Shake table testing of a multi-tower connected hybrid structure

Many single-tower reinforced concrete core wall-steel frame （RCC-SF） buildings have been built in China, but there are no buildings of different-height multi-tower hybrid system. A multi-tower RCC-SF tall building was thus studied because of its structural complexity and irregularity. First, a 1/15 scaled model structure was designed and tested on the shake table under minor, moderate, and major earthquake levels. Then, the dynamic responses of the model structure were interpreted to those of the prototype structure according to the similitude theory. Experimental results demonstrate that, despite the complexity of the structure, the lateral deformation bends as the ＂bending type＂ and the RC core walls contribute more than the steel frames to resist seismic loads. The maximum inter-story drift of the complex building under minor earthquakes is slightly beyond the elastic limitation specified in the Chinese code, and meets code requirements under major earthquakes. From the test results some suggestions are provided that could contribute favorable effect on the seismic behavior and the displacement of the building.

Digital Simulation of Full Scale Static Test of Aircraft

Full scale aircraft static test is a very important process of aircraft design, it is costly and time consuming. The testing accuracy and validity mainly depend on the rationality of the test scheme design. When the aircraft is being tested, the specimen＇s safety mainly depends on monitoring and understanding the testing data by way of evaluating the coherence with the digital simulation data synchyononsly. The test digital simulation can aid realizing above requirements and improving the test efficiency significantly during test scheme design stage or testing stage respectively. The key technologies and the solving methods of test digital simulation are presented and the application example is given.

Dynamic behavior of new cutting subgrade structure of expensive soil under train loads coupling with service environment

Expansive soil is sensitive to dry and wet environment change. And the volume deformation and inflation pressure of expansive soil may induce to cause the deformation failure of roadbed or many other adverse effects. Aimed at a high-speed railway engineering practice in the newly built Yun-Gui high-speed railway expansive soil section in China, indoor vibration test on a full-scaled new cutting subgrade model is carried out. Based on the established track-subgrade-foundation of expansive soil system dynamic model test platform, dynamic behavior of new cutting subgrade structure under train loads coupling with extreme service environment(dry, raining, and groundwater level rising) is analyzed comparatively. The results show that the subgrade dynamic response is significantly influenced by service conditions and the dynamic response of subgrade gradually becomes stable with the increasing vibration times under various service environment conditions. The vertical dynamic soil stress is related with the depth in an approximate exponential function, and the curves of vertical dynamic soil stress present a "Z" shape distribution along transverse distance. The peak value of dynamic soil stress appears below the rail, and it increases more obviously near the roadbed surface. However, the peak value of dynamic soil stress is little affected outside 5.0 m of center line. The vibration velocity and acceleration are in a quadratic curve with an increase in depth, and the raining and groundwater level rising increase both the vibration velocity and the acceleration. The vertical deformations at different depths are differently affected by service environment in roadbed. The deformation of roadbed increases sharply when the water gets in the foundation of expansive soil, and more than 60% of the total deformation of roadbed occurs in expansive soil foundation. The laid waterproofing and drainage structure layer, which weakens the dynamic stress and improves the track regularity, presents a positive effect on the control deformation of roadbed surface. An improved empirical formula is then proposed to predict the dynamic stress of ballasted tracks subgrade of expansive soil.

Research on Fixture's Effect on Properties of Single-Shear Bolt Jointed Composite Laminates Structure

The testing on the bearing strength of single-shear bolt jointed composite laminates structure is done.And the effect of the fixture on the testing results is analyzed. Then a macro-micro multi-scale analytical model combined with the improved"Generalized Method of Cells( GMC) "is developed,which is used to predict the macro bearing strength and to characterize the micro constitute material failure of the bolt jointed composite laminates structure. Both the contact conditions at the bolt/hole boundary and the contact conditions at the specimen/fixture boundary,progressive damage,and the material properties degradation are all taken account into the analytical model. Thus,the numerical simulation results agree well with the experimental results.Finally,the effect of the fixture on the testing results is characterized. The results show that the incomplete contaction between the fixture and the specimen or the lack of the lateral constraint on the specimen will affect the limited bearing strength and the offset bearing strength of the bolt jointed composite laminates structure. In addition,the lower support rigid of the fixture will affect the rigid of the bolt jointed composite laminates structure.

