THE FULLY PLASTIC J-INTEGRAL OF CORNER CRACKS AT A HOLE IN A PLATE

The line-spring model of surface cracks is applied to the fully plastic analysis of corner cracks at a hole in a plate. The generalized fully plastic constitutive relations and the fully plastic J-integral, as well as its coefficients in polynomial expressions are given. The model obtained is incorporated into a finite element program. The corner cracks at a hole in a plate subjected pure tensions are calculated by the present model. The fully plastic J-integral is then estimated. The results obtained show that the line-spring model is effective for the analysis of corner cracks. The influence of the crack depth and the hardening exponent on the fully plastic J-integral is also discussed.

STRESS INTENSITY FACTORS FOR CORNER CRACKS AT A HOLE UNDER REMOTE TENSION

The three-dimensional weight function method recently developed by the authors is used to determine stress intensity factors for two symmetric quarter-elliptical corner cracks at a hole in a wide finite-thickness plate subjected to remote tensile loading. The geometry parameters considered are r / t = 0.5, 1, 2; a / c= 0.2, 0.5, 1, 2; a / t = 0.2, 0.5 within c/r= 2. The results are compared, where possible, with other solutions available in the literature. Generally good agreement is observed. The effect of an approximation of the two-dimensional unflawed stress distribution on the accuracy of stress intensity factors by the weight function method is discussed.

Longitudinal corner crack of chamfered slab and optimization of mould

Chamfered mould has gradually become a new technology equipment to eliminate transverse corner crack.However,longitudinal corner crack ratio of chamfered slab was very high.Solidification microstructure was detected in the area where the longitudinal corner crack occurred.Effect of narrow face shape and taper distribution of mould copper plate on longitudinal corner crack was studied by industrial tests.Water velocity distribution in the narrow copper plate was studied by numerical simulation.On the premise of preventing cooling water from nuclear boiling,improvement measures of mould cooling process and water seam structure were put forward through heat transfer calculation.The results showed that local taper of the meniscus region of mould should be increased to prevent generation of longitudinal corner crack.Chamfering slope length of narrow copper plate should be controlled within 55 mm,and chamfering angle should be controlled at about 30°.Average water velocity should be more than 7.0 m/s.The flat and chamfering regions of narrow copper plate working face should be designed as double taper and funnel structure,respectively.The water seam in the chamfering region should preferentially choose the combined cooling structure with two holes and one slot.In order to prevent the extension of longitudinal corner crack,chamfered narrow face foot roller should be used.

Technology Development for Controlling Slab Transverse Corner Crack of Typical Micro-alloyed Steels

A mathematical model for simulating the fluid flow, heat transfer and solidification in the conventional mold and the chamfer mold, together with a finite element stress-strain model in the straightening process of both molds, were established for the typical niobium, vanadium, and titanium micro-alloyed steels. On the basis of both numerical analysis, the mold copper plate with an optimum chamfered shape was designed and applied in industrial tests. The predicted results from numerical simulation of fluid flow, heat transfer and solidification in the conven tional mold and the chamfer mold show that the increased chamfered angle leads to an approximately linear increase o[ the slab surface temperature, but it also causes strong flow near the slab corner. Very small chamfered length can lead to a significant increase of the temperature near the slab corner. However, with further increasing the chamfered length, the temperature of the slab corner increased slightly. The calculated results from the finite element analysis of stress-strain during the straightening process show that at the same slope width, the tangential strain on the slat） edges and corners is minimum when the chamfered angle is 30° and 45°, which is only 40° to 46° of rectangular slabs with the same cross-section area. At the same chamfered angle of 30°, when the chamfered length is controlled between 65-85 mm, the tangential strain on the part of the slab edges and corners is relatively smaller. Industrial test results show that the slab corner temperature at straightening segment increases about 100 ℃ by using chamfer mold compared to the conventional molds. The slab transverse corner cracks have been reduced more than 95° in comparison with those in the conventional mold.

