联肢弯剪型钢板剪力墙抗震性能试验研究

联肢钢板剪力墙结构是将2片钢板剪力墙通过钢连梁连接形成的抗侧力结构。通过对1榀1/3缩尺的4层联肢弯剪型钢板剪力墙试件进行低周往复加载试验,从滞回曲线、骨架曲线、延性、承载力及刚度退化、耗能能力等方面研究了该结构体系的抗震性能,并且对试件的屈服顺序和变形模式进行了分析。结果表明:联肢钢板剪力墙试件的延性系数达到5.03,承载力退化系数均大于0.96,承载力和刚度退化稳定,等效黏滞阻尼系数达到0.25以上,表明联肢弯剪型钢板剪力墙具有优越的抗震性能。加载过程中,连梁先于墙板发生屈服,墙板先屈曲后屈服,此后柱脚和横梁相继屈服。连梁的引入改变了结构的屈服机制,提高了整体的延性和耗能能力,能够组成多道抗震防线,且试件整体最终也体现出合理的破坏机制。整体侧移曲线呈弯剪变形模式。该试验研究更加贴合实际工程中联肢钢板剪力墙结构的应用情况,为联肢钢板剪力墙结构的进一步研究和应用提供了试验基础。

钢框架-灌浆轻钢剪力墙结构抗震性能试验研究

对钢框架-灌浆轻钢剪力墙结构足尺试件进行了水平低周往复加载试验,研究了灌浆轻钢剪力墙与钢框架的耦合效应,分析了结构的破坏模式、受力特征和耗能机理,得到了结构的承载能力、抗侧刚度、延性及耗能能力等。通过与纯钢框架及冷弯薄壁型钢灌浆墙体结构的试验结果对比,发现灌浆轻钢剪力墙通过自攻螺钉采用内嵌的方式与钢框架连接,二者具有良好的协同工作性能,框剪结构的抗剪承载力和抗侧刚度分别是钢框与墙体对应值之和的1.50倍和1.64倍,结构延性系数达5.42,抗震性能优良,研究结果可为该类结构的设计研究提供科学基础。

基于临界状态理论的海相含细粒土砂液化特性试验研究

采用饱和海相含细粒土砂开展固结不排水三轴剪切试验和轴向-扭转耦合循环剪切试验,基于临界状态理论,研究砂土状态参数与其液化特性的关系。研究结果表明:对于海相含细粒土砂,其临界孔隙比和归一化有效平均正应力具有很高的线性相关性;轴向-扭转耦合不排水循环剪切试验结果显示,循环应力比CRR相同时,状态参数ψ越大,液化振次N_(L)越小,根据研究结果提出砂土液化振次N_(L)的计算公式,N_(L)与ψ很好的满足指数函数关系。

主应力方向变化对松砂不排水动强度特性的影响

针对相对密度为Dr=30%的福建标准砂,利用新研制的土工静力-动力液压三轴-扭转多功能剪切仪进行了扭转和竖向循环耦合剪切试验和循环扭剪试验。通过对比三向非均等固结条件下的两类试验结果,着重研究了初始主应力方向变化和振动过程中主应力方向连续变化对松砂的动强度特性的影响。

主应力方向循环变化对饱和松砂不排水动力特性的影响

利用新研制的土工静力-动力液压三轴-扭转多功能剪切仪进行了主应力轴循环变化的多种模式竖向和扭转双向耦合循环剪切及普通循环扭剪试验。针对福建标准砂, 在均等固结条件下着重研究了振动过程中主应力方向的不同变化模式对饱和松砂不排水循环特性的影响。试验研究结果表明: 振动过程中主应力方向的变化方式对饱和砂土不排水动强度具有显著的影响, 在所采用的五种类型循环剪切应力路径中, 主应力方向连续旋转条件下的动强度最低。进一步的研究发现: 对于初始均等固结条件,分别采用初始平均有效固结压力和循环破坏次数归一化的循环孔隙水压力比与循环次数比之间的关系与振动过程中主应力方向变化方式无关, 这种归一化循环孔隙水压力比随广义剪应变的变化规律及累积广义剪应变与循环次数比之间关系均与振动过程中主应力方向变化方式无关。

