低电流TIG电弧辅助MIG高速焊咬边缺陷抑制机理及措施的研究

基于温度场、流场、熔滴过渡以及电弧形态检测,开展低电流钨极氩弧焊(Tungsten inert gas welding,TIG)辅助熔化极惰性气体保护(Metal inert gas welding,MIG)高速焊工艺试验。从传热、传质以及受力等角度分析低电流TIG辅助电弧对高速MIG咬边缺陷的抑制机理,并分析各工艺参数对最终焊缝成形的影响。相比常规MIG高速焊,低电流TIG辅助电弧能有效降低MIG高速焊前部熔池边缘的温度梯度,延长熔池存在时间,促进液态金属向焊缝边缘填充。电弧力和熔滴冲击力是影响高速焊咬边缺陷的主要作用力,低电流TIG辅助电弧对MIG熔滴冲击力改变较小,但两电弧耦合后,电弧静、动压力明显降低,可有效地抑制MIG高速焊中咬边缺陷的产生。此外,正交工艺试验显示,丝-极间距和焊枪倾角是影响复合焊工艺的重要参数,而钨极距工件距离和TIG焊接电流则对咬边缺陷的影响较小,通过对丝-极间距和焊枪倾角的调节能快速实现该复合焊工艺参数的优化,抑制咬边缺陷。     

低功率激光诱导电弧复合焊接钛合金薄板工艺研究

采用低功率脉冲YAG激光诱导非熔化极惰性气体保护(Tungsten inert gas,TIG)焊电弧复合热源实现了1 mm厚TC4钛合金薄板的优质焊接,研究激光诱导电弧复合焊接过程中热源能量匹配、热源间角度、对接间隙对焊缝成形的影响规律。结果表明,钛合金薄板低功率脉冲YAG激光诱导TIG电弧复合热源焊接过程中,激光能量与电弧能量之间的相互匹配将显著影响焊缝的表面成形。相对于电弧功率的变化,焊缝成形对激光功率变化的敏感度更高。随着热源间角度减小,激光诱导电弧复合热源传热能力增强;由于复合焊接速度快、热输入小、焊接试板横向变形小,当对接间隙为0~0.5 mm范围内时均能获得良好的焊缝成形。为了使焊缝成形均匀连续,焊接过程中需要对焊缝背面采用氩气进行保护,当保护气体流量为5~8L/min时获得最佳焊接接头。     

TIG-MIG双面对称焊焊缝成形机理研究

就纯铝中薄板,通过单面TIG、MIG和TIG-MIG双面对称焊工艺试验对比,利用ANSYS有限元计算软件进行了TIG-MIG双面对称焊熔池的数值模拟,研究了TIG-MIG双面对称焊的熔池特征及焊缝成形规律。研究表明,TIG-MIG双面对称焊的热源静态累积效应和动态热阻效应使得此焊接方法熔深大大增加,TIG、MIG熔池在焊接过程中发生交汇并在电弧力、熔池表面张力和重力等作用下达到平衡,并由此形成焊缝反面成形。TIG-MIG交汇熔池的稳定性决定焊缝的反面成形特征。     

中厚板铝合金光纤激光+MIG复合热源焊残余应力的数值分析

基于热弹塑性理论性,建立铝合金激光+熔化极惰性气体保护焊(Metal inert gas,MIG)复合热源焊残余应力的三维数值分析模型。激光和电弧热输入分别采用双椭球体热源模型和热流密度峰值指数递增的锥体热源模型描述。利用所建模型,通过ANSYS有限元软件对12 mm厚铝合金复合焊对接接头残余应力进行模拟计算,研究其分布特征,并与MIG焊的计算结果进行比较。同时,将温度场与残余应力的计算结果与试验结果进行对比,验证模型的准确性。研究结果表明,在焊缝及近缝区,纵向拉应力及等效残余应力较大,两者应力峰值均低于材料的屈服强度。而相较于电弧作用区域,激光作用区域残余应力相对较高。焊趾处横向残余表现为拉应力,但应力峰值相对较低。与MIG多层多道焊相比,复合焊纵向应力和等效应力高应力区域明显较窄;焊件上表面复合焊应力峰值小于MIG焊,但下表面应力峰值则较MIG焊大。     

