Structural Integrity Assessment of Offshore Jackets Considering Proper Modeling of Buckling in Tubular Members-a Case Study of Resalat Jacket

In the present research,results of buckling analysis of 384 finite element models,verified using three different test results obtained from three separate experimental investigations,were used to study the effects of five parameters such as D/t,L/D,imperfection,mesh size and mesh size ratio.Moreover,proposed equations by offshore structural standards concerning global and local buckling capacity of tubular members including former API RP 2A WSD and recent API RP 2A LRFD,ISO 19902,and NORSOK N-004 have been compared to FE and experimental results.One of the most crucial parts in the estimation of the capacity curve of offshore jacket structures is the correct modeling of compressive members to properly investigate the interaction of global and local buckling which leads to the correct estimation of performance levels and ductility.Achievement of the proper compressive behavior of tubular members validated by experimental data is the main purpose of this paper.Modeling of compressive braces of offshore jacket platforms by 3D shell or solid elements can consider buckling modes and deformations due to local buckling.ABAQUS FE software is selected for FE modeling.The scope of action of each of elastic buckling,plastic buckling,and compressive yielding for various L/r ratios is described.Furthermore,the most affected part of each parameter on the buckling capacity curve is specified.The pushover results of the Resalat Jacket with proper versus improper modeling of compressive members have been compared as a case study.According to the results,applying improper mesh size for compressive members can under-predict the ductility by 33%and under-estimate the lateral loading capacity by up to 8%.Regarding elastic stiffness and post-buckling strength,the mesh size ratio is introduced as the most effective parameter.Besides,imperfection is significantly the most important parameter in terms of critical buckling load.

Compressive Strength of Tubular Members with Combined Pitting Corrosion and Crack Damage

Tubular members subject to combined pitting corrosion and crack damage were numerically studied to clarify the reduction of ultimate strength and failure behavior,based on numerical models validated against available experi-ments.The effects of length,location and inclined angle of a crack under combined damage were studied to disclose the mechanism of interaction between the crack and corrosion pits.The methods,named as linear superposition directly accumulating the effects of solo crack and solo pitting damage,as well as crack projection transferring an inclined crack to a transverse one,were discussed and verified in the view of assessing ultimate strength of tubular members with combined damage.It was shown that the former is practical but complex while the next always over-estimates the residual strength.Besides,the location and inclined angle of a crack have a subtle effect on the reduction of ultimate strength under combined damage,especially at higher level of pitting damage,due to the synergistic effect between corrosion pits and cracks.Such effect can lead to early occurrence of plasticity and local buckling by inducing stress interaction between crack tips and pits,and causing more significant strength reduction compared with a solo type of damage.A practical method was proposed to determine the loss ratio of cross-sectional area on the equivalent weakest section of a damaged member.Based on the loss ratio,a formula was presented to predict the ultimate strength of damaged members with combined damage,showing good applicability.

Moment-curvature relationship of FRP-concrete-steel doubleskin tubular members

Tests were conducted on 3 specimens to study the flexural behavior of fiber reinforced polymer(FRP)-concrete-steel double-skin tubular members(DSTMs).The strip method was used to calculate the section momentcurvature curves of the 3 specimens and 12 models.A theoretical formula is presented for the flexural strength of DSTMs.The test results show that the tension zone of the specimen FRP tubes was in hoop compression while the compression zone was in hoop tension.The load-carrying capacity did not decrease even when the mid-span deflection reached about 1/24 of the span length.The tests,simulation and theoretical analysis resulted in a simplified formula for the flexural strength of DSTMs and a tri-linear moment-curvature model was expressed as a function of the section bending stiffness for DSTMs.

Shear Failure of a Clamped Dented Tubular Beam Under Lateral Impact

The shear failure of a rigid-plastic dented clamped tubular beam under the lateral impact of a mass is investigated. Both the denting and the impact point are in the middle span of the beam. It is assumed that denting does not spread during the shear sliding. Numerical results show that the axial force and lateral deflection of the beam are very small at the moment of the occurence of shear failure, which means that the finite deformation effect can be neglected in the shear failure analysis. Also, some aspects of the initial impact energy are investigated.

