Analytical Investigation into the Rotational Performance of Glulam Bolted Beam-Column Connections under Coupled Bending Moment and Shear Force

Considering the glulam beam-column connection form and the number of bolts,monotonic loading test and finite element analysis was carried out on 9 connection specimens in 3 groups to study the rotational performance and failure mode of the connection.The test results revealed that compared with U-shaped connectors,T-shaped connectors can effectively improve the ductility of connections,and the increase in the number of bolts can reduce the initial stiffness and ductility of connections.By theoretical analysis,formulas for calculating the initial stiffness and ultimate moment of connections were deduced.Subsequently,the moment-rotation theoretical model of connections was established based on the formulas,which were validated according to the test data and simulation results.The proposed model can not only improve the current theoretical system of heavy-duty glulam beam-column structure but also provide a theoretical basis for calculating the mechanical properties of the glulam beam-column connection.

Design on the Prestressed Concrete Frame Beam-column

A bidirectional ribbed concrete beam slab structure was widly adopted for the upper space of industrial buildings.To maintain ample space and minimize the presence of conventional columns,a bidirectional prestressed concrete beam is often employed.The intersection node of the prestressed concrete frame beam column was characterized by a high density of steel reinforcement,significant structural loads,and complex construction requirements.To ensure the quality,safety,and progress of prestressed frame beamcolumn intersection nodes during construction,this article proposed a new technology for constructing such nodes,which includes setting the tensioning and haunching ends of nodes at different positions,using ABAQUS finite element software to optimize the design of cross-sectional dimensions,conducting stress analysis simulations.

Seismic performance of interior precast concrete beam-column connections with T-section steel inserts under cyclic loading

An experimental investigation was conducted to study the performance of precast beam-column concrete connections using T-section steel inserts into the concrete beam and joint core,under reversed cyclic loading.Six 2/3-scale interior beam-column subassemblies,one monolithic concrete specimen and five precast concrete specimens were tested.One precast specimen was a simple connection for a gravity load resistant design.Other precast specimens were developed with different attributes to improve their seismic performance.The test results showed that the performance of the monolithic specimen M1 represented ductile seismic behavior.Failure of columns and joints could be prevented,and the failure of the frame occurred at the flexural plastic hinge formation at the beam ends,close to the column faces.For the precast specimens,the splitting crack along the longitudinal lapped splice was a major failure.The precast P5 specimen with double steel T-section inserts showed better seismic performance compared to the other precast models.However,the dowel bars connected to the steel inserts were too short to develop a bond.The design of the precast concrete beams with lap splice is needed for longer lap lengths and should be done at the beam mid span or at the low flexural stress region.

Pushover analysis of reinforced concrete frames considering shear failure at beam-column joints

Since most current seismic capacity evaluations of reinforced concrete （RC） frame structures are implemented by either static pushover analysis （PA） or dynamic time history analysis, with diverse settings of the plastic hinges （PHs） on such main structural components as columns, beams and walls, the complex behavior of shear failure at beam-column joints （BCJs） during major earthquakes is commonly neglected. This study proposes new nonlinear PA procedures that consider shear failure at BCJs and seek to assess the actual damage to RC structures. Based on the specifications of FEMA-356, a simplified joint model composed of two nonlinear cross struts placed diagonally over the location of the plastic hinge is established, allowing a sophisticated PA to be performed. To verify the validity of this method, the analytical results for the capacity curves and the failure mechanism derived from three different full-size RC frames are compared with the experimental measurements. By considering shear failure at BCJs, the proposed nonlinear analytical procedures can be used to estimate the structural behavior of RC frames, including seismic capacity and the progressive failure sequence of joints, in a precise and effective manner.

A review of flexibility-based finite element method for beam-column elements

For material nonlinear problem,elements derived with the flexibility-based method are more accurate than classical elements derived with the stiffness-based method. A review of the current state of the art of the flexibility-based finite element method is provided to enhance the robustness of structure analysis. The research on beam-column elements is the mainstream in the research on flexibility-based finite element method at present. The original development of flexibility-based finite element method is reviewed, and the further development of this method is then presented in several specific aspects, such as geometrically nonlinear analysis and dynamic analysis. The further research needed to be carried out in the future is finally discussed.