排布方式对铝合金激光-MIG复合横向焊接特性的影响

采用常规激光-熔化极惰性气体保护电弧(Metal inert gas,MIG)复合横向焊接铝合金过程中,焊缝表面极易出现咬边和下塌等缺陷,由此开展排布方式对激光-MIG电弧复合横向焊接铝合金焊接特性的影响研究。分析二者的排布方式对熔池特征、熔滴过渡形式以及焊缝成形规律的影响。试验结果表明,异面引导复合焊接方式对焊缝成形有明显改善作用,焊缝表面熔宽减少、中心线偏移和咬边缺陷得到有效抑制。采用同面引导复合方式时,熔滴过渡到匙孔后方,熔池下侧熔融金属大量堆积并产生周期性的波动,导致焊缝结晶组织出现了分层现象;而采用异面引导复合方式时,熔滴过渡到匙孔下方,并且熔滴在熔池中的落点位置与同面引导方式相比要偏上,熔滴过渡频率稍低,此时熔池中熔融金属分布较为均匀,熔池下部堆积金属较少,有效抑制了焊缝的下塌和咬边缺陷。     

薄壁不锈钢管列置双TIG电弧高速焊接工艺

单钨极惰性气体保护焊(Tungsten inert gas,TIG)是目前工业用薄壁不锈钢管主要生产工艺,但其存在生产效率低的问题。针对高速TIG焊出现的驼峰焊道、咬边等焊缝表面成形缺陷产生的原因,提出列置双TIG电弧高效节能焊接新工艺。试验结果表明,采用双TIG电弧高效焊接新工艺,48 mm×1.2 mm和42 mm×1.5 mm两种规格的409L铁素体不锈钢管在获得良好焊缝成形的条件下焊接速度分别可达5.1 m/min和3.2 m/min;与单TIG焊接生产工艺相比,生产效率分别提高了240%和140%,能耗也分别降低44%和29%。两种规格铁素体不锈钢管膨胀率分别达到14.1%和33.7%,高于单TIG电弧焊的11.2%和21.4%,满足生产要求。分析表明,辅助TIG电弧加热主TIG电弧熔池后部堆积的液态金属,从热和力两方面延长熔池存在时间、促使液态金属回流填平主TIG电弧产生的熔池凹陷,从而有效抑制驼峰焊道和咬边的产生,在高速焊接条件下获得良好的焊缝成形,实现薄壁不锈钢管优质高效节能的焊接生产。     

空心钨极中心负压电弧基础特性研究

为了提高传统钨极惰性气体保护(Tungsten inert gas,TIG)焊电弧的能量密度和热源边界的能量梯度,保证焊接热输入均衡,规避输入能量分散,提出空心钨极中心负压电弧焊接方法,设计并构建空心钨极中心负压电弧焊接系统,介绍系统的组成及操作方法。利用高速摄像机拍摄空心钨极中心负压电弧的宏观形态,进行定点焊接烧蚀试验,并对阳极表面熔池尺寸和焊接接头的宏观形貌进行分析。试验结果表明,在电弧自身刚性的作用下,空心钨极中心负压电弧能够稳定地建立于空心钨极和阳极工件之间;与传统TIG焊电弧相比,在宏观形态上,空心钨极中心负压电弧的弧柱沿径向收缩,呈现拘束状,空心钨极的尖端呈现白炽状态;在焊接接头的宏观形貌上,空心钨极中心负压电弧对应焊接接头的熔深大,熔宽小,焊缝成形好。     

基于视觉反馈的铝合金脉冲旁路耦合电弧MIG焊过程熔宽控制

文章针对脉冲旁路耦合电弧熔化极惰性气体保护焊（melt inert-gas welding,MIG焊）焊缝的熔宽控制问题,利用工业摄像机（CCD）高速拍摄获得的焊缝熔宽视觉传感信号作为输入变量,控制输出变量焊机送丝速度进行焊接过程。通过采用LabVIEW组态软件作为上位机软件,设计使用增量式PID控制器,建立了铝合金脉冲旁路耦合电弧熔化极惰性气体保护焊控制平台,在此基础上利用图像视觉传感技术以及相应的图像处理算法,采用补偿解耦的方式进行4mm的铝合金钢板的焊接试验。结果表明：采用脉冲旁路耦合电弧熔化极惰性气体保护焊的方式,利用视觉信号为反馈量,送丝速度为控制量的控制策略可以实现焊接过程熔宽的实时控制,并保证了焊接过程的稳定和焊缝成型的美观度。     