饱和黏土动剪切模量与阻尼比的试验研究

针对饱和黏土,利用土工静力-动力液压三轴-扭转多功能剪切仪,通过不固结不排水条件下的循环扭剪和竖向-扭转耦合试验,着重探讨了大应变情况下分级加载历史和循环应力耦合对动剪切模量与阻尼比等动力特性的影响。对试验结果的分析表明:采用多个试样单级加载与采用一个试样分级加载试验得到的初始骨干曲线、动剪切模量与阻尼比都较为一致,采用分级加载试验测定动剪切模量与阻尼比是可行的;耦合循环应力中的轴向偏差应力对扭转向应力-应变滞回圈的倾斜程度及动剪切模量与阻尼比都有显著影响,尤其当扭转向循环剪应力较小时,可以认为轴向偏差应力的大小控制着动剪切模量的增大量,受扭转向剪应力的影响,轴向应力–应变滞回圈的变化模式较为复杂。

复杂应力条件下长江口原状饱和软黏土门槛循环应力比试验研究

针对取自于长江口的海洋原状饱和软黏土,利用土工静力-动力液压三轴-扭转多功能剪切仪,在控制不同初始固结参数的三向非均等固结状态和不排水条件下,分别进行了轴向和扭转双向耦合循环剪切以及循环扭剪等多种复杂循环剪切试验。分别研究了初始大主应力方向角、初始偏应力比、初始中主应力系数以及循环剪切应力模式等因素对门槛循环应力比的影响。试验结果表明,在三向非均等固结条件下,初始大主应力方向角、初始偏应力比对门槛循环应力比影响显著,门槛循环应力比随着初始大主应力方向角与初始偏应力比的增大而明显减小;而初始中主应力系数对门槛循环应力比基本没有影响。循环剪切应力模式对门槛循环应力比具有显著影响,在相同的初始固结应力条件下,循环耦合剪切试验确定的门槛循环应力比明显小于循环扭剪试验所确定的门槛循环应力比。

不同应力条件下砂土动模量特性的试验对比研究

利用新研制的三轴—扭剪多功能剪切仪分别进行了竖向与扭转双向耦合剪切振动、振动三轴和振动扭剪等3种试验,采用内置于三轴室的轴力及扭矩双出力传感器和非接触式微小位移传感器测量荷载与位移,着重研究了均等固结条件下福建标准砂的动模量特性。试验结果表明:动力双向耦合试验在扭转方向和竖向的动模量与应变之间的变化规律分别与相同条件下的动扭剪、动三轴试验结果一致;归一化动模量与按照参考应变归一化后的应变比之间的关系不再依赖于初始固结压力、密度及应力路径;动三轴试验与动扭剪试验所得到的最大动剪切模量与初始固结应力之间的关系基本一致,与此相比,由动力耦合试验中扭转向振动分量所得到的结果偏高,由动力耦合试验中竖向振动分量所得到的结果又稍低。

带可更换连梁的双肢剪力墙抗震性能试验研究

设计了1个带有传统连梁的双肢剪力墙试件和1个带有可更换连梁保险丝的新型双肢剪力墙试件,通过低周反复加载试验对2个试件进行了抗震性能对比研究.研究表明,带有可更换连梁的新型剪力墙和传统剪力墙具有相同的承载力,其等效黏滞阻尼大于传统剪力墙,强度退化小,而且新型剪力墙能够将连梁的受损位置集中在保险丝,便于震后更换.

带分段式连梁的钢筋混凝土联肢剪力墙拟静力试验及数值模拟

文章提出一种由耗能段和承重段组成的分段式钢筋混凝土连梁,通过低周往复加载试验及有限元数值模拟,对带分段式连梁的钢筋混凝土联肢剪力墙试件的抗震性能进行研究。结果表明:连梁耗能段比承重段更早开裂及屈服,且试验结束后裂缝更多更密集,表明耗能段起到主要的耗能作用,而承重段能始终可靠地承受重力荷载;试件的滞回曲线初期较饱满,呈梭形,后期出现明显的捏拢效应,曲线呈倒S形;试件的位移延性达到2.4左右,极限位移角达到1/40左右,表明其具有良好的变形性能;随着耗能段截面高度的增加,试件耗能能力增强,但承重段损伤加重。

钢桁架连梁-联肢剪力墙耗能机理及抗震性能试验研究

对设置全钢桁架连梁和设置钢筋混凝土、钢桁架混合连梁的双层联肢剪力墙平面结构进行了拟动力试验和低周反复荷载试验,研究了不同工况地震波作用下剪力墙的时程响应,以及其破坏机理、承载力、滞回延性性能、耗能机理、刚度及强度退化机理。试验结果表明:全部设置钢桁架连梁的剪力墙的刚度分布合理,耗能机理及刚度强度退化机理符合联肢剪力墙抗震设计的要求。大震时,在保证较高耗能能力的同时能够维持较高的承载力和刚度,持续约束墙肢,抗震性能优于混凝土连梁联肢剪力墙体系,是一种较理想的连梁设置方案。