螺栓球节点对钢管杆件屈曲特征值的影响

利用ANSYS软件建立螺栓球节点与钢管杆组合构件的有限元模型,采用接触模拟法计算螺栓球钢管构件的屈曲特征值,分析螺栓球节点作为杆件两端约束时对杆件临界荷载产生的影响;参数化研究螺栓半径、套筒壁厚、封板厚度、螺栓头半径和套筒长度等因素对不同长细比杆件屈曲特征值的影响;基于杆件屈曲的欧拉公式,通过回归分析获得考虑螺栓球节点参数与杆件长细比影响杆件的屈曲特征值计算公式。结果表明:随螺栓半径和套筒壁厚增大杆件屈曲特征值显著增大,螺栓头半径对其的影响可忽略不计,封板厚度的增加和套筒长度的减小也能使杆件屈曲特征值有所增加;随杆件长细比的增大,以上各因素对杆件屈曲特征值的影响均逐渐减小,同时杆件长细比越大螺栓球节点对杆件的约束越强;利用回归分析获得组合构件屈曲特征值公式的计算值与有限元结果接近,随节点参数与杆件长细比的变化趋势一致,该公式能够较精准地计算杆件屈曲特征值。

圆形泡沫铝填充钢管静态压缩性能研究

通过实验研究了圆形泡沫铝填充钢管构件在静态压缩下的性能。对本试验范围内的结果进行分析可知,在外围钢管厚度较小时,在静态压缩过程中圆形泡沫铝填充钢管构件发生局部屈曲变形,压缩变形曲线现为弹性阶段和屈服平台阶段;在外围钢管厚度较大时,圆形泡沫铝填充钢管构件发生整体失稳,压缩曲线在经历弹性阶段后,进入弹塑性屈服阶段,到达峰值荷载后,构件承载力迅速下降。在试验基础上,提出了圆形泡沫铝填充钢管构件的平均压溃载荷和极限压溃载荷的设计公式,同时将试验结果与理论公式进行了比较,两者数值较为吻合。

模拟酸雨腐蚀钢管混凝土构件静力性能研究

该文讨论了模拟酸雨腐蚀环境下钢管混凝土构件静力性能的退化规律,具体包括模拟酸雨腐蚀后:钢材材料力学性能;钢管混凝土构件轴压力学性能;钢管混凝土构件纯弯力学性能;钢管混凝土构件偏压力学性能。分析了腐蚀率对钢材屈服强度、弹性模量、极限抗拉强度和极限延伸率的影响,采用钢管壁厚折减以及壁厚折减耦合材性折减的模拟腐蚀损伤方法,结合有限元ABAQUS软件、规范公式,分别计算了构件荷载-变形关系曲线、极限承载力,并和试验结果进行了比较,发现钢管壁厚折减方法优于壁厚折减耦合材性折减方法,地方标准严于国家标准。

钢管混凝土轴心受压构件的徐变分析

基于混凝土徐变的继效流动理论、多轴应力作用下混凝土的徐变理论 ,结合钢管混凝土轴心受压构件的受力特点 ,推导出钢管混凝土轴心受压构件徐变的计算公式。该徐变计算公式既考虑了钢管混凝土轴心受压构件徐变的特点 ,又能反应出不同因素 (含钢率、材料强度、应力大小等 )对构件徐变的影响。应用这些公式 ,通过迭代计算得到的钢管混凝土轴心受压构件的徐变 ,与文献[4 ]中的试验数据符合较好。

输电塔典型节点钢管杆件动力特性研究

输电塔钢管杆件易发生微风振动,起振风速与杆件自振频率有关。为了获得钢管杆件的自振频率规律,分别通过动力特性试验和ANSYS有限元模拟进行了研究,得到了常用长细比典型节点钢管杆件的1阶自振频率。结果表明单插板连接和U插板连接杆件弱轴1阶自振频率接近于两端铰接结果、强轴1阶自振频率接近于两端固接结果,十字插板连接和法兰连接杆件1阶自振频率接近于两端固接结果,螺栓数对钢管杆件1阶自振频率影响不大。最后总结出了方便工程应用的1阶自振频率简化计算方法。

