弯管元件机械阻抗研究

管路元件阻抗是管路系统振动和声学特性的表征，在管路系统减振降噪设计和计算中具有重要的用途。文章从弯管的振动方程出发，推导了弯管的阻抗计算表达式，并通过给定尺寸的弯管元件阻抗数值计算，分析了弯管相对于直管的机械阻抗差异以及参数变化对机械阻抗的影响。     

缠绕式弯管机上的管路的弯曲回弹与伸长规律

介绍如何通过实验分析的方法,研究缠绕式弯管机上管子的回弹与伸缩规律.管路的弯管精度直接影响管路装配过程.而影响弯管精度的关键因素就是管路回弹.弯管机、管子的机械特性、尺寸、机床的刚性等都对回弹有较大影响.通过理论计算获得能在缠绕式弯管机生产实验中使用的公式是困难的.介绍了如何通过实验分析方法得到弯管回弹与伸长规律.     

织物增强复合材料梁结构热校形工艺

本文借鉴金属零件热校形工艺的经验,利用复合材料在高温下的应力松弛现象,通过热校形工艺修正复合材料零件的形状。制造了碳纤维平纹织物/环氧复合材料L形梁、C形梁,通过自制的热校形模具,以实验方法研究热校形时间、热校形载荷对零件形状的影响,分析复合材料热校形工艺的可行性。研究表明,复合材料热校形工艺中零件变形的主要原因是零件在高温下发生应力松弛,其他因素可以忽略;热校形载荷、热校形时间都对热校形工艺的效果有重要影响。针对特定的复合材料结构,采用合理的热校形工艺过程能够有效地控制构件形状,方便零件的装配。     

复合材料机翼结构热校形工艺实验及数值模拟

纤维增强树脂基复合材料机翼结构复杂,往往存在明显的固化变形现象,严重影响机翼的装配和气动特性。本研究目的在于建立大型复合材料复杂结构的热校形工艺方法,解决复合材料机翼制造的变形控制问题。针对复合材料机翼的固化变形特点,设计了新的热校形夹具工装。在评价复合材料应力松弛特性的基础上,建立了大型复合材料机翼结构热校形工艺的有限元模拟方法,实现了对热校形后机翼结构残余变形的有效预报,分析了校形载荷、校形温度等关键工艺参数对校形效果的影响规律,形成优化的热校形工艺方案。模拟及实验结果表明,复合材料热校形工艺可以适用于大型复杂结构,复合材料机翼89.5%的固化变形被热校形工艺的残余变形抵消,达到机翼的装配和气动外形要求。      

X80热煨弯管热处理工艺对组织及性能的影响

研究了不同热处理工艺对热煨弯管母材及焊缝组织及性能的影响。通过对热煨弯管两种不同热处理工艺的研究,探讨了X80热煨弯管热加工工艺过程中热处理制度对母材及焊缝组织和性能的影响规律。结果表明,高温淬火(950℃)+高温回火(500℃)的工艺能够明显的改善焊缝及热影响区的组织,细化焊缝热影响区的组织,并能够有效地解决热煨弯管母材和焊缝的组织及性能匹配性,适宜于X80热煨弯管的加工。     

X70大变形管环焊接头及断裂机制研究

目的基于应变设计大变形管线环焊接头热影响区的软化问题,解决制约管线安装质量和服役寿命等难题。方法通过显微硬度测试、微观组织分析,研究了X70大变形管接头热影响区的软化原因,并利用数字相关法研究了焊接接头拉伸过程中的断裂机制,还对焊接接头热影响区进行了激光增强探索。结果 X70焊接接头热影响区粗晶区的最大硬度损失达HV0.239;软化区最大应变达到37%以上;经过热影响区激光重熔后,X70钢焊接接头抗拉强度可提高10%以上,断裂位置均位于母材。结论 X70焊接接头热影响区粗晶区存在明显的软化;拉伸过程中在软化区出现了明显的应变集中,是X70焊接接头断裂于近缝区的主要原因;焊接接头热影响区粗晶区粗大的粒状贝氏体和铁素体导致了焊接接头热影响区的软化。     