不同波形下饱和黏土耦合循环剪切特性的对比研究

海洋波浪荷载在海床内土体中引起的动应力的特点是动应力幅恒定,动主应力方向连续旋转。利用土工静力–动力液压三轴–扭剪多功能扭剪仪模拟海洋波浪的加载形式,针对饱和黏土进行了竖向和扭转耦合循环剪切试验,着重对比研究了在正弦波和三角波两种不同波形条件下饱和黏土的动强度、变形特性、广义临界循环应力比与应力洛德参数。研究表明:在相同破坏振次条件下,正弦波耦合试验比三角波的动强度小,且动剪应力越小,两者动强度的相对降低也越少;在相同动剪应力幅值下正弦波耦合循环剪切的变形大于三角波的变形;耦合循环剪切试验中的广义临界循环应力比受波形的影响,正弦波的广义临界循环应力比小于三角波的;应力洛德参数的变化曲线在不同波形下也有所不同。

波浪荷载作用下非均等固结饱和粉土孔压特性研究

选用近海地区分布广泛的粉土作为研究对象,利用空心圆柱仪进行了模拟波浪荷载作用下的循环三轴-扭剪耦合试验,探寻非均等固结条件下饱和粉土孔隙水压力的发展特性。试验结果表明:非均等固结条件下,饱和粉土孔压比与广义剪应变之间的关系符合双曲线发展形式,孔压比与振次比之间的关系可以用幂函数来较好地拟合。根据极限状态的摩尔—库仑定律,推导了少粘性粉土孔隙水压力极限值计算方法,并将计算值与试验值进行了比较。孔压比和固结比的计算值与试验值之间均符合直线型关系,且固结比越小,计算值与试验值之间的差异越小。

复杂应力状态下钙质砂的动强度

利用土工静力-动力液压三轴-扭剪多功能剪切仪模拟海洋波浪的加载形式,对相对密度为30%的钙质砂进行了扭转和竖向耦合循环剪切试验,着重研究了复杂应力状态下初始主应力方向角α0和中主应力系数b对钙质砂动强度特性的影响.研究表明:初始主应力方向对钙质砂的动强度具有显著的影响,随着初始主应力方向角α0的增大,动强度明显降低,且降低的程度随破坏振动次数的增加而增加;b值对动强度也有影响,影响程度与α0相比要小.

不同应力路径下饱和粉土动强度特性试验研究

试验选用近海地区分布广泛的粉土为研究对象,利用空心圆柱仪进行了模拟波浪荷载的循环三轴-扭剪耦合试验,探讨饱和粉土在不排水条件下的动强度特性,并对液化循环周数与无因次剪切应力比之间关系进行了曲线拟合。试验结果表明,在相同的剪切应力比下,循环三轴-扭剪耦合试验的破坏振次最少,循环纯扭剪最多,循环三轴介于二者之间。通过对加载效率的计算对不同应力路径下强度的差异进行了合理解释。

Stiffness Degradation of Undisturbed Saturated Soft Clay in the Yangtze Estuary Under Complex Stress Conditions

Stiffness degradation will occur due to the generation of accumulated pore pressure in saturated soft clays under cyclic loading. The soil static-dynamic multi-purpose triaxial and torsional shear apparatus in Dalian University of Technology was employed to perform different types of test on the saturated soft marine clay in the Yangtze Estuary. Undisturbed samples of the clay were subjected to undrained cyclic vertical and torsional coupling shear and cyclic torsional shear after three-directional anisotropic consolidation with different initial consolidation parameters. Investigated were the effects of the initial orientation angle of the major principal stress, initial ratio of deviatoric stress, initial coefficient of intermediate principal stress and continuous rotation of principal stress axes on the stiffness degradation. It is found that the degradation index decreases （or degradation degree increases） significantly with increasing initial orientation angle of the major principal stress and initial ratio of deviatoric stress. Compared with the effects of the initial orientation angle of the major principal stress and initial ratio of deviatoric stress, the effect of initial coefficient of intermediate principal stress is less evident and this trend is more clearly reflected by the results of the cyclic torsional shear tests than those of the cyclic coupling shear tests. At the same cycle number, the degradation index obtained from the cyclic torsional shear test is higher than that from the cyclic coupling shear test. The main reason is that the continuous rotation in principal stress directions during cyclic coupling shear damages the original structure of the soil more than the cyclic torsional shear does.Based on a series of experiments, a mathematical model for stiffness degradation is proposed and the relevant parameters are determined.