Q235连铸板坯角部裂纹形成机理及控制

为了解决Q235连铸坯角部裂纹缺陷,采用缺陷微观形貌分析和工艺参数影响规律统计分析相结合的方法研究了缺陷形成原因。结果表明:铸坯矫直前AlN大量析出是其产生角部裂纹的主要原因。基于AlN析出热力学分析,随着钢中铝和氮含量降低,AlN开始析出的温度下降,矫直温度范围内AlN析出量显著减少。考虑实际生产,确定了降铝措施作为改善铸坯角部裂纹缺陷的控制措施,现场应用后,Q235连铸板坯角部裂纹指数由3.59下降到0.19,钢中铝的质量分数平均下降126.64×10^(-4)%,合金使用成本降低。

厚硬顶板隅角悬顶分段多次水力压裂技术研究

针对煤矿综采工作面厚层坚硬顶板隅角悬顶问题,建立了“弧三角形”悬顶结构模型,分析了隅角悬顶的形成机理。通过研究水力压裂弱化顶板岩层的作用机理,创新提出分段多次水力压裂技术并对顶板进行预裂切顶,在采空区采动压力与煤柱支承压力共同作用下,实现隅角顶板及时切落。现场试验结果表明,采用水力压裂后,隅角顶板及时垮落,最大悬顶长度控制在10 m以下。研究可为类似条件矿井提供借鉴和参考。

60Si2Mn弹簧钢盘条拉拔裂纹原因分析

针对60Si2Mn弹簧钢盘条在拉拔、淬火后出现的表面裂纹,通过对缺陷钢丝进行取样分析,确认为连铸坯缺陷导致,进而检查铸坯发现铸坯存在角部裂纹与之相对应。对铸坯角裂产生的原因进行分析,并提出了有效的控制措施,最终消除了铸坯角部裂纹缺陷。

冷轧双相钢DP590的连铸坯角部横裂纹研究

冷轧双相钢DP590连铸坯角部横裂纹给冷轧产品的质量带来很大困扰,导致其后续连退产品边部出现夹渣、翘皮或裂纹等缺陷。通过对连铸坯角部横裂纹部位进行观察,发现角部横裂纹发生在连铸坯的振谷部位,横裂纹向铸坯宽面和窄面有一定的延伸,发生横裂纹的振谷通常是不规则振痕,其形貌带有横向的凹陷特征。通过连铸坯的枝晶侵蚀试验发现,连铸坯发生角部横裂纹的部位,二次枝晶间距大,裂纹处的连铸坯表面冷却速率显著低于正常的连铸坯表面,这说明连铸坯坯壳冷却均匀性需要改善。并且裂纹附近有明显异常粗大的枝晶间距,通过电子探针检测发现这些异常粗大枝晶间存在硫、锰的富集现象,说明这是凝固过程中枝晶间发生断裂,富集锰硫溶质的钢液补充形成的。结合浇铸的结晶器热电偶测量温度趋势,判断该型保护渣控制传热能力以及渣膜的稳定性不足。通过优化保护渣和提高铸坯拉速,消除了连铸坯凹陷和角部横裂纹。

180 mm×180 mm AH32钢铸坯振痕特征对其角部横裂的影响

AH32钢连铸坯常用于制作球扁钢。某尺寸为180 mm×180 mm的AH32钢铸坯角部出现横向裂纹。为此,采用热酸洗、图像处理、扫描电子显微镜等研究了铸坯角部和中部振痕的不均匀度和深度对其角部横裂纹发生的影响。结果表明:铸坯角部振痕不均匀度小于14%时,角部横裂发生率均值为0.75%,大于14%时角部横裂发生率明显增大;铸坯中部振痕不均匀度小于44%时,角部横裂发生率小于0.50%,且铸坯角部振痕深度控制在500μm以内,角部横裂发生率能保持在0.25%以下,满足质量要求。

管坯用圆钢12Cr1MoVG表面长裂纹原因分析及改进措施

按照GB/T 31212—2014标准对12Cr1MoVG管坯用圆钢进行了表面漏磁探伤,结果表明,深度>0.30 mm的长裂纹比例占15%左右,分析发现造成管坯用圆钢表面长裂纹的主要原因是铸坯角部裂纹。通过采取将中包钢水过热度由15~30℃提高到35~45℃,铸坯拉速由0.85 m/min提高到0.95 m/min,铸坯采取弱冷和均匀冷却等措施来解决了该问题。12Cr1MoVG管坯用圆钢长裂纹比例降到了3%以下。

