Experimental study of electron beam welded titanium alloy to chromium bronze joint with a vanadium sheet

Electron beam welding experiment of titanium alloy to chromium bronze with a vanadium filler metal was carried out. Microstructure of the joint was observed by optical microscopy and scanning electron microscopy. Tensile strength of the joint was evaluated. The fracture surface of the joint was also analyzed. The results showed that the addition of vanadium filler metal reduced the brittleness of joint by increasing the amount of vanadium-based solid solution in the weld. But the melting point of vanadium.filler metal was so high that large heat input was needed to completely melt the filler metal. Thus, a large amount of interfacial compounds were produced. The tensile strength of joint was 280 MPa with a brittle fracture mode.     

激光增材制造TC4/GH4169梯度结构微观组织分析

目的 提高TC4/GH4169梯度过渡界面的元素分布均匀性,削弱界面效应,制备二维TC4/GH4169梯度结构。方法 利用激光增材制造技术,采用TC4-90%TC4+10%GH4169-GH4169的梯度过渡方式制备TC4/GH4169一维梯度材料,并在一维梯度的基础上设计二维梯度结构,制备TC4/GH4169二维梯度材料。利用场发射扫描电子显微镜对TC4/GH4169一维和二维梯度材料内的析出相以及各梯度过渡界面的组织形态进行分析,利用能谱仪对各梯度过渡界面处的元素分布进行分析。结果 一维梯度90%TC4+10%GH4169-GH4169界面相比于TC4-90%TC4+10%GH4169界面材料相互渗透程度更高。由于TC4内Ni元素的加入,在90%TC4+10%GH4169内生成了较多的呈交联网状分布的Ti2Ni析出相。二维梯度样件在水平方向的界面波动程度以及材料相互渗透程度相比于沉积方向更高,其中二维梯度水平方向TC4-90%TC4+10%GH4169界面两侧元素充分扩散,相比于一维梯度TC4-90%TC4+10%GH4169界面处的元素分布均匀性显著提高。结论 通过合适的梯度过渡...     

Numerical analysis on flow field of weld pool during deep penetration electron beam welding of titanium alloy

Flow field of weld pool during deep penetration electron beam welding of TA 15 titanium alloy was numerically and experimentally studied using a hybrid heat source of Gaussian surface heat source and rotational paraboloidal body heat source. And the formation mechanism of the weld pool flow field was analyzed. The results showed that the movement of the liquid metal in the top weld pool was the fiercest and weakened gradually in the middle and bottom of the weld pool. The maximum flow velocity of the liquid metal was about 0. 295 m/s in the top surface of weld pool. The primary driving forces of the movement of liquid metal in the weld pool were the recoil pressure of metal vapor and the surface tension.     

Analysis of metal transfer during electron beam welding with filler wire

The metal transfer mode of electron beam welding （EBW） with filler wire was studied experimentally. The spatial position between the electron beam and the filler wire was defined. Basing on the charge coupled device （CCD） visual sensing system, the metal transfer mode of filler wire was investigated. The results showed that there were five transfer modes during EBW process due to different wire feed rates and spatial positions between beam and filler wire, such as short-circuiting mode, molten metal bridge mode, small droplet mode, big droplet mode and mixed mode. By comparing the weld appearance of different transfer modes, the molten metal bridge transfer was proved to be the best transfer mode.     

TC4/Ti60合金钎焊接头界面组织及力学性能

采用TiZrNiCu非晶钎料实现了TC4和Ti60异种钛合金的真空钎焊连接,利用扫描电子显微镜(SEM)、能谱仪(EDS)和X射线衍射仪(XRD)等分析手段研究了钎焊工艺参数对接头界面组织结构及力学性能的影响. 结果表明,TC4/TiZrNiCu/Ti60钎焊接头的典型界面结构为:TC4/α-Ti+β-Ti+(Ti,Zr)2(Ni,Cu)/Ti60. 随着钎焊温度升高或保温时间延长,片层状α+β相逐渐填充整条钎缝,(Ti,Zr)2(Ni,Cu)相含量减少且分布更加均匀. 接头室温抗拉强度随钎焊温度或保温时间的增加均先增大后减小,在990 ℃/10 min钎焊条件下所获接头抗拉强度达到最大为535.3 MPa. 断口分析结果表明,断裂位于钎缝中,断裂方式为脆性断裂.     

SiO2玻璃陶瓷与TC4钛合金的活性钎焊

分别采用活性钎料AgCuTi和TiZrNiCu对SiO2陶瓷和TC4钛合金进行了钎焊连接,使用扫描电镜和X射线衍射等手段对接头的界面组织和力学性能进行了研究.结果表明,采用两种钎料均能够实现对SiO2陶瓷和TC4钛合金的连接;SiO2/TiZrNiCu/TC4接头的典型界面为SiO2/Ti2O+Zr3Si2+Ti5Si3/(Ti,Zr)+Ti2O+TiZrNiCu/Ti基固溶体/TiZr-NiCu+Ti基固溶体+Ti2(Cu,Ni)/TC4;SiO2,AgCuTi/TC4接头的典型界面为SiO2/TiSi2+Ti4O7/TiCu+Cu2Ti4 O/Ag基固溶体+Cu基固溶体/TiCu/Ti2Cu/Ti+Ti2 Cu/TC4.当钎焊温度为880℃和保温时间为5 min时,SiO2/TiZrNiCu/TC4接头的最高抗剪强度为23 MPa;当钎焊温度为900℃和保温时间为5 min时,SiO2/AgCuTi/TC4接头的最高抗剪强度为27MPa.     

