Experimental and Numerical Studies on Sea Sand Concrete Filled Stainless Steel Tube with Inner FRP Tube Subjected to Axial Compression

Since fibre-reinforced polymer(FRP) and stainless steel(SS) offer advantages of corrosion resistance and hybrid confinement, this study proposed a new type of composite column: sea sand concrete(SSC)-filled SS tubular columns with an inner FRP tube(CFSTFs) to help exploit abundant ocean resources in marine engineering. To study compressive behaviours of these novel members, eight CFSTFs and two SSC-filled SS tubular columns(CFSTs)were tested under axial compression. Their axial load-displacement curves, axial load-strain curves in SS or FRP tubes were obtained, and influences of key test parameters(the existence of glass FRP(GFRP) tubes, steel tube shapes, and GFRP tube thicknesses and diameters) were discussed. Further, specimen failure mechanism was analyzed employing the finite element method using ABAQUS software. Test results confirmed the excellent ductility and load-bearing capacity of CFSTFs. The existence of GFRP tubes inside can postpone SS tube buckling, and the content of inner FRP tubes, particularly increasing diameters, was found to improve compressive behaviours. GFRP contents helped develop the second elastic-plastic stage of the load-displacement curves. Furthermore, the bearing capacity of CFSTFs with a circular cross-section was approximately 26% higher than that with a square cross-section, and this difference narrowed with the increase in GFRP ratios.

Deformation behaviors of 21-6-9 stainless steel tube numerical control bending under different friction conditions

For contact dominated numerical control(NC) bending process of tube, the effect of friction on bending deformation behaviors should be focused on to achieve precision bending forming. A three dimensional(3D) elastic-plastic finite element(FE) model of NC bending process was established under ABAQUS/Explicit platform, and its reliability was validated by the experiment. Then, numerical study on bending deformation behaviors under different frictions between tube and various dies was explored from multiple aspects such as wrinkling, wall thickness change and cross section deformation. The results show that the large friction of wiper die-tube reduces the wrinkling wave ratio η and cross section deformation degree ΔD and increases the wall thinning degree Δt. The large friction of mandrel-tube causes large η, Δt and ΔD, and the onset of wrinkling near clamp die. The large friction of pressure die-tube reduces Δt and ΔD, and the friction on this interface has little effect on η. The large friction of bending die-tube reduces η and ΔD, and the friction on this interface has little effect on Δt. The reasonable friction coefficients on wiper die-tube, mandrel-tube, pressure die-tube and bending die-tube of 21-6-9(0Cr21Ni6Mn9N) stainless steel tube in NC bending are 0.05-0.15, 0.05-0.15, 0.25-0.35 and 0.25-0.35, respectively. The results can provide a guideline for applying the friction conditions to establish the robust bending environment for stable and precise bending deformation of tube bending.

Influence of flash trap profiles on joint properties of friction welded CP-Ti tube to 304L stainless steel tube plate using external tool

Titanium tube and stainless steel tube plate were welded by an innovative friction welding of tube to tube plate using an external tool (FWTPET). Copper was used as an interlayer for joining the dissimilar materials and also to minimize the effect of intermetallics formed at the joint interface. The process parameters that govern FWTPET process are plunge rate, rotational speed, plunge depth, axial load and flash trap profile. Among them, the flash trap profile of the tube has a significant influence on the joint integrity. Various flash trap profiles like vertical slots, holes, zig-zag holes, and petals were made on the titanium tube welded to the stainless steel tube plate. Macroscopic and microscopic studies reveal defect-free joints. The presence of copper interlayer and intermetallics was evident from X-ray diffraction (XRD), scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) studies. The microhardness survey was presented across and along the interface. A novel test procedure called “plunge shear test” was developed to evaluate the joint properties of the welded joints. The highest shear fracture load of 31.58 kN was observed on the sample having petals as flash trap profile. The sheared surfaces were further characterized using SEM for fractography.