Influence of the column-to-beam flexural strength ratio on the failure mode of beam-column connections in RC frames

The column-to-beam flexural strength ratio(CBFSR)has been used in many seismic codes to achieve the strong column-weak beam(SCWB)failure mode in reinforced concrete(RC)frames,in which plastic hinges appear earlier in beams than in columns.However,seismic investigations show that the required limit of CBFSR in seismic codes usually cannot achieve the SCWB failure mode under strong earthquakes.This study investigates the failure modes of RC frames with different CBFSRs.Nine typical three-story RC frame models with different CBFSRs are designed in accordance with Chinese seismic codes.The seismic responses and failure modes of the frames are investigated through time-history analyses using 100 ground motion records.The results show that the required limit of the CBFSR that guarantees the SCWB failure mode depends on the beam-column connection type and the seismic intensity,and different types of beam-column connections exhibit different failure modes even though they are designed with the same CBFSR.Recommended CBFSRs are proposed for achieving the designed SCWB failure mode for different types of connections in RC frames under different seismic intensities.These results may provide some reference for further revisions of the SCWB design criterion in Chinese seismic codes.

Seismic Behaviour of Beam-Column Joints of Precast and Partial Steel Reinforced Concrete

A beam-column joint of precast and partial steel reinforced concrete( PPSRC) is proposed for precast reinforced concrete frames. The PPSRC consists of partial steel and reinforced concrete. The partial steel is located in the core joint region and the connections between concrete members. This paper presents an experimental study of a series of PPSRC specimens. These specimens are tested under low cyclic loading.Experimental results demonstrate that the bearing capacity of the PPSRC specimens is 3 times that of the ordinary reinforced concrete( RC) beam-column joints. The strength and stiffness degradation rates are slower compared with that of the RC beam-column joints. In addition,the strength of the core joint region and the connections is higher than other parts of the PPSRC specimens. Beam failure occurs firstly for the PPSRC specimens,followed by column failure and connections failure. The failure of the core joint region occurs finally.Test results show that the seismic performance of the PPSRC is better than that of the ordinary RC beam-column joints.

Analysis of nonlinear stability and post-buckling for Euler-type beam-column structure

Based on the assumption of finite deformation, the Hamilton variational principle is extended to a nonlinear elastic Euler-type beam-column structure located on a nonlinear elastic foundation. The corresponding three-dimensional （3D） mathematical model for analyzing the nonlinear mechanical behaviors of structures is established, in which the effects of the rotation inertia and the nonlinearity of material and geometry are considered. As an application, the nonlinear stability and the post-buckling for a linear elastic beam with the equal cross-section located on an elastic foundation are analyzed. One end of the beam is fully fixed, and the other end is partially fixed and subjected to an axial force. A new numerical technique is proposed to calculate the trivial solution, bifurcation points, and bifurcation solutions by the shooting method and the Newton- Raphson iterative method. The first and second bifurcation points and the corresponding bifurcation solutions are calculated successfully. The effects of the foundation resistances and the inertia moments on the bifurcation points are considered.

Finite Element Modeling of Stability of Beam-Column Supports for Field Fabricated Spherical Storage Pressure Vessels

Spherical pressure vessels in large sizes are generally supported on legs or columns evenly spaced around the circumference. The legs are attached at or near the equator of the sphere. This research work focussed on flexural-torsional buckling of beam-column supports of field fabricated spherical pressure vessels using finite element analysis. Flexuraltorsional buckling is an important limit state that must be considered in structural steel design and it occurs when a structural member experiences significant out-of-plane bending and twisting. This research has therefore considered the total potential energy equation for the flexural-torsional buckling of a beam-column element. The energy equation was formulated by summing the strain energy and the potential energy of the external loads. The finite element method was applied in conjunction with the energy method to analyze the flexural-torsional buckling of beam-column supports. To apply the finite element method, the displacement functions are assumed to be cubic polynomials, and the shape functions used to derive the element stiffness and element geometric stiffness matrices. The element stiffness and geometric stiffness matrices were assembled to obtain the global stiffness matrices of the structure. The final finite element equation obtained was in the form of an eigenvalue problem. The flexural-torsional buckling loads of the structure were determined by solving for the eigenvalue of the equation. The resulting eigenvalue equation from the finite element analysis was coded using FORTRAN 90 programming language to aid in the analysis process. To validate FORTRAN 90 coding developed for the finite element analysis and the methodology, the results given by the software were compared to existing solutions and showed no significant difference P > 0.05.