高强焊丝钢N2M2T连铸坯表面缺陷分析及工艺改进

针对某钢厂在冶炼N2M2T高强焊丝钢时,连铸坯表面出现的凹陷、角部深振痕裂纹及渣坑等表面缺陷,结合理论分析及现场实际生产情况,从保护渣理化性能、结晶器振动参数、一冷配水及钢中N含量等对铸坯表面产生的缺陷进行分析。结果表明,连铸坯产生的表面缺陷主要与保护渣理化指标、结晶器振动参数、钢中N含量有关,而与一冷配水关系不大。生产实践表明,通过将保护渣碱度从0.6提高到1.19,w[C]从13.51%降低到8.21%,粘度从0.666 Pa.s降低到0.156 Pa.s,结晶器振动参数偏斜率由0.15提高至0.20,振频公式由60+50 V调整为90+60V,钢中N含量控制在<50×10^(-6),连铸工序△N<7×10^(-6)等措施,N2M2T高强焊丝钢连铸坯的表面缺陷得到明显改善,铸坯合格率从85%提高到95%以上,为后续轧钢的稳定轧制提供了保证。

重轨大方坯角部纵裂原因及控制

针对重轨大方坯生产中出现的铸坯角部纵裂问题,分析了铸坯角部纵裂形成机理,通过加强结晶器使用管理、结晶器对弧精度、优化结晶器冷却制度、改进结晶器保护渣性能等措施,能够有效控制重轨铸坯角部纵裂的发生。

锅炉集箱水冷壁管座裂纹的问题分析与预防

工业锅炉中集箱与水冷壁管连接处管座角焊缝焊接质量是保证锅炉安全使用的重要因素,当管座角焊缝出现裂纹情况时,检验人员应排查角焊缝裂纹发生的主要原因,对锅炉集箱管座角焊缝开裂问题进行原因分析,总结出防止焊缝产生裂纹的预防措施,希望为从事相关工作人员提供参考和借鉴。

中厚板铸机改造及铸坯质量提升

某钢厂为了提升其中厚板连铸机的铸坯质量,在原有铸机设计的基础上进行了自主升级改造。通过对扇形段0段上部增加定位轴、下部增加定位槽,1段上部增加定位块,改变0、1段对中方式;将9~12段轻压下方式改为辊缝和压力双控制模式;中间包液位高度从850 mm提升到1200 mm,底部宽度从1190 mm提升到1290 mm,底部长度从3761 mm提升到3956 mm,侧壁倾角调整为15℃,采用“稳流器+挡坝+挡墙”的内部结构控流方式;将二冷区的冷水管路由18路增加到32路,铸坯角部横裂纹发生率由8%降低到0.3%以下,铸坯内部中间裂纹基本消失,对应生产的钢板其探伤合格率从94.6%提高到99.7%,B类夹杂物2.0及以下比例由94.3%提高到98.5%,针对性地解决了铸坯角横裂纹、中间裂纹发生率较高的问题,提高了钢板的探伤合格率和夹杂物合格率。

中薄板坯角部纵向边裂的原因与措施

分析了中薄板坯角部纵向边裂的影响因素,采取优化结晶器振动台控制系统和同步精度,优化结晶器锥度,提高结晶器整备精度,适当减小结晶器冷却水量,提高扇形段辊缝和接弧精度标准等措施后,中薄板坯角部纵向边裂发生率由3.5%降至1.0%,保证了中薄板坯产品的质量。

谐载欠采样图像采集疲劳裂纹在线测量方法

针对谐振疲劳裂纹扩展试验中,由裂纹闭合引起裂尖和背景区域图像灰度对比度不高造成的裂纹长度动态测量精度不高、稳定性不够的问题,提出一种谐振载荷状态下基于欠采样频闪图像采集疲劳裂纹长度在线测量方法。该方法首先在一个欠采样周期内通过同步控制器硬触发摄像机等间隔采集裂纹试件图像,同时载荷控制器获得与采集图像匹配的一系列载荷点,对载荷点进行最小二乘曲线拟合,拟合曲线幅值点近似谐振载荷最大点;然后将幅值点与邻近载荷点相位差对应时间反馈给同步控制器校准采集间隔,使每个欠采样周期采集接近谐振载荷最大点的裂纹张开图像;最后采用基于亚像素角点检测裂纹长度测量方法对裂纹张开图像进行在线测量。试验结果表明:测量数据稳定,测量精度可达0.025 mm。

