基于KENTRACK的铁路沥青混凝土底砟层疲劳特性评价

重复动载疲劳损伤是沥青混凝土底砟层的破坏形式之一。本文建立了沥青混凝土底砟层的三维有限元分析模型,分析其在列车荷载作用下的受力变形特性。采用KENTRACK设计方法分析了沥青混凝土底砟层的疲劳寿命。结果表明:沥青混凝土底砟层等厚度替代基床表层的路基结构形式在列车荷载作用下基床表层的竖向动变形和振动加速度明显减小;沥青混凝土底砟层的层底拉应变在10×10^-6~90×10^-6,处于较低水平;沥青混凝土底砟层具有良好的疲劳耐久性,可用于工程实践。     

重载铁路四线高墩连续梁桥的设计

神瓦(神木—瓦塘)铁路冯家川车站大桥为重载铁路四线桥,主桥采用4线(65+100+65)m连续梁,最大墩高85 m.桥上线间距大,上下部结构横向尺寸较大,利用有限元分析软件BSAS,MIDAS/FEA对结构受力进行了计算分析.结果表明:在主梁梁高相同的情况下,采用单箱三室截面能更好地减小主应力,采用单箱双室截面增加腹板厚度对主应力的改善有限;多线桥桥墩横向尺寸较大,空心截面设置纵肋板能很好地提高高墩的局部稳定性;主梁及桥墩各项计算指标均满足规范要求.     

既有铁路斜交盖板涵接长方案探讨

涵洞接长广泛应用于既有铁路改造及增建二线铁路中,斜交盖板涵接长是其中特殊的一类。根据已建成的增建渝怀二线21座斜交接长涵洞,首先按孔径、斜交角度、填土厚度分类汇总;然后采用MIDAS建立有限元模型,分析不同类型盖板裂缝及应力;最后根据计算结果并结合不同工程实际条件,总结出5种斜交盖板涵洞接长方案。实践证明,这5种方案对铁路运输影响小,施工安全,快捷。     

北京地铁区间联络通道冻结法施工技术

北京地铁一区间联络通道兼泵房采取冻结法施工,冻土帷幕是冻结法施工的关键所在。施工前对盐水温度、冻土温度、泄压孔压力进行现场监测,分析冻土帷幕发展规律,判定冻土帷幕各参数是否达到施工指标。通道开挖时获得冻土帷幕信息,以此来验证监测数据的准确性。结果表明:温度随着时间的变化先是急剧下降,之后缓慢下降趋于稳定;冻结壁交圈发生在泄压孔压力开始增大时,泄压孔压力稳定表明冻土帷幕基本形成。开挖施工获得的冻土帷幕信息证实了监测数据的准确性。     

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。     

上游静止柱体对圆柱体结构尾激振动的影响

文章运用半隐式特征线分裂算子有限元算法对串列布置的静止上游柱体和下游圆柱的尾激振动问题进行了数值模拟研究。数值结果表明:上游柱体结构的形状、尺寸比(d/D)和折减速度(Ur)三个参数对下游圆柱体结构的动力响应、运动轨迹与涡脱落模态有着显著的影响,且与单圆柱工况相比存在明显区别;随着尺寸比的增大,上/下游柱体结构之间的互扰作用会由流致效应逐渐转变为尾流效应,使得频率特性发生变化,并会导致下游圆柱体结构的振动响应增强;当d/D=0.5和1.0时,下游圆柱体结构的运动轨迹主要为“8”字形;当d/D=1.5时,除了“8”字形外,运动轨迹还会呈现双弯刀形、“双8”字形和不规则形状。通过对流体力系数与位移时程曲线及位移PSD曲线特性进行分析,揭示了其相互作用的内在机理。另外,下游圆柱体结构的尾流场特性也会随参数的变化而变化,其涡脱落模态主要为2S、P+S和2P三种。     

