钢管桩与混凝土芯粘结力及抗弯应力传递模拟试验研究

依托深圳蛇口集装箱码头二期工程,进行了钢管桩与混凝土芯粘结力及抗弯应力传递模拟试验,对试验结果进行理论分析,讨论了不同搭接长度和不同UEA掺量对钢管桩与混凝土芯单位粘结力的影响;推导出纯弯矩作用下,混凝土芯与钢管粘结段粘结长度的计算公式。为类似工程提供方法指导和理论依据。     

盾构法隧道纵向地震响应特性

采用土—结相互作用的动力有限元法,引入无长度的3自由度弹簧单元模拟纵向螺栓接头,分析行波波长、地基刚度与阻尼对盾构法隧道纵向地震响应的影响。分析结果表明:行波从水平方向输入时有突变弯矩产生,突变弯矩随波长和阻尼的增大而减小,而地基刚度系数对突变弯矩的影响相对较小;行波作用下,产生的接头最大轴力及最大弯矩值均随波长的增大而减小,而地基刚度系数及阻尼系数取值对最大弯矩值的影响较小。因此,建议在实际工程设计计算中要重视输入地震动参数的选择,且取较小的阻尼系数。     

《钢结构设计规范》在起重扒杆设计中的应用

在起重船扒杆设计中，现行《船舶及海上设施起重设备规范》没有提供直接强度计算方法，容易导致强度计算缺乏统一标准和审图产生困难。作者认为，《钢结构设计规范》（GB50017）提供的有关计算会式可作为船舶工程中起重扒杆以及其它压弯构件的计算方法。     

关于规定曲率弯矩方程弯矩正负号的问题

阐明了曲率弯矩方程的物理概念及用此方程建立梁(柱)弯曲微分方程的思路,论述了在建立梁(柱)弯曲微分方程中规定弯矩正负号(简称这种规定)引起的问题:1)这种规定破坏了曲率弯矩方程所反映的物理概念及用曲率弯矩方程建立梁(柱)弯曲微分方程的思路;2)这种规定导致了梁(柱)截面内力矩与梁(柱)曲率正负号无关的错误概念;3)按这种规定建立梁(柱)弯曲微分方程须记住弯矩正负号的规定,与此种规定对应的坐标系,不考虑梁(柱)曲率的正负号等3条内容,否则得出错误结果。建议材料力学在阐述梁(柱)弯曲微分方程中删去这种规定,以避免上述问题。     

轨道交通曲线连续 钢—混组合梁抗剪分析

论述在钢混组合梁计算中,规范中按实体梁横向弯曲剪应力计算,没有扭转剪应力计算的规定。曲线组合梁的扭矩较大,讨论是否需要考虑扭转剪应力的影响。结合工程实例,计算分析自由扭转剪应力,按闭口薄壁构件和实体梁分别计算弯曲剪应力,并对计算结果进行对比分析,提出合理的计算方法。     

软土地铁隧道沉降治理效果评估

基于某地铁隧道沉降治理过程中的实测数据,研究沉降治理效果评估方法。首先利用3次样条曲线插值法对隧道沉降监测点数据拟合,计算出累计沉降的曲率半径;然后以等效轴向刚度模型为基础,推导出盾构管片接头环缝张开量和纵向连接螺栓受力情况。通过理论计算对治理后隧道结构健康状态作出评估,全面分析隧道沉降治理效果,为后期运营维护提供依据。     

黏FRP加固钢筋混凝土构件抗弯简化计算

黏FRP加固钢筋混凝土梁在屈服时和屈服后拉断时2种状态下正截面受压混凝土尚未压坏,作者对其合力大小及位置进行了简化,给出了相应的弯矩特征值近似公式.研究结果表明,其计算结果与试验结果吻合良好.提出了以抵抗FRP拉断为目标的抗弯加固设计简化计算方法.     

P70型棚车车体钢结构上侧梁旁弯工艺控制

对P70型通用棚车车体钢结构在生产过程中经常出现的上侧梁旁弯超差现象进行了分析,找到了原因,通过采用强制焊接及调整车顶弯梁的工艺尺寸等改进措施,使上侧梁旁弯满足了技术要求。     

砂浆锚杆的有限元模拟方法探讨

针对现有砂浆锚杆有限元模拟方法的局限性与不足，在深入探讨砂浆锚杆的力学机理的基础上，提出了一种包含锚杆、砂浆以及接触面的新型复合锚杆单元，该单元不仅能反映锚杆的轴向受力作用，还能反映锚杆的抗弯以及锚杆与岩体接触面的剪切滑移效应，并利用有限元基本理论，推导了新型复合锚杆单元刚度矩阵及相关计算公式，并编制了相应的计算程序，工程实例分析表明：模型能够满足工程要求，具有一定的理论与工程实用价值。     

A regression and beam theory based approach for fatigue assessment of containership structures including bending and torsion contributions

Container shipping has been expanding dramatically during the last decade. Due to their special structural characteristics, such as the wide breadth and large hatch openings, horizontal bending and torsion play an important role to the fatigue safety of containerships. In this study the fatigue contributions from vertical bending, horizontal bending and torsion are investigated using full-scale measurements of strain records on two containerships. Further, these contributions are compared to results from direct calculations where a nonlinear 3D panel method is used to compute wave loads in time domain. It is concluded that both bending and torsion have significant impacts on the fatigue assessment of containerships. The stresses caused by these loads could be correctly computed by full-ship finite element analysis. However, this requires large computational effort, since for fatigue assessment purposes the FE analysis needs to be carried out for all encountered sea states and operational conditions with sufficient time steps for each condition. In this paper, a new procedure is proposed to run the structure finite element analysis under only one sea condition for only a few time steps. Then, these results are used to obtain a relationship between wave loads and structural stresses through a linear regression analysis. This relation can be further used to compute stresses for arbitrary sea states and operational conditions using the computed wave loads (bending and torsion moments) as input. Based on this proposed method for structure stress analysis, an efficient procedure is formulated and found to be in very good agreement with the full-ship finite element analysis. In addition it is several orders of magnitude more time efficient for fatigue assessment of containership structures.