常泰长江大桥组合索塔锚固结构钢-混传剪构造足尺模型试验研究

常泰长江大桥索塔锚固结构采用钢箱-核芯混凝土组合结构,为研究该新型组合索塔锚固结构钢-混传剪构造的受力特性,进行钢-混传剪构造足尺模型试验研究。制作2个锚固结构足尺节段试验模型,通过压剪试验研究锚固结构的荷载~滑移曲线及应力、应变分布等受力特性,并通过有限元模型分析锚固结构的传力机理和各组件的内力分配比例,推导剪力钉剪力计算方法。结果表明:在2.14倍单索最大索力荷载作用下,锚固结构保持弹性状态,钢壁板未产生明显滑移,钢-混界面最大滑移不超过0.25 mm,该锚固结构中钢-混传剪构造至少具有2.14倍的安全系数;荷载作用下,剪力钉剪力从上至下逐渐增大,锚腹板附近底部3排剪力钉剪力较大,钢-混传剪构造至少存在剪力钉和界面摩擦力2种传剪机制,钢-混传剪构造的承载能力显著提高;钢-混传剪构造受力过程分为粘结力传力阶段和局部滑移阶段,剪力钉剪力分布不仅与沿剪切方向长度分布有关,也与荷载的大小线性相关。

南方山区民居木结构榫卯节点抗震性能试验研究

为研究截面参数和节点形式对有穿销直榫节点抗震性能的影响,首先,以梁高、梁宽为研究参数,并与有穿销透榫节点作对比,共设计制作了4个足尺节点试件;然后,通过低周往复加载试验,研究不同参数下节点的破坏形态、滞回曲线、骨架曲线、延性、强度和刚度退化及耗能能力等性能;最后,推导有穿销直榫节点的弯矩-转角理论公式,并与试验结果进行对比.研究结果表明:试件的主要破坏形态为柱内侧梁榫受拉边缘的顺纹拉裂破坏,伴随有柱内侧梁榫受压边缘的挤压变形和柱外侧梁榫的水平劈裂;节点的弯矩-转角滞回曲线呈捏缩效应明显的反Z形;在试验设计参数范围内,有穿销直榫节点的转动刚度和抗弯承载力随着梁截面高度和宽度的增大而增大,但是强度退化系数和等效黏滞阻尼系数的变化不明显;相比于有穿销透榫节点,有穿销直榫节点的正向抗弯承载力大62%,反向抗弯承载力大26%,且承载力下降更平缓,表明有穿销直榫节点具有更好的抗震性能;有穿销直榫节点理论公式所得结果与试验结果误差在9%内.

新型装配式无砟轨道设计方案理论与试验研究

为适应城市轨道交通铺设装配式无砟轨道的发展趋势,克服传统现浇整体道床混凝土浇筑量较大等缺点,提出一种新型装配式无砟轨道结构设计方案,采用理论分析与试验测试相结合的方法,建立轨道系统有限元精细化分析模型和室内实尺试验模型,对城市轨道交通新型装配式无砟轨道力学响应开展理论分析和试验研究。研究表明:新型装配式无砟轨道在列车荷载作用下轨道板最大拉应力为0.696 MPa,最大位移为0.04 mm;静载试验中轨道结构应变随着垂向静荷载增大呈线性增加趋势,在510 kN垂向加载力作用下轨道板最大压应变为38.4με,卸载后残余变形很小,未出现明显塑性变形,结构承载能力满足要求;疲劳试验中随着疲劳加载次数增加,轨道板混凝土和钢筋应变在较小范围内变化,钢筋变化最大幅值为3με,混凝土最大变化幅值为10με,结构未见裂缝,抗疲劳性能良好;轨道结构加速度和位移峰值从上往下逐层递减,衰减效果显著;结构第一阶主频为70 Hz,与车辆系统频率相差较大,不会产生共振。

襄阳东站钢屋盖超多杆连接节点设计与足尺模型试验研究

襄阳东站屋盖南北向长358m,东西向最大跨度86m,采用焊接球钢网架,整体不设变形缝,南端开设瀑布造型大洞口,由于屋盖结构超长、不连续、大悬挑及瀑布造型使得钢屋盖空间受力十分复杂,特在分叉柱柱顶沿南北向设置加强杆以加强屋盖瀑布区洞口两侧边缘约束刚度及改善结构整体受力性能。钢屋盖瀑布区悬挑端分叉柱柱顶节点相连杆件达12根之多,该节点作为屋盖结构的关键节点,其受力状态尤为复杂,创新地采用了半铸造半相贯焊连接形式并采取了构造加强措施,针对该超多杆连接节点进行了足尺模型加载试验验证,详细介绍了试验加载装置、加载方案、试验现象及试验结果,并进行了有限元对比分析。结果表明有限元对比分析结果与加载试验吻合较好;该超多杆半铸造半相贯焊连接节点构造合理、承载力高,薄弱部位出现在与铸造本体相连的接长钢管上,满足强节点弱构件、强连接弱构件的设计要求。