味精废水处理工艺研究

首先分析、列出味精废水的主要成分,简述国内外处理这类废水的方法和技术。作者重点介绍其对高浓度味精废水和低浓度的味精厂混合排放污水处理所作的研究和试验：对高浓度味精废水采用混凝法,对低浓度的混合污水采用ＳＢＲ法（序批法）。试验结果表明,排放水水质达到国家规定的标准,本项研究试验成果可应用到工程实际中去。     

Dynamic behavior of scaled tubular K-joints subjected to impact loads

This paper examines the dynamic behavior of the tubular K-joints in offshore platforms by means of experimental and numerical studies. The structural response is studied through Falling Weight Impact Tester(FWIT) with three different falling heights. A non-direct similitude method is developed and applied to the scaled K-joint models. The experimental results, including final deformed shapes and impact force responses, are reported to be useful for further benchmark studies. The finite element models are then developed by commercial software LS-DYNA, where nonlinear material properties are considered based on the corresponding tensile tests. Good correspondence between the numerical and experimental results is achieved, and relevant sensitivity analyses of numerical results are carried out to verify the reliability of the numerical models. Finally, the influence of the strain-rate definition and the reliability of the similarity are discussed. In general, the impact response in the present study is significantly dependent on the definition of dynamic material characteristics. The results obtained from Cowper-Symonds model with constants derived from the dynamic tensile test yield a good estimation when compared with the experimental results. Besides, scaled models tend to obtain un-conservative prediction results, and the developed non-direct similitude method is appropriate for the application.     

On the fluid-structure response of elastic-plastic ship sides subjected to impact loads

This paper presents a simplified numerical model capable of analysing the interaction between the structural dynamic response of elastic-plastic struck plate wall of a fluid tank subjected to wedge impact and the resulting fluid motion. The Variational Finite Difference Method (VFDM) is applied to analyse the structural dynamics of the struck plate and 2-D linear potential flow theory is used to study the resulting fluid motion and its effects on the structural dynamics of the struck plate. Experiments of a wedge indenter impacting with both empty and 90% filled tanks are carried out to study the structural deformation of the struck plate. The accuracy of the developed numerical model is validated with published results and experimental results, and good agreement is achieved. Through the comparison of the impact behaviour of empty and partially filled water tank, it is found that the resulting water motion helps to reduce the structural deformation of the struck plate since part of the impact energy is dissipated by the resulting water motion. Parametric studies are performed to investigate the effect of impact velocity and water level on the structural dynamics of the struck plate of a partially filled water tank. A case study is also conducted to demonstrate the potential application of the proposed method in analysing ship-ice impact problems.     

Numerical simulation of level ice impact on landing craft bow considering the transverse isotropy of Baltic Sea ice based on XFEM

Ice bending is a major failure mechanism of level ice when ships and marine structures interact with level ice. This paper aims to investigate the ice bending and ice load when level ice collides on ships and marine structures using numerical simulation method, and compare the numerical results with field test. The fracture of ice is simulated with extended finite element method (XFEM), and cohesive zone concept is used to describe the crack propagation. In order to consider the characteristics of S2 columnar ice, a transversely isotropic elastic material model is used for the ice bulk elements, and a transversely isotropic Tsai-Wu failure criterion is adopted to predict the initiation of cracks. A well-controlled field test of a landing craft bow colliding with level ice in Baltic Sea is simulated to verify the numerical scheme. The ice plate's continuous deformation, crack initiation and crack propagation at different impact velocities and angles are simulated and the results are discussed. In the simulation, the bending crack emerges at the midline of the top surface of ice plate, then propagates towards free boundary, and finally a circumferential crack forms. It is found that with the impact velocity increases, the bending load increases and the fracture size (perpendicular distance from the crack to the contact edge) decreases. And as the angle between the landing craft bow and vertical direction increases, the bending load and the fracture size decrease. The simulated results corresponds well with the field test. The competition between the circumferential crack and radial crack is also found in the simulation and will be discussed in this paper. The results show that this method well simulates the bending of level ice and predict the ice load, and provides a good approach for investigating the mechanism of different forms of level ice fracture.