某挤出机螺杆断裂原因分析

某德国进口的熔融挤出机在投入使用7a(年)后螺杆发生断裂,采用断口宏观分析、化学成分分析、拉伸试验、断口微观分析、金相检验、显微硬度测试等方法,对螺杆断裂原因进行了分析。结果表明:断裂螺杆的滚条堆焊层热影响区宽度不均匀,显微组织变形,材料中的脆性夹杂物在外力作用下引起应力集中是螺杆热影响区萌生裂纹源的主要原因;裂纹在螺杆扭转应力作用下沿堆焊层逐渐扩展最终导致疲劳断裂。     

保持时间对定向合金DZ125热/机械疲劳断裂行为的影响

对DZ125定向凝固铸造镍基高温合金进行了应变比为-1.0的同相位三角波和同相位梯形波,550℃()1000℃热/机械疲劳实验研究.实验结果表明:在相同应变幅下,同相位三角波载荷情况下的热/机械疲劳寿命比同相位梯形波载荷情况下的热/机械疲劳寿命长.研究了在两种载荷情况下材料的热/机械疲劳循环应力响应行为.试样断口的微观分析表明:在热/机械疲劳过程中,同时存在疲劳、蠕变和氧化损伤;在同相位三角波载荷下,穿晶 沿晶断裂为疲劳断裂的主要特征;在同相位梯形波载荷下,裂纹主要为沿晶萌生与扩展.这是导致在同相位梯形波载荷下疲劳寿命缩短的主要原因.     

热弯成形对双相不锈钢弯管焊缝低温冲击性能的影响

某LC65-2205双相不锈钢焊管在热弯成形后进行低温冲击试验,发现弯管焊缝的冲击性能严重降低。采用金相检验、断口分析、热处理工艺验证等方法,研究了热弯成形对弯管焊缝低温冲击性能的影响。结果表明:焊管热弯成形过程中冷却速度较慢导致大量σ相析出,使位错滑移受阻,大量位错聚集在弯管焊缝并造成应力集中,最终导致焊缝的低温冲击性能显著下降。     

Q460高强钢材及T形对接接头超低周疲劳特性

为明确高强钢材焊接接头的超低周疲劳特性,进行了Q460高强钢母材、焊缝、热影响区钢材及T形全熔透对接焊接接头的超低周疲劳加载试验,基于试验结果校正了Q460高强钢材的随动-等向混合强化材性参数,识别了其循环微孔扩张模型(CVGM)微观断裂预测模型参数,在ABAQUS软件中建立Q460高强钢T形焊接接头的精细化三维有限元模型,采用CVGM模型准确预测了焊接接头循环荷载下的延性断裂行为,继而变化板厚、板件夹角和板件标准段长度针对接头断裂性能进行了参数分析。结果表明,往复荷载作用下,Q460高强T形对接接头失效前内部存在两处危险地带,即钢板内逐步形成的塑性条带和热影响区,接头的断裂特性取决于这两处的缺陷和损伤累积状况。随着板厚、板件夹角和板件标准段长度的增加,对接接头的超低周疲劳寿命断裂延长,位移延性系数增大。     

6005A铝合金挤压型材搅拌摩擦焊接头的疲劳性能

对6005A-T6铝合金挤压型材进行焊速为1000 mm/min的搅拌摩擦高焊速焊接,研究了对接面机械打磨对接头组织和力学性能的影响.结果 表明,与生产中常用的焊前打磨处理相比,尽管对接面未机械打磨的接头焊核区的"S"线更明显,但是两种接头的硬度分布和拉伸性能相当,拉伸时都在最低硬度区即热影响区断裂.高周疲劳实验结果表...     