30 m预应力UHPC箱梁抗弯性能试验及结构优化研究

为了解大尺寸预应力UHPC箱梁的抗弯性能,以预应力UHPC公路桥——河北石磁跨线桥为背景,设计、制作1片长30 m的足尺预应力UHPC箱梁模型进行四点弯曲试验,结合有限元计算结果,分析试验现象及裂缝分布、跨中荷载~位移曲线、受拉区UHPC及筋材应力~应变曲线。在此基础上分别考虑普通钢筋配筋情况、预应力筋数、腹板厚度和底板厚度等参数对预应力UHPC箱梁进行结构优化设计研究。结果表明:箱梁破坏时受压区UHPC未压溃、受拉区钢纤维被拔出,裂缝贯通底板;根据荷载~位移曲线,箱梁受力可分为弹性阶段、裂缝发展阶段、裂缝快速发展阶段和破坏阶段;根据应力~应变曲线,受拉区UHPC在纵筋屈服时仍能贡献抗拉能力;试验现象及力学指标实测值均说明了预应力UHPC箱梁抗弯能力还有很大富裕空间,可进一步优化。完全不配置普通钢筋的预应力UHPC箱梁仍能满足抗弯承载能力极限状态设计要求;底部预应力筋数增多可有效提高受压区UHPC的抗压强度利用率;腹板厚度过薄会造成腹板主拉应力过大问题,不宜薄于8 cm;采用体外预应力的方法可有效减薄底板所需厚度。

仿生鲨鱼皮复合微纳减风阻结构的仿真与制备

仿生学与减阻技术的结合,为减阻开辟了重要的研究方向,在航空航天领域有着潜在的发展与应用前景。为提高降低风阻效果,本文对复合微纳减风阻结构进行了研究,基于仿生学原理,采用CFD仿真及激光微纳制造技术,建立了减阻结构组合模型,并在飞行器的大气传感器半球头体模型表面制造仿生鲨鱼皮复合微纳结构,即在仿生鲨鱼皮鳞片结构的基础上,通过激光干涉扫描二级微沟槽,以进一步提升减阻效果。采用CFD仿真与风洞实验相结合的方式,对减阻机理进行理论分析,完成了复合结构的微纳制造,减阻率最高可达10.3%。

衢州西站综合交通枢纽项目结构设计

杭衢高铁衢州西站综合交通枢纽及配套项目由综合交通枢纽、站前广场及匝道组成。为解决工程中大跨度拱形钢箱梁、单层网壳+钢网格筒柱、双曲面混凝土屋面以及钢箱梁弯桥等设计重难点问题,设计中对拱形钢箱梁、拉杆拱弧形屋面、钢箱梁弯桥进行结构分析,并对单层网壳+钢网格筒柱进行整体结构缩尺试验及整体结构有限元分析,同时对重要的圆管节点进行足尺试验和有限元分析。结果表明:拱形钢箱梁结构整体刚度好,设计合理;拉杆拱结构自平衡可有效减小基础推力和基础尺寸;单箱双室钢箱梁弯桥强度、刚度、抗倾覆验算均满足设计要求;单层网壳+网格筒柱整体结构在2.0倍标准组合荷载下仍能保持弹性受力状态;通过节点试验和节点有限元分析,验证了大跨度自由曲面钢结构圆管焊接节点的力学可靠性。

考虑非线性行为相似的高层结构动力试验模型简化设计方法研究

随着物理试验技术的快速发展,结构模型试验可较准确获得结构在环境荷载作用下的动力响应,但在土-结相互作用、区域群体结构、大型复杂结构的风洞、拟静力及动力等模型试验问题研究中,简单、实用、准确的结构试验简化模型仍是研究的重点。针对现有模型简化方法中非线性力学参数标定复杂、试验可行性不足等问题,提出了一种考虑非线性行为相似的高层结构动力试验模型简化设计方法,将模拟高层结构的弯、剪恢复力模型分解为线性和非线性行为的组合,其中结构非线性行为采用库仑摩擦模型模拟,因其参数简单,具有一定物理意义,可直接适用于缩尺模型动力试验研究中。基于上述理论方法,将弯剪耦合模型和平扭摩擦装置有效结合,提出了用于缩尺动力试验的物理模型设计方法及等效刚度、屈服后刚度和承载力等参数的计算方法,并建立了对应的“层间双剪切、双弯曲弹簧”力学计算模型,可通过模型试验结果较好地预测原型结构弹性及非线性阶段的动力响应。以某高层结构为例,通过数值模拟和振动台试验验证了该方法的准确性和可行性。