截面分层法计算不锈钢-混凝土-钢双壁管受弯承载力

提出不锈钢(薄壁外层)-混凝土-钢双壁空心管(DSTM)新型构件。借鉴钢-混凝土组合结构构件的基本假定及材料本构关系,分析DSTM正截面受弯承载力性能。利用截面分层法建立DSTM管纯弯构件承载力计算公式,并采用有限元数值计算方法对截面分层法计算结果进行比较分析。结果表明,两种方法所得结果基本吻合,所建立的公式可为工程设计提供参考依据。

圆钢管混凝土轴心受压构件徐变分析的比较

在对钢管混凝土构件徐变研究进行回顾的基础上,应用考虑多轴受压状态下的混凝土徐变理论建立圆钢管混凝土轴心受压构件徐变模型,分别采用继效流动理论和龄期调整有效模量法对构件的徐变进行分析,通过迭代计算得到基于2种理论方法的圆钢管混凝土轴心受压构件的徐变,并与试验所得的回归公式计算结果进行比较。通过对比,指出了2种理论的差异性。结果表明:在钢管混凝土轴心受压构件的徐变计算中,继效流动理论具有较高的精度。

CFRP增强圆钢管混凝土受弯构件试验

目的了解圆截面CFRP-钢管混凝土受弯构件的静力性能,分析荷载-跨中挠度曲线特性以及纵向CFRP层数对该类构件极限承载力的影响.方法对8根圆截面CFRP-钢管混凝土受弯构件以及用于对比的2根圆截面钢管混凝土受弯构件开展静力试验并分析试验结果.结果对于仅缠绕1层环向CFRP的圆CFRP-钢管混凝土受弯试件,其荷载-跨中挠度曲线类似于对应的圆钢管混凝土受弯构件的曲线;对于包裹纵向CFRP的构件,其荷载-跨中挠度曲线可以划分为以下几个阶段:弹性阶段,弹塑性阶段和下降段.结论在本文试件参数范围内,仅环向缠绕1层CFRP对圆钢管混凝土受弯构件的承载力并无显著影响;圆CFRP-钢管混凝土受弯构件的延性性能要好于圆截面FRP筒内填混凝土受弯构件.

圆端形钢管混凝土构件纯弯力学性能

为研究圆端形钢管混凝土构件的纯弯力学性能,对4个构件进行了纯弯试验,分析了高宽比和含钢率对纯弯曲作用下圆端形钢管混凝土构件破坏形态、挠度曲线、截面应变、抗弯承载力的影响。基于ABAQUS建立有限元模型对圆端形钢管混凝土构件纯弯性能进行模拟,试验结果与模拟结果吻合良好,利用验证后的模型对圆端形钢管混凝土构件进行了受力全过程分析以及参数分析。最后基于ABAQUS参数分析结果提出了圆端形钢管混凝土构件抗弯承载力计算公式,公式计算结果与试验结果吻合良好。结果表明:圆端形钢管混凝土构件在纯弯曲作用下发生了明显的挠度变形,当跨中挠度达到L/25(L为试件长度)时,试件仍能承受较大的荷载,表现出良好的延性;圆端形钢管混凝土构件的挠度曲线可假设为正弦半波曲线,其跨中截面基本保持为平截面;当构件达到抗弯承载力时,钢管承受了大部分弯矩,圆弧段钢管相较于平直段钢管对混凝土的约束作用更强;圆端形钢管混凝土构件的抗弯承载力随钢材强度的增大而增大,而混凝土强度的改变对其抗弯性能影响较小。

离心钢管混凝土结构弹性扭转应力分析

采用弹性力学的基本分析方法,建立了离心钢管混凝土构件扭转作用的基本方程.假定应力函数的基本模式,令其满足平衡方程及力的边界条件;通过对层合材料扭转余能的变分使协调条件得到近似满足,确定了离心钢管混凝土构件在扭矩作用下的横截面及层间剪应力的具体计算公式.