Finite Element Analysis (FEA) for the Beam-Column Joint Subjected to Cyclic Loading Was Performed Using ANSYS

This paper analyses the seismic performance of exterior beam-column joints strengthened with unconventional reinforcement detailing. The beam-column joint specimens were tested with reverse cyclic loading applied at the beam end. The samples were divided into two groups based on the joint reinforcement detailing. The first group (Group A) of three non-ductility specimens had joint detailing in accordance with the construction code of practice in India IS456-2000, and the second group (Group B) of three ductility specimens had joint reinforcement detailed as per IS13920-1993, with similar axial load cases as the first group. The experimental studies are proven with the analytical studies carried out by finite element models using ANSYS. The results show that the hysteresis simulation is satisfactory for both un-strengthened and ferrocement strengthened specimens. Furthermore, when ferrocement strengthening is employed, the strengthened beam-column joints exhibit better structural performance than the un-strengthened specimens of about 31.56% and 38.98 for DD-T1 and DD-T2 respectively. The analytical shear strength predictions were in line with the test results reported in the literature, thus adding confidence to the validity of the proposed models.

基于LCL滤波器的三相光伏并网控制系统研究

针对采用LCL滤波器三相光伏并网逆变器,首先进行理论分析并建立数学模型,其次提出一种极点配置与重复控制相结合的并网控制方案,最后通过实验验证理论分析的正确性以及控制策略的可行性。

基于.NET的通用查询组件的开发

在分析主要开发技术的基础上,介绍了如何在.NET平台下用C#语言开发一个实用的通用查询组件,详细叙述了该查询组件的设计方法、功能实现的部分程序代码。在实际数据库的应用系统中,各子系统在调用该组件时只要设置相应的连接字符串参数,就可满足子系统的查询需求,达到通用的要求。在包含多个查询子系统的应用中,通过调用查询组件可以加快开发进度,降低成本,提高软件的开发效率。

腹板摩擦式自定心预应力混凝土框架梁柱节点的试验研究

提出了一种腹板摩擦式自定心预应力混凝土框架梁柱节点形式,并通过14个低周反复加载试验,对节点在循环荷载下的力学行为以及耗能特性进行研究,分析钢绞线预应力、螺杆预应力、梁端钢套、螺旋箍筋等参数对于节点性能的影响。试验结果表明,腹板摩擦式自定心预应力混凝土框架梁柱节点具有震后自动复位、主体结构基本无损、耗能机制明确等优点。梁端的钢套避免了混凝土梁柱在相对转动时的局部受压破坏,而位于梁端腹板的摩擦装置则提供了良好的耗能能力。随着初始预应力的加大,节点的初始刚度、临界张开弯矩加大并具有更强的自定心能力;节点的耗能效果主要受摩擦力的大小控制,预应力螺杆的正应力越大,耗能效果越明显。为保证槽钢的传力和摩擦耗能效果,须加强柱预埋钢板在框架柱中的锚固。