Influence of loading path on formability of 304 stainless steel tubes

The loading path affects the metal formability remarkably in tube hydroforming, and it is also one of the research focuses. Recently, some scholars abroad proposed a new fluctuant hydraulic loading method, which can improve the formability of tubes in hydroforming. Related studies have shown that this new loading method can improve the tube formability, the distribution of deformation is more uniform and this is useful for avoiding excessive local thinning. In this paper, tube hydroforming experiments without axial feeding were carried out; the influences of the loading methods on formability of stainless steel tubes were studied. Through the comparison of the experimental results under the condition of monotonous increase loading and fluctuation hydraulic loading, the outside diameter distribution, the thickness distribution and the crack expansion forms of deformation zone all fully prove that the uniformity of the distribution of tube deformation and formability have been increased significantly under the condition of fluctuation loading without axial feeding, the reasons should be distinguished from the fluctuation hydroforming with axial feeding. In order to study the forming mechanism, uniaxial tensile test of tubes similar to fluctuation loading deformation is designed in this paper, namely intermittent tensile test. It is found that intermittent uniaxial stretch can improve the tube elongation at fracture by about 40% and the deformation distribution is more uniform than that through uniaxial tensile test of the stainless steel tube. In the process of intermittent tensile tests, changes of metal microstructures brought by the loading and unloading processes are the main reasons that improve the formability of the tubes.

石墨管与不锈钢管钎焊接头的组织和残余应力

为使石墨材料能够在空间核电散热装置中更充分地发挥其价值,本文采用BNi-2钎料真空钎焊连接等静压石墨管和304不锈钢管,研究了石墨/BNi-2/不锈钢接头在1010℃、保温90 min条件下的显微组织和不同冷却工艺对接头残余应力的影响。研究表明:在1010℃,保温90 min条件下,钎焊接头致密无裂纹,Cr元素在石墨侧与石墨基体反应形成Cr_(7)C_(3)反应层,在不锈钢侧形成了σ-FeCr扩散层,界面接头组成为石墨/Cr_(7)C_(3)/Ni(s,s)+Ni_(3)Si/σ-FeCr/不锈钢;经缓冷工艺处理的接头,常温剪切强度为28.38 MPa,比炉冷处理的接头剪切强度提高了22%;有限元数值分析结果表明,采用缓慢冷却的钎焊工艺可以有效缓解钎焊接头在冷却过程中产生的残余应力,符合剪切实验结果。

通气孔对新型不锈钢芯管平压性能影响分析

不锈钢芯管作为不锈钢桥面芯板的重要传力构件,其平压力学性能与桥面板承载能力息息相关。因钎焊工艺要求,不锈钢芯管壁上开设有双通气圆孔。为研究双通气圆孔对不锈钢芯管平压性能的影响,开展2组不同厚度不锈钢芯管平压性能试验与有限元非线性屈曲分析。通过试验结果验证采用Riks弧长法进行不锈钢芯管非线性屈曲分析方法的正确性。并考虑圆孔直径d、偏心距e、芯管壁厚t等因素,建立不同规格不锈钢芯管模型,开展非线性屈曲分析,探究多参数协同作用下对不锈钢芯管平压性能的影响分析。研究结果表明:不锈钢芯管平压试验曲线表现出明显的非线性特征,分为弹性阶段、弹塑性阶段与塑性破坏阶段;通气孔、管端扳边处转角及管脚10 mm处易优先出现局部屈曲破坏;不锈钢芯管极限荷载Pu及其对应的压缩位移δ_(u)随孔径d、偏心距e的增加而减小,随壁厚t增加而增大;芯管极限荷载Pu受孔径d的影响大于受偏心距e的影响,增大孔径使芯管极限荷载Pu下降6.00%~15.51%,而增大偏心距使芯管极限荷载Pu下降0.64%~9.22%,芯管应规避在管身中部(e/H=0.5)开孔;当孔径比d/D≯0.04、偏心比e/H≯0.3时,通气孔对芯管极限承载力影响较小,对极限荷载下的压缩位移δ_(u)不产生影响,建议将其作为通气孔设计取值。研究中获得的临界值及变化规律可用于新型不锈钢桥面芯板结构设计与优化研究。

