axis position above the base line in the sagging condition or below the deck in the hogging condition - H depth of hull section in linear elastic state - I _s moment of inertia of a longitudinal stiffener with effective plating - l length of a longitudinal stiffener between transverse beams - M _E elastic bending moment - M _p fully plastic bending moment of hull section - M _u ultimate bending moment capacity of hull section - M _uh ,M _us ultimate bending moment in hogging or sagging conditions - r radius of gyration of a longitudinal stiffener with effective plating [=(I _s /a _s )^1/2] - t plate thickness - Z elastic section modulus at the compression flange - Z _B ,Z _D elastic section modulus at bottom or deck - slenderness ratio of plate between stiffeners [= (b/t)(_y/E)^1/2] - slenderness ratio of a longitudinal stiffener with effective plating [=(l/r)(_y/E)^1/2] - _y yield strength of the material - _yB , _yB , _yD yield strength of outer bottom, inner bottom - _yS deck, or side - _u ultimate buckling strength of the compression flange - _uB , _uB , _uD ultimate buckling strength of outer bottom - _uS inner bottom, deck, or side     

材料、结构和工艺因素对高强度螺栓疲劳性能的影响试验研究

对影响高强度螺栓疲劳性能的材料、结构和工艺等因素进行了较广泛的对比试验研究。比较了6种材料疲劳试样的疲劳性能;考察了硬度、再回火、去应力退火、表面脱碳、滚丝/磷化的先后顺序、头下圆角粗糙度、滚丝轮螺纹牙形、头下圆角过渡形式等因素对高强度螺栓疲劳性能的影响。     

压实质量的动态控制

探讨了压路机在压实施工中，压实质量的动态控制问题。结合课题实践，构思出了压实质量动态适时控制系统的工作框图。     

钢管混凝土拱桥在车辆荷载作用下的非线性动力响应分析

根据随动硬化理论和钢管混凝土组合材料恢复力模型 ,提出了复杂应力状态下钢管混凝土组合材料的弹塑性应力应变关系。采用非线性有限元法 ,对一钢管混凝土拱桥进行移动车辆荷载作用下车—桥体系的动力响应分析 ,并进一步研究钢管混凝土组合材料进入塑性后对体系振动的影响 ,取得了较满意的结果 ,为钢管混凝土拱桥动力性能评价提供参考。     

基于弹性动力分析的工程机械集成化设计系统

为了解次目前国内工程机械设计中由于动力学分析水平和设计效率较低而造成的产品性能落后这一长期存在的问题，首次引入弹性动力分析理论建立了工程机械工作装置的通用弹性动力分析模型，以此为基础建立了工程机械动力学仿真系统，并建立了工程机械方案设计与部件选型专家系统以实现总体方案设计、部件选型和整机动力匹配的自动化，最后利用信息集成技术建立了基于弹性动力分析的工程机械集成化设计系统。     

滑模摊铺水泥混凝土路面施工配合比计算方法

本文针对我国目前大规模采用滑模摊铺机施工高速公路水泥混凝土路面，为适应滑模摊铺施工机械性能，充分发挥滑模摊铺机施工优势，确保水泥混凝土路面强度、平整度等指标而提出的水泥混凝土施工配合比计算方法。     

低强度桩复合地基处理桥头跳车现场试验研究

介绍了浙江台州浃里陈大桥成功地采用低强度混凝土桩复合地基处理桥头跳车问题，同时通过现场载荷试验、桩顶和桩间土的土压力测试以及沉降观测，较全面地研究了低强度桩复合地基承载力和桩土受力特性以及沉降变化规律，得到了一些可供理论研究和工程实践借鉴的有益结论。     

潭邵高速公路顺层滑坡整治

通过对某顺层古滑坡的现场调查，分析判断出古滑坡的滑动范围、滑动面，并对滑动面抗剪强度参数进行了反分析计算。据此对古滑坡体进行了初步整治设计，实际整治时未进行防水措施，抗滑指标进一步下降，并对此时软化滑动面抗剪强度进行了计算分析。结果对K89-95段的调查分析，对此区段的切方边坡违背工程地质选线原则导致的后果进行了反思。     

高压共轨式电控柴油机动态仿真研究

建立了一个准稳态的发动机非线性模型,该模型主要用于研究高压共轨式电控柴油机的动态特性以及各种控制参数对发动机性能的影响。以车用YC6112ZLQ柴油机为仿真对象,在MATLAB/SIMULINK环境下完成模型的建立并进行了动态过程的实时仿真,给出了典型稳态及动态过程的仿真结果。     

汽车无线电导向行驶系统

介绍GPS系统概况、GPS全球卫星定位系统的基本原理及固定电台汽车导向行驶系统。