Analysis of Wave-Induced Liquefaction in Seabed Deposits of Silt

The dynamic stress introduced in half elastic space by wave loading is characterized by the equation between the magnitude of half cyclic axial stress and cyclic torsion shear stress and the principal stress, whose direction rotates continuously and compression stress on seabed can be calculated by the use of small amplitude wave theory. With relationship curves of saturated silt of liquefaction cycles and cyclic stress ratios obtained by cyclic triaxial-torsional coupling shear tests and curve fitting method to different data points of relative density, it is suggested that the cyclic stress ratio corresponding to constant liquefaction impedance be taken as the critical cyclic stress ratio which implies liquefaction. There exists a linear relationship between critical cyclic stress ratio and relative density under different relative densities. Empirical formula for critical cyclic stress ratios of seabed liquefaction induced by wave loading under different relative densities is established. The possibility of seabed silt liquefaction and its influence factors are analyzed based on the small-amplitude wave theory and the data acquired in laboratory tests.

Effect of Initial Principal Stress Direction on the Dynamic Characteristics of Carbonate Sand

The dynamic characteristics of carbonate sand under wave loads are very important for constructions on the ocean floor. The initial principal stress direction has been known to exert some influence on the dynamic characteristics of sand during cyclic loading. In an effort to investigate this aspect of the problem, several series of cyclic undrained tests were carried out on a saturated and loose sample of carbonate sand using a geotechnical static and dynamic universal triaxial shear apparatus. In this test apparatus, a hollow cylindrical sand specimen is subjected to a simultaneous application of both triaxial and torsional modes of shear stresses, which brings about the continuous rotation of principal stress axes. The test results indicated that the initial principal stress direction has a considerable influence on the dy- namic strength of loose carbonate sand and with the increase of initial orientation of principal stress, dynamic strength will be reduced, the cyclic pore pressure increased, but the residual pore pressure reduced.

Characteristics of Pore Water Pressure of Saturated Silt Under Wave Loading

The characteristics of dynamic stress in the seabed under wave loading are constant principal stress and continuous rotation of the principal stress direction. Cyclic triaxial-torsional coupling shear tests were pefformed on saturated silt by the hollow cylinder apparatus under different relative densities, deviator stress ratios and vibration frequencies to study the development of pore water pressure of the saturated silt under wave loading. It was found that the development of pore water pressure follows the trend of ＂fast - steady - drastic＂. The turning point from fast to steady stage is not affected by relative density and deviator stress ratio. However, the turning point from steady to drastic stage relies on relative density and deviator stress ratio. The vibration cycle for the liquefaction of saturated silt decreases with increasing deviator stress ratio and increases with relative density. The vibration cycle for the liquefaction of the saturated silt increases with vibration frequency and reaches a peak value, after which it decreases with increasing vibration frequency for the relative density of 70%. But the vibration cycle for the liquefaction of saturated silt increases with vibration frequency for the relative density of 30%. The development of pore water pressure of the saturated silt is influenced by relative density and vibration frequency.

联肢加劲钢板剪力墙滞回性能试验研究与数值分析

完成了3个1/3比例的3层联肢钢板剪力墙试件的低周反复加载试验。3个试件的钢板剪力墙分别采用非加劲、槽钢竖向加劲和井字加劲的形式,钢板剪力墙的竖向边缘构件采用方钢管混凝土。得到了联肢钢板剪力墙试件的荷载-位移滞回曲线和破坏形态,对试件的骨架曲线、应力发展、延性及耗能能力等进行了分析。采用有限元软件ABAQUS对试件进行了数值模拟。结果表明:非加劲和槽钢竖向加劲墙板先屈曲后屈服,井字加劲墙板先屈服后屈曲,墙板屈服后连梁与钢板剪力墙边框梁相继屈服。方钢管混凝土柱脚屈服较早,屈服后仍具有良好的承载力和弹塑性变形能力。采用非加劲墙板的试件承载力最低,滞回环捏缩效应最严重,其次是采用槽钢竖向加劲墙板的试件。采用井字加劲墙板的试件滞回环较饱满。井字加劲和槽钢竖向加劲试件的峰值荷载分别比非加劲试件的峰值荷载提高了11.7%和6.9%,井字加劲和槽钢竖向加劲试件的等效黏滞阻尼系数分别比非加劲试件的等效黏滞阻尼系数提高了65.9%和19.9%。各试件的延性系数均大于4.5,表明不同加劲形式的联肢钢板剪力墙均具有良好的延性。数值分析与试验结果吻合较好,可充分地反映试件的滞回性能和破坏过程。加劲肋对连梁和边缘构件的内力影响较小,但可显著提高剪力墙板的抗剪承载力。相较于两片单肢钢板剪力墙,联肢钢板剪力墙的承载力和耗能能力均有大于20%的提高。