高强度结构钢及其接头热影响区的疲劳及断裂性能分析

采用焊条电弧焊对48 mm厚高强度结构钢进行焊接,对焊接接头热影响区疲劳裂纹扩展门槛值ΔK_th、裂纹扩展速率da/dN和断裂韧度K_IC进行研究并与基体进行对比。结果表明,在室温下,焊接接头热影响区具有更好的疲劳和断裂性能;随着与熔合线距离的增大,热影响区的组织依次为粗大板条状贝氏体+奥氏体薄膜、细粒状贝氏体、回火索氏体+细粒状贝氏体,硬度逐渐下降;在室温下,焊接接头热影响区和基体冲击韧性均位于上平台。热影响区的残余奥氏体薄膜和硬度较高的贝氏体是影响其疲劳和断裂性能的重要因素。      

Effects of mechanical heterogeneity on the tensile and fatigue behaviours in a laser-arc hybrid welded aluminium alloy joint

The effects of mechanical heterogeneity on the tensile and high cycle fatigue (10⁴–10⁷ cycles) properties were investigated for laser-arc hybrid welded aluminium alloy joints. Tensile–tensile cyclic loading with a stress ratio of 0.1 was applied in a direction perpendicular to the weld direction for up to 10⁷ cycles. The local mechanical properties in the tensile test and the accumulated plastic strain in the fatigue test throughout the weld’s different regions were characterized using a digital image correlation technique. The tensile results indicated heterogeneous tensile properties throughout the different regions of the aluminium welded joint, and the heat affected zone was the weakest region in which the strain localized. In the fatigue test, the accumulated plastic strain evolutions in different subzones of the weld were analyzed, and slip bands could be clearly observed in the heat affected zone. A transition of fatigue failure locations from the heat affected zone caused by accumulated plastic strain to the fusion zone induced by fatigue crack at pores could be observed under different cyclic stress levels. The welding porosity in the fusion zone significantly influences the high cycle fatigue behaviour.     

3044 t/h超超临界锅炉磨煤机拉杆断裂原因

某电厂3044 t/h超超临界锅炉磨煤机拉杆发生断裂,通过化学成分分析、断口分析、力学性能测试和金相检验等方法对拉杆断裂原因进行了分析.结果表明:该拉杆供货态热处理质量较差,导致强度和冲击韧性指标不合格,且磨损补焊处因热处理不到位而产生冷裂纹,长期在往复拉应力及弯曲应力的作用下,裂纹疲劳扩展,最终导致拉杆疲劳断裂.     

汽车高强钢SG1000激光复合焊接力学性能研究

目的 针对汽车高强钢SG1000焊接接头恶化等问题,研究了SG1000激光复合焊接的力学性能。方法 选用等强匹配焊丝MG90-G对高强钢SG1000进行激光复合焊接,对焊接接头进行拉伸和低温冲击韧性试验,并结合扫描和硬度监测等手段对焊缝组织和断口形貌进行分析。结果 由于激光的预热作用,高强钢SG1000激光复合焊接成形件的焊缝美观,焊接过程稳定可靠,焊接熔池深度较大,有效改善了传统焊接的咬边、飞溅、气孔等缺陷。焊缝组织主要由板条马氏体和奥氏体晶粒组成,热影响区的过热区内部板条马氏体和奥氏体晶粒比较粗大,而焊接母材主要为细小的板条马氏体和奥氏体晶粒。焊接拉伸断口主要为细小且较浅的韧窝,且韧窝底部存在第二相粒子及夹杂物,焊接拉伸断口断裂于热影响区且微观形貌为韧性断裂;冲击微观形貌主要由准解理小平面及河流花样组成,且存在一定数量大小不一的韧窝交错分布,焊接冲击断口断裂于热影响区且微观形貌也为韧性断裂。结论 焊缝热影响区的晶粒比非热影响区的晶粒粗大,拉伸和冲击断裂均发生于热影响区;随着激光功率的增大,复合焊接接头的力学性能呈现逐渐增强的趋势;随着焊接速度的增大,复合焊接接头的力学性能呈现先增强后削弱的趋势。高强钢SG1000激光复合焊接最佳工艺参数如下:激光功率为9.5 kW,焊接速度为0.8 m/min,对应屈服强度为1 072 MPa,抗拉强度为1 175 MPa,断裂伸长率为13.5%,冲击断裂吸收的能量为30.8 J、焊缝中心显微硬度为342 HV。     