带有损伤杆件的钢管结构极限承载力计算的实用力学模型

采用有限元计算和试验数据建立的回归模型方法来研究一般受损条件下轴心受压圆钢管杆件受力的全过程.分析了凹陷深度、初弯曲、长细比和截面径厚比等参数对杆件极限承载力的影响.重点研究了上述参数对杆件荷载—轴向缩短关系的单独影响和综合影响.最后引入了受损杆件的折算刚度系数,为带有损伤杆件的钢管结构极限承载力的非线性分析提供了合理的力学模型.

一种新型预制管混凝土柱的轴压性能研究

对一种新型的预制管混凝土柱结构与钢筋混凝土现浇柱,以体积配箍率和预制管的混凝土轴心抗压强度为参数,进行对比试验。用二轴强度理论计算预制管混凝土柱的开裂荷载,并在本次试验和以往理论研究的基础上,给出预制管混凝土柱轴心受压承载力计算公式。

一种新型预制管混凝土柱的非线性有限元分析

提出了一种新型的预制管混凝土柱结构,在8根预制管混凝土柱及两根钢筋混凝土现浇柱的对比试验基础上,进一步用Ansys对预制管混凝土柱进行了非线性有限元分析,结果表明,按所建立的Ansys模型,计算结果与试验吻合较好.

内配圆钢管的圆钢管混凝土构件耐撞性能分析

内配圆钢管的圆钢管混凝土是一种新型复合形式的组合构件,由圆钢管混凝土内部配置同心位置的圆管,并在内部圆管的内外两侧均浇筑混凝土而形成的构件。基于有限元软件ABAQUS对内配圆钢管的圆钢管混凝土构件在低速横向撞击作用下的耐撞性能进行了数值模拟,数值结果与其他研究者完成的钢管混凝土、中空夹层钢管混凝土试件的撞击试验数据进行了对比,验证了模型的正确性。采用该模型分析了此类组合构件在横向撞击作用下的动力响应全过程及其典型破坏模态,对影响其耐撞性能的主要影响参数进行了分析,初步得出了各主要影响参数对此类组合构件耐撞性能的影响。参数分析结果表明,提高外钢管的强度及含钢率可以有效地改善该构件的耐撞性能,而混凝土强度的变化对构件耐撞性能的影响很小;增强构件两端的支座约束,可以增强构件的耐撞性能;构件的内外径之比为0.6～0.8时,构件具有较好的耐撞性能。

钢管塔架K型加肋节点的承载力分析

通过试验对1/4加肋K型钢管插板连接节点的极限承载力进行了研究,同时借助有限元分析了主管壁厚,环板宽度和厚度以及不同加肋方式对节点极限承载力的影响。在此基础上根据试验和有限元结果以及节点的破坏模式提出了适用于估算此类节点极限承载力的极限分析模型和建议公式。结果表明:加肋K型钢管插板连接节点的承载力受主管壁厚和环板宽度和厚度的影响较大,且分主管控制和环板控制2种情况来讨论。采用的四铰破坏机理和五铰破坏机理极限分析模型能较好的反映此类节点的受力性能。

变电构架受损伤圆钢管杆件轴压极限承载力分析

以电力构架中常用的圆钢管杆件为研究对象,采用有限元计算和试验数据建立的回归模型方法,研究一般受损条件下杆件轴压极限承载力的变化情况。分析了凹陷深度、初弯曲、长细比和截面径厚比等参数对杆件极限承载力的影响,讨论了上述参数对荷载-轴向缩短关系的单独影响和综合影响。了解了多杆件极限承载力的特点,引入了受损杆件的折算刚度系数。所得结论为变电构架的可靠性分析和维修加固提供了依据。