无砟轨道泡沫混凝土路基碎石夹层结构动力特性试验研究

为研究无砟轨道泡沫混凝土路基碎石夹层结构的动力特性和长期动力稳定性,建立夹层结构足尺试验模型,开展变频加载和循环加载试验。研究结果表明,在变频动载作用下,夹层结构的振动加速度、动位移和动土压力呈增大规律但无峰值出现,表明夹层结构未产生共振现象;为降低加载频率对比值系数的影响,建议采用底座板与路基面之间振动位移比值系数作为基床或级配碎石夹层对无砟轨道结构支承状态分析的判据。循环动载作用下,夹层结构的振动加速度、动位移和动土压力在加载至100万次后趋于稳定;相较传统土石填料路基,泡沫混凝土层能更好地均化上部荷载;经200万次动载作用后,试验模型总累积沉降为0.898 mm,碎石夹层的压缩变形占总累积沉降的82.9%。试验结果表明,在无砟轨道结构与泡沫混凝土层之间设置厚度为0.7 m的级配碎石夹层,可为线路提供平顺性和稳定性。

新型密柱支撑张弦铝合金结构设计与施工关键技术研究

世博温室项目屋盖为任意不规则曲线组成的无曲率平面,采用异形多边形网格加大透光率,基于这些特点,选型最终定为张弦铝合金网格结构。本项目挤压出新型“日”字型挤压铝合金构件以更好地承受屋盖面内弯矩,保证杆件与整体结构平面内有效传力。设计了新型刚接板式节点并通过足尺试验和精细化有限元分析研究了节点刚度与极限承载力,试验及有限元对比分析结果表明,该类节点有较高的抗剪、平面内和平面外承载力。阐述了弯扭构件数字化加工工艺及不规则铝合金特殊单元式的装配式预拼装技术,引入立面幕墙与主体结构一体化设计技术,其中立面幕墙面板设计首次通过整体协同分析考虑了主体结构变形的影响,计算结果表明设计构造满足要求。重点说明了双向正交布置拉索的施工张拉模拟计算方法,验证了索力分级张拉时结构处于安全状态,张拉完毕结构变形满足要求。

基于GUM法的风电叶片结构试验方法不确定度研究

针对风电叶片全尺寸结构试验方法,首先分析试验过程中所需测量物理量的不确定度因素来源;其次利用GUM法建立不确定度数学模型,然后评定各部分输入量的标准不确定度;最后分析得到叶片结构试验各测试物理量的合成标准不确定度和扩展不确定度,从而建立风电叶片试验不确定度的系统评价方法。

支撑与腰梁及连续墙节点抗震性能研究

研究目的:装配式建筑技术具有材料能耗低、生产效率高等优点,国内已逐步将装配式建筑技术应用于地铁车站的建设当中。为适应广州地区常见的内支撑支护体系,广州地铁提出一种新型的装配式地铁车站形式,该地铁车站的临时支护结构将作为车站的永久结构,采用“两墙合一”的设计,因此该工程对其地下连续墙-腰梁-支撑连接节点的连接精度及力学性能要求较高。本文基于该工程背景,针对连续墙-腰梁-支撑连接节点的足尺构件进行低周循环加载试验,探究在本工程中采用钢板连接及接驳器连接两种连接方案的适用性及安全性,并对比两种足尺节点的抗震性能的差异。研究结论:(1)试验结果表明两种连接方式的节点均能满足装配式地铁车站结构的设计抗震性能要求;(2)两个构件的破坏位置均为腰梁与支撑连接处界面,在进行抗震设计时应加强该处的连接强度;(3)与钢筋接驳器连接的节点相比,钢板连接节点的强度退化小、刚度大、延性好、抗震性能更优,可优先作为该类装配式地铁车站的连接方式;(4)本研究成果可为装配式地铁车站节点的抗震设计提供参考。