CRTSⅢ型板式无砟轨道底座凹槽四角裂缝产生机理及结构优化措施研究

针对高铁CRTSⅢ型板式无砟轨道底座板施工过程中限位凹槽出现的四角裂缝病害,引入混凝土损伤塑性本构关系,建立底座板限位凹槽非线性随机损伤有限元分析模型,研究底座板凹槽四角裂缝产生机理并提出结构优化措施。研究结果表明:在较大负温度梯度荷载作用下,底座板凹槽四角位置会出现与现场实际情况相符的受拉损伤,负温度梯度为底座板凹槽四角裂缝产生的主要温度荷载条件,现场应重点关注轨道结构的负温度梯度情况;倒角能明显提高底座板凹槽四角混凝土损伤产生的临界负温度梯度,对限位凹槽的损伤情况也有一定程度改善,建议限位凹槽四角倒角半径取80~100 mm。现场应用情况表明,限位凹槽四角倒角结构优化设计对抑制凹槽四角裂缝产生效果明显。

1Cr11Ni2W2MoV钢疲劳裂纹闭合与试样类型的相关性

压力容器材料的疲劳裂纹扩展门槛值在预测服役寿命方面具有重要意义,而门槛值的准确测定常受到裂纹闭合的影响。为了验证采用角裂纹(CC)试样测定疲劳裂纹扩展门槛值时是否受裂纹闭合影响,采用1Cr11Ni2W2MoV钢加工了角裂纹试样和紧凑拉伸(C(T))试样,在室温下开展了疲劳裂纹扩展门槛值试验,并测定了门槛值对应的载荷-裂纹张开位移曲线。通过扫描电子显微镜对断口形貌中由裂纹闭合产生的磨损痕迹进行了观察。结合试验结果分析了两种试样类型的裂纹闭合程度及成因。通过CC试样测定的门槛值与C(T)试样相近或更小。在所测试4个CC试样中,仅有一个出现了足以影响裂纹扩展驱动力的裂纹闭合现象,而在所有测试的C(T)试样中均观察到了裂纹闭合。CC试样可用于疲劳裂纹扩展门槛值试验,并在当前试验条件下获得了接近理想门槛值的结果。

反应堆压力容器接管区角裂纹应力强度因子影响系数法适用性分析

分别采用有限元法(FEM)和合乎使用(FFS)规范ASMEⅪ附录G,API 579,RCC-MRx中的影响函数法计算了断裂力学参数,求解了不同工作载荷和不同裂纹尺寸下的反应堆压力容器接管区角裂纹应力强度因子(SIF),对比了不同方法中SIF计算结果的差异,并讨论了采用不同合乎使用规范进行工程结构断裂参量计算的适用性。结果表明,对于裂纹前缘最深点应力强度因子的计算,随着裂纹尺寸的增加,基于API 579和方法2的SIF结果由不保守约10.00%逐渐变化为保守约10.00%;RCC-MRx方法的保守度为12.50%和20.00%之间;ASME方法1的SIF结果的不保守度逐渐增大,最大不保守程度可达到15.00%左右。对于裂纹前缘SIF最大值的计算,API 579,ASME方法1和ASME方法2的不保守度可接近20.00%;ASME方法2比其他3种方法的不保守度更大,最高可达34.65%。现有的FFS规范方法不适用于计算接管区角裂纹前缘的最大值,需要发展新的计算方法或公式。

YOLOv5超声波图像识别技术在高原高寒钢轨探伤中的应用

高原高寒地区环境复杂、昼夜温差大,对铁路建设与运营产生不良影响,容易发生由于钢轨内部伤损引起的断裂事故。研究基于YOLOv5的超声波图像识别技术在青藏铁路钢轨探伤检测中的应用,特别是针对轨头核伤、轨面鱼鳞伤等常见伤损类型进行检测。通过智能钢轨探伤仪采集高寒地段钢轨数据,以YOLOv5方法对数据集进行整理、处理和模型训练,精准识别和定位轨头核伤、轨面鱼鳞伤等损伤。研究表明,基于YOLOv5的模型在识别和定位各类钢轨损伤方面具有很高的准确性和实时性,可以同时进行目标检测和类别分类,并能在保持较高准确度的同时实现快速检测。提供一种新的、更有效的钢轨探伤检测数据分析方法,有助于提高铁路安全和运营效率。