基于AR模型的并靠两船相对运动预报研究

根据两船相对运动的特点,利用两船模相对运动的测量数据,运用基于自回归模型的时间序列分析法,建立了两船相对运动的数学模型,并给出了运动姿态的预报值.通过本方法的研究,可以得到满意的相对运动预报精度,为两船补给波浪、补偿装置的开发打下了理论基础.     

软弱富水地层浅埋暗挖隧道地表沉降和支护结构受力的模型试验

以莞惠城际轨道交通工程项目GZH-5标段中DK32+300~DK32+927.303段为背景,通过2组模型试验,其中一组无超前注浆,另一组进行超前注浆,研究软弱富水地层浅埋暗挖隧道地表沉降和支护结构受力规律及超前注浆对其受力变形造成的影响,最后,针对软弱富水地层浅埋暗挖隧道施工,提出几点隧道工程设计和施工的相关建议。     

基于基准有限元模型的箱梁TMD振动控制研究

针对高架桥梁结构引起的振动噪声问题,研究TMD控制箱梁结构振动的特性。为了获得精准的箱梁有限元模型,首先以铁路32 m简支箱梁桥为原型,按10:1的几何相似比设计制作简支箱梁缩尺试验模型,应用ANSYS软件建立初始动力有限元模型;对有限元模型模态分析与试验模型模态测试得到的自由模态信息进行误差分析,并采用基于灵敏度分析的模型修正技术对初始动力有限元模型弹性模量和密度进行修正,得到基准有限元模型,误差确认结果显示修正后的有限元模型更精准地反应箱梁的振动特性;进一步利用基准有限元模型,开展TMD控制简支箱梁桥振动的研究,研究结果表明TMD对于抑制桥梁竖向共振有很好的效果。     

铁路路基动态变形模量的数值模拟分析

介绍铁路路基动态变形模量理论计算公式的推导及动态变形模量的测试原理,采用有限元软件模拟动态变形模量的测试过程,分析承载板与土体接触压力、路基动态变形模量的影响因素,并计算动态变形模量的有效测试深度.结果表明:在承载板中心一定范围内,接触压力模拟结果较理论计算值大;土体的动弹性模量对接触压力影响很小,可以忽略;路基动态变形模量测试冲击荷载作用下,土体只发生弹性变形;动态变形模量与土体动弹性模量呈线性关系,路基动态变形模量的模拟结果大于理论计算值;土体的泊松比对动态变形模量影响较小;动态变形模量有效测试深度建议取0.5~0.6 m.     

Eco-driving behaviors of electric vehicle users: A survey study

Previous research has shown that electric vehicle (EV) users could behave differently compared to internal combustion engine vehicle (ICEV) drivers due to their consciousness or practices of eco-driving, but very limited research has fully investigated this assumption. This research explores this topic through investigating EV drivers’ eco-driving behaviors and motivations. We first conducted a questionnaire survey on EV drivers’ driving behavior and some hypothetical decisions of their driving. It indicates various characteristics between EV and ICEV commuters, including self-reported daily driving habits, preferences of route choices, tradeoff between travel time and energy saving, and adoption of in-vehicle display (IVD) technologies. Then, through statistical analysis with Fisher’s exact test and Mann-Whitney U test, this research reveals that, compared to ICEV drivers, EV drivers possess significantly calmer driving maneuvers and more fuel-efficient driving habits such as trip chaining. The survey data also show that EV drivers are much more willing to save energy in compensation of travel time. Furthermore, the survey data indicate that EV drivers are more willing to adopt eco-friendly IVD technologies. All these findings are expected to improve the understanding of some unique behavior found in EV drivers.     

Buckle propagation of damaged SHCC sandwich pipes: Experimental tests and numerical simulation

Sandwich pipe (SP) combining high-strength performance and thermal insulation has been considered an effective solution for oil and gas transportation in ultra-deepwater. Strain hardening cementitious composite (SHCC) is well known for its capacity to withstand both tensile load and external hydrostatic pressure. The sandwich pipe considered in the research is constituted of concentric steel pipes with SHCC annular layer. In the present research work, the SHCC was manufactured, and full scale sandwich pipes were assembled. Intact and damaged specimens were submitted to controlled external pressure in a hyperbaric chamber to obtain the collapse and propagation pressures, respectively. Modeling and simulation of the buckle propagation of the SPs were correlated with the experimental results. The results show that sandwich pipe with SHCC core has an excellent structural strength under high external pressure in both intact and damaged conditions. Moreover, the results also show that the interaction between the annular and the inner/outer pipes provides a significant contribution to the buckling resistance under propagation pressure.     