圆中空夹层不锈钢管水泥砂浆短柱轴压性能研究

海洋工程平台塔架结构中,圆形截面中空双钢管是主要受力构件,工程界十分关注其受压性能和耐腐蚀性能。为研究圆中空夹层不锈钢管水泥砂浆短柱的轴压力学性能,以外不锈钢管壁厚、内碳素钢管直径和是否含夹层水泥砂浆为试验变量,共设计了12个短柱试件。分析各试件的破坏情况、荷载-位移曲线、承载力、变形能力及应变特征,研究不同变量对极限承载力的影响规律。结果表明:试件破坏形态为外钢管端部或中部局部屈曲破坏;随着不锈钢管壁厚的增大,试件的轴压承载力近似呈线性增长;夹层水泥砂浆对试件力学性能影响较大,可有效提高试件承载力,抑制外不锈钢管的变形,提高试件延性;对于含夹层水泥砂浆的试件,承载力随空心率增大而减小,不含夹层水泥砂浆的试件,承载力随空心率增大而增大。根据国内外规范以及相关学者提出的理论公式,计算了试件的极限承载力,并与试验承载力进行了对比分析,给出了设计建议。

内置型钢的圆形不锈钢管混凝土构件的抗弯性能

采用有限元模型研究内置型钢的圆形不锈钢管混凝土构件的纯弯力学性能,有限元计算结果与试验结果吻合良好。该类典型构件的抗弯承载力比不锈钢管混凝土对比构件的相应值高111.33%;混凝土承担的弯矩也比对比构件的相应值高23.31%,受压区混凝土的抗压承载力约提高了20%,原因是钢管和型钢翼缘对受压区混凝土形成了良好的约束作用。该类构件的抗弯刚度与抗弯承载力随着混凝土强度、不锈钢含钢率、型钢含钢率和回转半径比的增大而提高;其抗弯承载力随着不锈钢屈服强度或型钢屈服强度的增大而提高。最终给出了该类构件的抗弯刚度和抗弯承载力的简化计算方法。

含油海洋环境下316L仪表管点蚀深度预测模型研究

为了提升316L不锈钢仪表管在含油海洋大气环境下点蚀深度的预测精度,建立了基于改进粒子群算法优化的直接离散灰色点蚀深度预测模型[SCPSO-DDGM(1,1,λ)]。首先以暴露实验点蚀数据为例,建立DDGM(1,1)模型,并利用新信息变权弱化缓冲算子、等维灰数递补对模型进行动态改进;后采用非线性变化惯性权重和正弦余弦学习因子提高粒子群算法(PSO)的寻优能力和收敛速度,引入高斯扰动策略增强PSO跳出局部最优的能力,进而用SCPSO对改进后的DDGM(1,1,λ)模型中的权重参数λ进行寻优;最终在MATLAB中进行仿真计算,分析对比SCPSO-DDGM(1,1,λ)模型与GM(1,1)、DDGM(1,1)、PSO-DDGM(1,1,λ)模型的预测结果。结果表明:在研究的时间区间内,经优化的新模型预测深度与实际深度高度吻合,较于对比模型性能更优。证明SCPSO-DDGM(1,1,λ)模型能够有效预测仪表管点蚀深度,为仪表管的腐蚀研究提供了新的思路与方法。

双相不锈钢换热管与管板的焊接

换热管与管板的焊接是换热器质量控制的重点。双相不锈钢焊接的目标是获得平衡的铁素体(δ)和奥氏体(γ)。采用手工钨极氩弧焊,使用Φ1.6 mm的ER2209焊丝,以0.54 kJ/mm的热输入焊接Φ25 mm×2 mm的S32205双相不锈钢换热管与管板试件。经取样检测,角焊缝厚度均值2.88 mm;焊缝维氏硬度均值255.8 HV;按ASTM E562测定铁素体含量,焊缝铁素体含量均值59.3%,管侧熔合线57.3%,管侧热影响区58%,板侧熔合线58.7%,板侧热影响区58.2%;按ASTM A923的方法A检测,5区的金相组织相界和晶界平滑,无有害沉淀相析出,评定为未受影响的金相组织;按GB/T 4334的方法E试验,无晶间腐蚀现象。以上各项检测指标均符合相应标准和技术协议要求,说明焊接工艺适用。