不锈钢AA-TIG焊接法

针对不锈钢,提出一种新型活性TIG焊方法——电弧辅助活性TIG焊,即AA-TIG焊。采用CO2+Ar作为小电流钨极电弧的保护气体进行单弧AA-TIG焊,分别研究小电流钨极电弧和正常TIG焊工艺参数对焊缝熔深的影响,并针对试验范围内的最佳焊接规范研究不锈钢AA-TIG焊的焊缝成形、焊缝显微组织、化学成分和焊缝性能。采用AA-TIG焊可以单道焊透10mm厚的不锈钢板材,单面焊双面成形。与传统TIG焊相比,焊缝组织和化学成分几乎没有变化,焊缝的耐Cu/CuSO4腐蚀性能和低温冲击韧度都满足相关标准要求。     

低功率脉冲激光-电弧复合热源高效焊接过程中的“匙孔”行为研究

激光-电弧复合热源焊接技术由于具有焊接熔深大、效率高、质量好等优点而受到广泛关注。采用低功率脉冲激光-钨极惰性气体保护(Tungsten inert gas,TIG)焊电弧复合热源技术进行镁合金板材的焊接,研究激光脉冲作用消失之后的等离子体行为和激光"匙孔"行为。在上述试验结果的指导下优化工艺参数,对比研究采用单独激光焊、TIG电弧焊和复合热源焊这三种方法实现镁合金板材对接焊相同效果时焊接效率的差异。研究结果表明,激光"匙孔"和"匙孔"等离子体的形成是实现复合热源高效焊接的前提条件,恰当的工艺参数可以使得激光"匙孔"维持稳定的开口状态,这种状态提高了电弧的稳定性和能量密度,延长了镁等离子体的恢复时间,因此能够提高复合热源的焊接效率。达到相同焊接效果时复合热源的焊接效率分别达到单独激光焊接效率的7.14倍和单独TIG电弧焊接效率的4.29倍。     

Minimal Realization of Linear Graph Models for Multi-physics Systems

An engineering system may consist of several different types of components,belonging to such physical"domains"as mechanical,electrical,fluid,and thermal.It is t...     

INTEGRAL EQUATION METHOD＇S APPLICATION IN HOLE-EDGE STRESS OF COMPOSITE MATERIAL PLATE WITH DIFFERENT SHAPED HOLES

The strength of composite plate with different hole-shapes is always one of the most important but complicated issues in the application of the composite material. The holes will lead to mutations and discontinuity to the structure. So the hole-edge stress concentration is always a serious phenomenon. And the phenomenon makes the structure strength decrease very quickly to form dangerous weak points. Most partial damage begins from these weak points. According to the complex variable functions theory, the accurate boundary condition of composite plate with different hole-shapes is founded by conformal mapping method to settle the boundary condition problem of complex hole-shapes. Composite plate with commonly hole-shapes in engineering is studied by several complex variable stress fimction. The boundary integral equations are founded based on exact boundary conditions. Then the exact hole-edge stress analytic solution of composite plate with rectangle holes and wing manholes is resolved. Both of offset axis loadings and its influences on the stress concentration coefficient of the hole-edge are discussed. And comparisons of different loads along various offset axis on the hole-edge stress distribution of orthotropic plate with rectangle hole or wing manhole are made. It can be concluded that hole-edge with continuous variable curvatures might help to decrease the stress concentration coefficient; and smaller angle of outer load and fiber can decrease the stress peak value.     

Non-monotonic material contrast in scanning ion and scanning electron images

30 keV Ga⁺ focused ion beam induced secondary electron (iSE) imaging was used to determine the relative contrast between several materials. The iSE signal compared from C, Si, Al, Ti, Cr, Ni, Cu, Mo, Ag, and W metal layers does not decrease with an increase in target atomic number Z₂, and shows a non-monotonic relationship between contrast and Z₂. The non-monotonic relationship is attributed to periodic fluctuations of the stopping power and sputter yield inherent to the ion–solid interactions. In addition, material contrast from electron-induced secondary electron (eSE) and backscattered electron (BSE) images using scanning electron microscopy (SEM) also shows non-monotonic contrast as a function of Z₂, following the periodic behavior of the stopping power for electron–solid interactions. A comparison of the iSE and eSE results shows similar relative contrast between the metal layers, and not complementary contrast as conventionally understood. These similarities in the contrast behavior can be attributed to similarities in the periodic and non-monotonic function defined by incident particle–solid interaction theory.     

