振动传播与阻尼试验数值研究1

Q4 Engineering
A. Saarenheimo, M. Borgerhoff, K. Calonius, Anthony Darraba, A. Hamelin, S. G. Khasraghy, A. Karbassi, C. Schneeberger, Matthias Stadler, M. Tuomala, Pekka Välikangas
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引用次数: 1

摘要

地震和飞机撞击引起的振动会在整个建筑物中传播,因此在设计ssc(结构、系统和部件)时需要考虑这些因素。设计实践中主要采用线性计算方法,规范和标准只在线性结构分析中考虑阻尼比。诱导振动,特别是在受损的混凝土结构中,还没有足够广泛的研究来优化结构框架和/或合格的系统和组件。在对标分析程序和方法时,也需要损伤钢筋混凝土阻尼性能的实验数据。最近,在IMPACT项目中,在VTT上进行了一种考虑振动传播的新型测试系列。试验目标是一个钢筋混凝土结构,有两个平行的墙连接到楼板上。前墙还由三角形的侧墙支撑,侧墙也与楼板相连。试验结构由弹性轴承座支撑,后管主要抗压,杆主要抗拉。为了获得不同损伤等级下混凝土结构的振动传播信息,对同一结构进行了6次试验。每次可变形的不锈钢导弹的质量为50公斤。命中点位于前墙的中间。前4次试验(V1A- d)的冲击速度约为110 m/s,其余2次试验(V1E和F)的冲击速度约为60 m/s。本文将V1A和V1F试验的数值结果与相应的实验结果进行了比较。计算结果包括加速度、位移及其响应谱和应变,并与实验结果进行了比较。计算中使用了五种有限元程序:Abaqus, Europlexus, LS-DYNA, SOFiSTiK和内部代码(IHC)。目前研究的有限元代码大多采用壳单元。在Abaqus和SOFiSTiK中,通过将截面分层来模拟壳截面的非线性行为。强化也被建模为层。在Europlexus和IHC中,采用了另一种方法,即混凝土和钢筋的非线性行为在壳厚方向上预先均匀化,得到了壳截面上有效的应力结果和广义应变之间的关系。在LS-DYNA中,三维实体单元用于模拟混凝土,梁单元用于模拟钢筋。除SOFiSTiK采用隐式积分法外,运动方程的积分均采用显式中心差分时间积分法。上述有限元程序的建模和计算是相互独立的。用LS-DYNA作为盲练习进行计算。从基准的角度考虑结果仍在进行中。然而,在最大位移、加速度和应变等主要设计参数水平上,分析结果明显符合合理的试井结果。频谱估计也比较好。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical studies on vibration propagation and damping test V1
Earthquakes and aircraft impacts induce vibrations that propagate throughout the entire building and they need to be considered in designing SSCs (Structures, Systems and Components). Mainly linear calculation methods have been in use in design practice and the codes and standards consider damping ratios only for linear structural analyses. Induced vibrations, especially in damaged concrete structures, have not been studied extensively enough for optimization of structural frameworks and/or qualified systems and components. Experimental data on damping properties of damaged reinforced concrete are needed also for benchmarking analysis programs and methods. Recently, within IMPACT project, a new type of test series considering vibration propagation has been carried out at VTT. The test target is a reinforced concrete structure with two parallel walls connected to a floor slab. The front wall is additionally supported by triangular shaped side walls which are connected to the floor slab too. The test structure is supported on elastomeric bearing pads, with back pipes effective mainly in compression and with bars effective in tension. In order to obtain information on vibration propagation in damaged concrete structure at different levels of damage grades the same structure was tested six times. At each time the mass of the deformable stainless steel missile was 50 kg. The hit point located in the middle of the front wall. The impact velocity was about 110 m/s in the first four tests (V1A-D) and about 60 m/s in the remaining two tests (V1E and F). In this paper, numerical results on tests V1A and V1F are compared with the corresponding experimental ones. The calculated results, such as accelerations, displacements, their response spectra and strains, are compared with experimental measurements. Five finite element (FE) programs are used in computations: Abaqus, Europlexus, LS-DYNA, SOFiSTiK and an in-house code (IHC). Most of the FE-codes in the present study use shell elements. In Abaqus and SOFiSTiK non-linear behaviour of shell section is modelled by dividing the cross section into layers. Reinforcements are also modelled as layers. In Europlexus and IHC, an alternative approach is adopted in which the non-linear behaviour of concrete and reinforcement is homogenized beforehand in the shell thickness direction obtaining relations between stress resultants and generalized strains valid for the shell section. In LS-DYNA, 3D solid elements for modelling concrete and beam elements for modelling reinforcements are used. Equations of motion are integrated with explicit central difference time integration method, except in SOFiSTiK implicit integration method is used. Modelling and computations with the mentioned FE-programs are made independently of each other. Computations with LS-DYNA are carried out as blind exercises. Consideration of the results from benchmarking point of view is still on-going. However it is evident that analysed results follow reasonable well test results in main design parameter level such as maximum displacements, accelerations and strains. Also frequency spectra are estimated reasonably well.
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Rakenteiden Mekaniikka
Rakenteiden Mekaniikka Engineering-Mechanical Engineering
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