银杏叶提取物对早期糖尿病肾病患者TGF-β1和CTGF水平的影响

目的探讨银杏叶提取物对早期糖尿病肾病(DN)患者转化生长因子(TGF)-β1、结缔组织生长因子(CTGF)及Ⅳ型胶原(CⅣ)水平的影响。方法63例早期DN患者随机分组,对照组(29例)采用糖尿病(DM)常规治疗,治疗组(34例)在常规治疗基础上加用银杏叶片,疗程2个月。采用酶联免疫吸附法(ELISA)测定两组患者治疗前后血清TGF-β1、CⅣ和尿TGF-β1、CTGF水平,同时观察尿白蛋白排泄率(UAER)、空腹血糖(FPG)、血肌酐(Scr)、血脂等指标的变化。结果与治疗前比较,治疗组患者治疗后血清TGF-β1、CⅣ和尿TGF-β1、CTGF水平下降(P<0.05或P<0.01),UAER明显降低,Scr、血脂指标改善(P<0.05或P<0.01),对照组治疗后上述指标无明显差异(P>0.05)。结论银杏叶提取物可通过降低早期DN患者TGF-β1、CTGF水平而延缓DN的发展。

一种提取SAR图像边缘的改进算法

传统的边缘提取算法不能解决合成孔径雷达(SAR)图像小边缘、赘余边缘多的问题。针对SAR图像特点,提出一种改进的基于过渡区模糊增强边缘提取方法。通过分析经典模糊增强算法和改进的模糊增强算法的缺陷,在图像增强中引入过渡区概念,很好地克服了原来模糊增强算法渡越点选择不当造成的丢失目标边缘信息、边缘连通性不好、小边缘多等缺点。能够有效地提取出感兴趣目标的丰富的边缘信息,并且去除了很多小边缘赘余信息。对比实验结果证明该方法效果好。

基于区域特征和连接成分的地图规范化算法

地图图像规范化算法是使地图图像同类型对象的某种属性具有相同的表现形式的一种方法或过程,它是地理信息识别的一个重要步骤。根据彩色栅格城市交通地图图像中各类地理要素的特征,提出一种基于区域特征和连接成分的地图图像规范化算法。首先对地图图像中的区域特征进行分析,并建立区域识别测度,实现了区域颜色规范化;再通过对非区域对象的连接成分进行分析,并建立道路识别测度,在区域颜色规范化的基础上,实现了道路颜色规范化。实验结果表明,对于彩色城市交通地图图像,该算法取得了良好的效果。

国防预研项目管理立项评价方法研究

建立了国防预研项目立项评价的指标体系和等级标准,根据国防预研项目立项评价的特点,提出将多元联系数引入国防预研项目立项评价的研究思路,并给出了利用5元联系数进行国防预研项目评价的具体步骤。实证分析表明,该方法不但可以为国防预研项目管理提供量化的决策依据,而且方法思路清晰,实用性较强。

基于社会控制理论的未成年人违法犯罪成因及对策思考——以重庆市为例

从社会控制论的角度研究区域未成年人违法犯罪的成因,旨在揭示社会结构变化过程中未成年人违法犯罪的规律,为预控未成年人违法犯罪提供正确的决策。

直升机复合材料结构装配工艺研究

本文详细分析了直升机复合材料关键装配特征,进行了装配工装设计。系统研究了制孔、锪窝、切割加工工艺及铆接、螺接等连接工艺和方法。为今后大型复杂复合材料结构装配奠定了基础。

Experimental Study on Effects of Fuel Injection on Scramjet Combustor Performance

In order to investigate the effects of fuel injection distribution on the scrarnjet combustor performance, there are conducted three sets of test on a hydrocarbon fueled direct-connect scramjet test facility. The results of Test A, whose fuel injection is carried out with injectors located on the top-wall and the bottom-wall, show that the fuel injection with an appropriate close-front and centralized distribution would be of much help to optimize combustor performances. The results of Test B, whose fuel injection is performed at the optimal injection locations found in Test A, with a given equivalence ratio and different injection proportions for each injector, show that this injection mode is of little benefit to improve combustor performances. The results of Test C with a circumferential fuel injection distribution displaies the possibility of ameliorating combustor performance. By analyzing the effects of injection location parameters on combustor performances on the base of the data of Test C, it is clear that the injector location has strong coupled influences on combustor performances. In addition, an irmer-force synthesis specific impulse is used to reduce the errors caused by the disturbance of fuel supply and working state of air heater while assessing combustor performances.