裂解炉稀释蒸汽管道三通开裂原因分析

针对某乙烯裂解装置稀释蒸汽管道304H耐热不锈钢三通使用1年后发生开裂的情况,从材料成分、力学性能、金相组织、残余应力和断口特性等方面进行了分析。结果表明,裂纹分别启裂于三通的内壁和外壁,多数裂纹开裂处伴有晶间腐蚀特征,裂纹扩展特性以沿晶型为主;断口附近腐蚀产物存在O,S,Cl等酸性腐蚀介质。三通主管表面最大轴向应力达到147 MPa,三通相贯线附近距裂纹20 mm处的最大环向应力达到114 MPa,说明运行中的三通表面应力达到了材料屈服强度的1/2。分析认为,裂纹的产生是由于材料发生敏化后,在应力和腐蚀介质共同作用下形成的以沿晶为主的应力腐蚀开裂,更换三通材料或通过适当的固溶处理降低三通中的残余应力是避免三通开裂的重要途径。

新型不锈钢管固废混凝土构件受弯性能研究

进行了6个不锈钢管混凝土试件的纯弯试验研究,分析了在弯曲荷载作用下,混凝土类型和截面形状对新型S35657奥氏体不锈钢管混凝土构件的破坏模态、荷载-变形关系、抗弯刚度与承载力的影响规律。试验结果表明:固废混凝土对新型不锈钢管混凝土纯弯构件的整体破坏模态影响不大,但固废混凝土有利于提高构件的抗弯承载力与刚度。随后建立了不锈钢管固废混凝土纯弯构件有限元模型并验证了既有材料模型的适用性,最后分析了各规范抗弯承载力计算方法的适用性和预测精度。

爆炸荷载作用下不锈钢管混凝土构件工作机理研究

本文进行不锈钢管混凝土构件在爆炸荷载作用下力学性能的试验研究,试验参数包括钢管截面形式(圆形、方形)、比例距离及有无填充混凝土。建立爆炸荷载作用下不锈钢管混凝土构件动态响应的有限元分析模型,模型计算结果得到试验结果的验证。基于验证的有限元计算模型,对比分析不同条件下不锈钢管混凝土和普通钢管混凝土构件的破坏形态、动态响应和耗能规律。试验和有限元分析结果均表明:随着比例距离减小,构件的破坏程度由弹性变形到弯曲破坏或剪切破坏;混凝土的填充能够有效延缓钢管发生局部屈曲和破坏,构件的承载能力、变形能力和耗能能力得到有效提升,进而提高构件的抗爆性能。在近场爆炸范围内,不锈钢管混凝土和普通钢管混凝土构件均出现三种可能的整体破坏形态,即弯曲破坏、弯剪破坏和剪切破坏,另还伴随有较明显的局部破坏形态;在条件相同包括名义屈服强度相同的情况下,不锈钢管混凝土构件的抗爆性能优于相应普通钢管混凝土构件。

电力火灾后圆端形不锈钢管混凝土柱轴压性能研究

进行了14根电力火灾后圆端形不锈钢管混凝土短柱的轴压试验,分析截面高宽比、受火时间和含钢率对其火灾后剩余承载力的影响。试验表明:该类短柱的破坏模态均为局部屈曲、焊缝开裂和混凝土被压碎;试件的剩余承载力随着受火时间或高宽比的增加而降低,受火120 min后该类试件的承载力降低了7.8%~13.9%。接着建立了有限元模型,该模型可很好地模拟实测结果。基于有限元模型开展了理论分析,结果表明初始荷载对该类组合柱的剩余承载力影响较小。参数分析表明当混凝土强度从30 MPa增加到90 MPa时,其强度折减系数降低了15.8%;当截面周长从1 228 mm增加到4 913 mm时,其强度折减系数提高了20.5%;当受火时间从0 min增加到180 min时,其强度折减系数降低了8%;但含钢率、高宽比和钢材强度对其强度折减的影响较小。最后给出了电力火灾后圆端形不锈钢管混凝土短柱的剩余承载力的设计方法。