新型隧道结构纵向连接筋对支护性能影响研究

隧道工程中,纵向连接筋多为焊接或者插入式连接,但纵向连接筋对隧道支护性能影响尚不明确,没有相关试验分析。基于此问题,按照初支二衬联拱隧道新型支护体系,设计采用不同纵向连接筋形式初期支护构件,采用MTS大型拟动力加载系统进行室内加载试验,对采用纵向连接筋构件的力学特性进行研究,得到如下结论:(1)纵向连接筋在初期支护中稳定型钢、参与结构受力,加强隧道支护承载能力及抗变形能力,提升隧道整体性、稳定性;(2)纵向连接筋插入式连接在提升构件承载力及抗变形能力要优于焊接连接,该影响主要体现在加载后期;(3)该试验对比了几种不同纵向连接筋构件受力及变形情况,根据试验结果可确定纵向连接筋最优设置形式,为实际工程提供参考。     

南昌地铁砾砂层渣土改良技术试验研究

随着土压平衡盾构的广泛推广和应用,其地层适应性也越来越强,但盾构机在一些特殊地层中掘进时,渣土无法满足盾构施工对渣土流塑性的要求,易造成刀盘结饼、掌子面压力不稳定、刀盘磨损严重等问题。泡沫渣土改良技术是保证施工安全、顺利进行的关键技术之一。本文针对两种工程现场常用的泡沫进行泡沫基础性能试验,并以南昌地铁3号线盾构区间为工程背景,针对该区间砾砂地层进行改良渣土坍落度试验,对不同注入率和不同发泡剂的改良效果进行分析。研究发现,两种泡沫剂的建议使用浓度为3%;渣土流动性随泡沫注入率的增大而提高。在试验所用土样条件下,建议施工时使用的泡沫注入率为20%~30%。     

成昆铁路矮塔斜拉桥索梁锚固区模型试验研究北大核心

为研究铁路矮塔斜拉桥索梁锚固区的受力形式,以成昆铁路金沙江大桥为工程背景,针对该桥采用的新型梁顶混凝土锚固构造,通过缩尺模型试验研究其在不同荷载下的应力分布和开裂特征。结果表明:在斜拉桥成桥恒载索力作用以及最不利荷载组合索力作用下,C7锚固块更容易发生破坏,将其作为试验构件开展缩尺模型试验,发现锚固块在不同张拉荷载作用下张拉至设计索力的过程中,应变增幅基本上线性增加,卸载后同样呈线性减小,说明混凝土受力处在线弹性阶段,且应力在规范要求范围内。在试验荷载加载至140%设计索力时,锚固块前端倒角位置开始出现细小裂纹且随荷载的增加不断开展。当荷载卸载至0时,之前出现的裂缝随荷载的减小逐渐闭合,宽度肉眼不可见,表明该构造能够满足正常使用要求且具备足够的安全储备。     

Structural safety assessment procedure for membrane-type LNG CCS considering hydroelasticity effect

As environmental regulations have become more onerous, the demand for LNG and LNG carriers has increased. The LNG cargo containment system (LNG CCS) is one of the most important facilities in LNG carriers, and many membrane types of LNG CCS have been developed so far. Traditionally, sloshing model tests are performed and a series of statistical approaches are used to obtain design sloshing pressures. Then, these design loads are utilized to analyze the structural safety of LNG CCS. In the sloshing model test, the flat and almost rigid plate is used as the LNG CCS instead of a real model, and thus, the hydroelasticity effect cannot be considered. In the present research, the effect of hydroelasticity on sloshing pressure was investigated in a fluid-structure interaction simulation. A wet drop simulation was conducted, and its results subsequently were compared with wet drop experimental test results to ensure their validity. Then, two types of structure model, namely a flat-rigid plate model and a flat-flexible CCS model, were generated to investigate the effect of hydroelasticity. Also, a fluid hitting analysis model was devised to realize the sloshing phenomenon, and the two generated structure models were applied as the structure domain in the analysis. In the fluid hitting simulations, it was found that the hydroelasticity effect on sloshing pressure is significant. Thus, correction factors, which are quantitative values of the effect of hydroelasticity, were derived (and are proposed herein). Finally, a structural safety assessment procedure for consideration of the hydroelasticity effect was derived (and is suggested herein).