Application of Feature Extraction through Convolution Neural Networks and SVM Classifier for Robust Grading of Apples

This paper proposes a novel grading method of apples,in an automated grading device that uses convolutional neural networks to extract the size,color,texture,an...     

分布动态载荷识别的抗噪处理

针对正交多项式频域法在用多种响应对矩形薄板进行载荷识别中抗噪性较差的问题,综合运用平均法、矩阵预处理和奇异值截断法等方法对之进行改善,并引入空间映射的思想,将该方法的应用范围拓展为复杂的模型.利用仿真算例,证实了该方法具有较好的抗噪性.     

基于MELTAC-N平台的核电厂安全级DCS环网研究与测试

针对工程实践中环网通讯相关问题的处理缺乏理论基础及国产化安全级DCS平台的开发缺乏成熟经验借鉴问题,对基于MELTAC-N平台核电厂安全级DCS环网的软硬件实现进行了研究。提出了安全级DCS环网双环网冗余设计、光切换开关设计等硬件设计方法,以及以RPR协议为基础,采用全数据收发策略的软件设计方法。在CPR1000安全级DCS平台上对安全级DCS环网的可靠性及实时性进行了评价,并进行了容错能力、响应时间及响应时间稳定性测试验证实验。结果表明,基于MELTAC-N平台安全级DCS环网软硬件设计具有较好的容错能力及响应时间稳定性。     

Short-Term Relay Quality Prediction Algorithm Based on Long and Short-Term Memory

The fraction defective of semi-finished products is predicted to optimize the process of relay production lines, by which production quality and productivity ar...     

End-to-End Multiview Gesture Recognition for Autonomous Car Parking System

The use of hand gestures can be the most intuitive human-machine interaction medium.The early approaches for hand gesture recognition used device-based methods....     

The laboratory simulation of abrasive wear

Abrasive wear has long been recognised as one of the most potentially serious tribological problems facing the operators of many types of plant and machinery; several industrial surveys have indicated that wear by abrasion can be responsible for more than 50% of unscheduled machine and plant stoppages. Locating the operating point of a tribological contact in an appropriate operational ‚map’︁ can provide a useful guide to the likely nature and origins of the surface degradation experienced in use, though care must be exercised in choosing the most suitable parameters for the axes of the plot. Laboratory testing of materials and simulations of machine contacts are carried out for a number of purposes; at one level for the very practical aims of ranking candidate materials or surface hardening treatments in order of their wear resistance, or in an attempt to predict wear lives under field conditions. More fundamentally, tests may be aimed at elucidating the essential physical mechanisms of surface damage and loss, with the longer term aim of building an analytical and predictive model of the wear process itself. In many cases, component surface damage is brought about by the ingress of hard, particulate matter into machine bearing or sealing clearances. These may be running dry although, more usually, a lubricant or service fluid is present at the interface. A number of standardised wear test geometries and procedures have been established for both two- and three-body wear situations, and these are briefly described. Although abrasive wear is often modelled as following an ‚Archard’︁ equation (i.e. a linear increase in material loss with both load and time, and an inverse dependence on specimen hardness) both industrial experience and laboratory tests of particularly lubricated contacts show that this is not always the case: increasing the hardness differential in an abrasively contaminated lubricated pair may not always reduce the rate of damage to the harder surface.     

ANGULAR DISTORTION ALLOWABLE VALUE AND ASSESS METHOD OF WELD ON COKE TOWER

A graph as the new engineering method for estimate the safety of bulging deformation of coke tower is proposed. Through stresses analysis of circumferential weld of coke tower and comparing the stresses produced by pressure with heat stress of steady state, residual stress, bending stress produced by both itself weight and wind loads, it showed that the stresses produced by pressure on the angle distortion are the main factor of equivalent stress of the combined stress. After comparing four kinds of stress controlling conditions, the relation to stress with depth of angular distortion, grade of curvature of angular distortion and half of region of angular distortion has been inferred. Graph of deformation allowable value of coke tower for different condition by angular distortion and half of region of angular distortion has been plotted. The five steps for its engineering use have been explained. The lighter the grade of curvature is, the larger of bulge allowance, may be, and the bigger of depth of angular distortion may pose too. For the coke tower with a popular structure of Dg 5 400 mm×28 mm, the result by graph is nearly more than the result of two formulas formed by other research, the error is less than 7.0%. But, the graph can be easily applied to different size of angular distortion.