AISI-304不锈钢薄壁管滚珠旋压工艺参数的正交优化研究

针对小直径不锈钢薄壁管滚珠旋压参数不当引发的一系列问题,选取φ6 mm×0.5 mm×10 mm的AISI-304不锈钢管为研究对象,建立其有限元模型,运用Abaqus软件对其成形过程进行仿真,分析了不同工艺参数(减薄量、进给比、旋压角)对其等效应力和均匀塑性应变的影响,最后运用正交试验法对工艺参数进行优化。结果表明:优化后的工艺参数组合为:减薄量0.2 mm、进给比0.05 mm/r、旋压角25°。在此工艺参数组合下,AISI-304不锈钢管的等效应力值和均匀塑性应变值达到最优,其值分别为642.22 MPa和0.06。

通风管三通相贯线处焊接坡口自动切割机的研究与设计

通风管三通焊接前需要切割相贯线处的坡口,焊缝坡口的准备对后续焊接工作至关重要。同时,还设计了以液压传动及其控制系统为核心的通风管三通相贯线处焊接坡口自动切割机。其具有钢管夹紧力可控,快、慢速运动有效结合,提高了生产效率,保证了坡口切割质量,改善了工人劳动条件。液压传动及其控制系统的应用为钢管自动切割提供了必要条件,方案合理可行,机构简单紧凑,将具有广阔的应用前景。

双不锈钢管约束海水海砂混凝土柱轴压试验及承载力计算模型

目的 研究双不锈钢管约束海水海砂混凝土柱(DSTSCC)试件的轴压性能、破坏形态和轴压承载力计算模型,为该类构件的轴压承载力计算提供试验和理论研究参考。方法 对24个DSTSCC试件进行轴压试验,分析外管壁厚、芯管壁厚和芯管直径等参数对其破坏形态、应力-应变曲线和承载力的影响规律。结果 双不锈钢管约束试件的破坏形态以腰鼓型破坏为主;由于不锈钢受拉本构无明显的屈服台阶,可以持续地约束核心混凝土,试件应力-应变曲线无明显的下降段,表现出较好的延性特征;随外管壁厚增大,轴压承载力可提高6%~25%;随芯管壁厚增大,轴压承载力可提高3%~20%;随芯管直径增大,轴压承载力呈现为先提高后降低的趋势。结论 基于试验破坏机理分析和理论分析,所建立DSTSCC试件的轴压承载力计算模型相较于既有承载力计算模型,具有更好的适用性。

某凝析油稳定塔塔底重沸器2205管束的腐蚀失效原因

某油田凝析油稳定塔塔底重沸器2205双相不锈钢换热管束发生开裂失效。通过宏观检查、化学成分和组织检查、残余应力测试、断口分析以及应力腐蚀试验系统分析了其失效原因。结果表明:换热管束失效多集中在U形弯区域,裂纹多呈现环向开裂特征;在失效管束U形弯区域存在残余拉应力,其最大值达到262 MPa;断口表面可见明显的解理和准解理特征,以及二次裂纹。综合分析结果可知管束失效原因为高温-结盐-氧引起的氯化物应力腐蚀开裂。

冷凝液汽提系统夹套管不锈钢内管开裂失效分析

某化工企业甲醇中心净化装置冷凝液汽提系统夹套管不锈钢内管发生开裂泄漏,通过宏观观察、化学成分分析、力学性能测试、金相分析、硬度测试、能谱分析和断口扫描电镜分析等手段对失效原因进行了分析。结果显示:夹套管不锈钢内管力学性能不符合标准要求,且内部凹坑与裂纹均在酸洗前已存在,为原始制造缺陷。

基于机器学习的不锈钢管混凝土构件轴压承载力预测方法研究

基于收集的189个不锈钢管混凝土构件的轴压试验数据建立了机器学习数据库,采用6种机器学习模型(随机森林、决策树、支持向量机、多层感知器、极端梯度提升和自适应提升)分别对圆形和方形截面不锈钢管混凝土构件进行了轴压承载力预测研究,同时分析了不同参数对机器学习模型预测精度的影响。研究结果表明,上述6种机器学习预测模型中预测精度最高的是极端梯度提升模型,对于圆形和方形截面构件所有参数的预测,该模型的均方根误差分别为0.0435和0.0188,且预测值与试验值之比的变异系数分别为0.127和0.166,相较于现有标准,该模型表现出更高的预测精度和更广泛的适用范围,可为工程应用提供数据支撑和理论指导。