包胶辊开裂原因分析

采用化学成分分析、宏观和微观组织检验以及力学性能测定等方法对在使用过程中发生开裂的包胶辊进行了分析。结果表明，由于错误地将平衡重焊在了辊筒内壁，由此造成辊筒的显微组织和力学性能以及受力状况发生了变化。在承受频繁的弯曲应力作用后，在其焊接热影响区萌生了裂纹源进而发生疲劳开裂。     

Characterization of failure modes for different welding processes of AISI/SAE 304 stainless steels

Weld joints manufactured with a welding electrode type 308L and by three different arc welding processes shielded metal arc welding (SMAW), gas metal arc welding (GMAW) and flux cored arc welding (FCAW) in a AISI/SAE 304 were studied in order to compare the failure mechanisms associated with their mechanical and microstructural properties. Chemical compositions were analyzed by optical emission spectroscopy and the ferrite numbers (FN) of the welds were also identified. Relevant microstructural characteristics of the different processes were analyzed by microscopy techniques. Finally, fatigue tests were performed to study the variations in the mechanical properties of each process and to analyze their most probable failure modes by means of a fractographic study, in which the characteristic morphologies of each one (nucleation, propagation, final fracture) were identified by means of optical stereoscopy and scanning electron microscopy (SEM). Three different fracture modes were found at the welding joints that showed correlations with microstructural changes produced during the welding process. The first failure mode displayed that the nucleation of the crack was at the weld root. The second failure mode was generated at the heat affected zone (HAZ), where the crack nucleated due to a variation in the grain size produced by the process and then further propagated through the edge of the weld. The third failure mode appeared due to the presence of exogenous inclusions generated by the welding process, which acted as stress concentrators in the weld and produce the initiation and further propagation of the crack. Lastly, some welding processes presented a combination of the previous failure modes and consequently multiple sites of crack nucleation.     

Failure investigation of a convection line elbow

Failure investigation was carried out on a cracked 5″ 304L stainless steel elbow tube for the convection line of an ethylene furnace. The crack was observed in the heat-affected zone (HAZ) at the end leading to the elbow parent material. The crack was along the circumference and was about 12″ in length. The crack started from the toe of the weld to the parent metal on the elbow side. The failure investigation revealed that the HAZ of the elbow tube suffered from stress corrosion cracking and mild grain boundary carbide precipitation during welding. The carbide precipitation was possibly due to improper welding practices such as high heat input and/or extended welding time. The tube thickness, which is relatively thick, was a contributing factor in making proper welding more difficult.     

Influence of Heat Input on Microstructure and Mechanical Properties of Laser Welding GH4169 Bolt Assembly—Numerical and Experimental Analysis

By conducting the numerical and experimental analysis, the influence of heat input on the microstructures and mechanical properties of laser welding GH4169 bolt assembly is systematically investigated. The weld formation, temperature field, and residual stress distribution during laser welding by using the finite element modeling are consistent with experimental results. The numerical simulation results show that the increase of heat input imparts lower residual stresses and higher temperature gradient. During the process of laser welding, the steepest temperature gradient and the peak residual stress arise in the fusion zone (FZ). In addition, the dissolution of γ″ and γ′ toward the fusion line increases in heat affected zone (HAZ), but only Laves phase is observed in FZ. With increasing heat input from 24 to 48 J mm⁻¹, the ultimate tensile strength of welded joints decreases. Both the lowest microhardness values and tensile failure of GH4169 alloy laser welded joint are in FZ. Herein, it is that the relationship among the heat input, microstructures, and mechanical properties of GH4196 bolt assembly in laser welding is systematically established, which will be of guiding significance for the selection of welding parameters in aerospace.     

环氧乙烷精制塔开裂原因分析

通过金相检验、断口分析以及腐蚀产物能谱分析等方法,对某石化公司环氧乙烷精制塔开裂的原因进行了分析。结果表明:材料在焊接过程中,焊接热影响区的组织受到敏化影响,铬的碳化物沿晶界析出,造成该区域贫铬,从而在应力和腐蚀介质的共同作用下,发生了晶间腐蚀开裂。最后提出了相应的预防措施。