大尺寸壁板结构的高声强噪声试验系统研究

为获取某飞机壁板在高声强噪声激励下的疲劳寿命,本文提出了一种适用于大尺寸壁板结构的噪声试验方法。本方法结合大尺寸壁板试验工件的特点,设计了具有较小矩形截面积的气流通道,既能实现大尺寸壁板试验工件的安装,又能实现高声强噪声激励的施加;并采用了工作段两侧面同时固定试验工件的方案,有效的缩短试验周期,提高试验效率。研究结果表明:与现有技术相比较,本文提出的高声强噪声试验系统适用于大尺寸壁板结构的高声强噪声试验系统,能够有效考核大尺寸壁板结构耐受高声强噪声的能力,且造价较低,对工程实际应用一定实践价值。

预制装配式桥墩足尺推覆试验反力架装置设计

济郑高铁省界段预制装配式桥墩开展足尺推覆试验配套反力架需满足施加竖向作用荷载13400 kN、水平作用荷载3400 kN的要求,尚没有操作简便、安全可靠、满足加载要求的反力架装置。提出三种反力架设计方案,介绍了单向分离式、整体式和自平衡式方案的特点,比选确定采用自平衡整体式反力架方案,有限元数值模拟分析验证了方案的强度和刚度均满足试验要求。研发的桥墩推覆试验反力架装置目前国内型制最大,实现了水平、竖向的不借助外力加载,减小了开展大吨位推倒试验所依赖外部结构规模,能重复使用、经济性优,完全实现设计预期。

TBM掘进煤矿巷道装配式支护结构足尺试验

随着全断面掘进机(TBM)在煤矿深井岩巷掘进中的推广应用,不良地层已成为影响TBM掘进煤矿深井岩巷施工安全性和掘进效率的主要因素。为解决TBM在煤矿不良地层中巷道围岩支护困难的问题,提出了TBM掘进煤矿巷道装配式支护结构,并加工制作了装配式支护结构足尺模型,使用煤矿井巷支护结构大型试验平台,开展不同侧压系数下的支护结构足尺加载试验;通过拉杆式位移计监测支护结构关键节点位移,采用应变片监测支护结构足尺模型应变分布演化规律,同时搭建足尺模型变形摄影测量监测系统,监测获得足尺模型变形数据;开展侧压系数为λ=1.0和1.5两种加载条件下的装配式支护结构足尺模型均载和非均载试验;试验研究装配式巷道支护结构的变形破坏形态、承载力和应变分布特征,厘定支护结构承载能力的影响因素,揭示支护结构失稳破坏机理;开展支护结构数值试验,获得足尺模型试验中难以监测的轴力、弯矩等参数。结果表明:支护结构在管片接头和跨中首先出现局部失稳,进而导致结构整体失稳;侧压系数λ=1.0和1.5时,支护结构极限承载力分别为3 972.2和2 763.2 kN;随侧压系数提高,支护结构承载力呈指数型下降,结构变形破坏也更为明显;足尺模型试验中支护结构极限承载力略小于数值试验,足尺模型试验和数值试验结果一致性较好;均载试验中,支护结构接头处轴力较大,接头和管片跨中处弯矩较大,弯矩均为正值,而非均载试验中,支护结构轴力略有降低,弯矩值正负皆有,且弯矩值高于均载试验值。

Small-scale multi-axial hybrid simulation of a shear-critical reinforced concrete frame

This study presents a numerical multi-scale simulation framework which is extended to accommodate hybrid simulation （numerical-experimental integration）. The framework is enhanced with a standardized data exchange format and connected to a generalized controller interface program which facilitates communication with various types of laboratory equipment and testing configurations. A small-scale experimental program was conducted using a six degree-of-freedom hydraulic testing equipment to verify the proposed framework and provide additional data for small-scale testing of shear- critical reinforced concrete structures. The specimens were tested in a multi-axial hybrid simulation manner under a reversed cyclic loading condition simulating earthquake forces. The physical models were 1/3.23-scale representations of a beam and two columns. A mixed-type modelling technique was employed to analyze the remainder of the structures. The hybrid simulation results were compared against those obtained from a large-scale test and finite element analyses. The study found that if precautions are taken in preparing model materials and if the shear-related mechanisms are accurately considered in the numerical model, small-scale hybrid simulations can adequately simulate the behaviour of shear-critical structures. Although the findings of the study are promising, to draw general conclusions additional test data are required.