Microstructure and mechanical properties of butt joints of QCr0.8/1Cr21Ni5Ti equal-thickness dissimilar materials by electron beam welding

0　IntroductionThedissimilarmaterialsjointisusuallyemployedinindustrialproductiontomakefulluseofthematerialsperformanceadvantageorspecialstructuralpurpose.Thedissimilarmaterialsjoiningtechnologybetweencopperalloyandstainlesssteelhasattractedagreatdealofattention,botheffectiveassemblageputweldedcomponent’scoolingandhighstrengthintoeffect.However,becauseofbothmaterialschemicalandthermophysicalperformancedifferenceandcomplexityofweldingmetallurgy,thedefectsuchaspore,crackandbrittlephaseandarathe…     

电子束焊接QCr0.8/TC4焊缝反应层结构及成长分析

QCr0.8/TC4偏铜电子束焊接焊缝由熔合区及反应层组成,其中反应层的组织结构、相组成和反应程度是影响接头抗拉强度的主要因素.参考扩散理论,利用Fick第一定律计算了稳态扩散时Cu,Ti两种组元在界面处的扩散通量比.反应层中优先生成CuTi化合物,其在反应层中为连续生成及分布.通过能谱分析得出反应层的组成依次为Cu CuxTi区,CuTi基固溶体区.其中CuxTi为多种化合物的混合,如Cu4Ti,Cu3Ti,Cu2Ti等.由于电子束焊接接头冷却速度极快,TC4侧靠近熔合线处来不及生成第二相化合物,因此反应层处形成的连续金属间化合物CuTi层使该处变得硬脆且残余应力较大,成为影响接头力学性能的主要因素.     

AgCu钎料钎焊TC4钛合金与QCr0.8铬青铜接头界面结构及性能

采用AgCu28钎料实现了TC4钛合金与QCr0.8铬青铜的真空钎焊,利用SEM, EDS以及XRD等分析方法确定TC4/AgCu/QCr0.8接头的典型界面结构为TC4钛合金/CuTi +Cu3Ti2 +CuTi2/Ag(s,s) +Cu4Ti/Ag(s,s)+Cu(s,s)/QCr0.8铬青铜. 研究了工艺参数对接头组织和性能的影响. 结果表明,随着钎焊温度和保温时间的增加,钎缝中银铜共晶组织减少,钛铜化合物增多. 接头抗剪强度随钎焊温度的升高先增加后降低,在钎焊工艺参数为890 ℃/0 min时,获得最大抗剪强度449 MPa.保温时间的延长使得接头脆性钛铜化合物增多,接头性能下降,因此随保温时间延长接头抗剪强度显著降低.     

Synthesis and Properties of Monodisperse Superparamagnetic Mg_（0.8）Mn_（0.2）Fe_2O_4 Nanoparticles Using Polyol Reflux Method

Superparamagnetic monodisperse Mg0.8Mn0.2Fe2O4 nanoparticles have been successfully synthesized in liquid polyol at elevated temperature of 200 °C. Diethylene glycol(DEG) used here plays dual role in synthesis as it acts as reducing agent and alternatively coats the surface of nanoparticles while synthesis and thereby maintaining uniform size and dispersibility. Powder X-ray diffraction(XRD) and magnetic measurements showed that the sample is cubic spinel and superparamagnetic at room temperature. Raman spectra confirmed the formation of the Mg0.8Mn0.2Fe2O4 nanoparticles.The nanoparticles exhibit very good stability in water due to in situ coating with DEG molecules.     

Effect of welding parameters on Al/Ti joint property in electron beam welding-brazing

The electron beam welding-brazing being used to join 5A06 Al alloy to TC4 Ti alloy decreases the formation of brittle intermetallic compound. Experiments were carried out to study the influence of electron beam welding parameters on the tensile strength of welds, based on an orthogonal test and analysis method. The welding parameters include beam current, welding speed, scanning figure, scanning frequency, figure size, beam offset and focus current. The optimum parameters for 3 mm 5A06 Al alloy and 2 mm TC4 alloy were as follows: acceleration voltage was 60 kV, beam current was 11 mA, welding speed was 600 mm/min, focus current was 0 mA, scan figure was ○, scanning frequency was 1 000 Hz and beam offset was 0.5 mm. The results show that the joints were with good appearance and quality welded by the optimum parameters. The successful joints could be gained and the maximum tensile strength of Al/Ti dissimilar alloy joints could be up to 222.61 MPa using electron beam welding-brazing.     

铜/钛合金电子束焊接工艺优化

研究了QCr0.8/TC4电子束焊接工艺及接头组织,由于铜合金热导率高而熔化量较小,以及焊缝中生成大量脆性金属间化合物相,因此对中焊时接头强度较低.采用偏铜侧进行非对中电子束焊接,接头抗拉强度随偏束量的增大而增高,偏束量为0.8mm时接头最高抗拉强度为270.5MPa.断裂发生在TC4侧熔合线处,为脆性准解理断裂特征.偏铜焊时接头成形得到改善,焊缝包括熔合区及TC4侧反应层两部分.熔合区主要由铜基固溶体组成,硬度较TC4母材有所降低.反应层成分过渡较大,含有多种金属间化合物相.随着工艺参数的变化,反应层厚度也发生变化,从而对接头性能产生影响.     

TC4钛合金表面激光熔覆WC增强镍基复合涂层的组织及耐磨性

为提高TC4钛合金的耐磨性,利用激光熔覆技术(laser cladding,LC)在TC4钛合金表面制备Ni60+50%WC(体积分数)和deloro22(d22)粉末打底+(Ni60+50%WC)2种耐磨复合涂层。采用扫描电子显微镜(SEM)、能谱仪(EDS)以及X射线衍射仪(XRD)来表征涂层的微观结构和物相组成;使用HV-1000显微维氏硬度计、HRS-2M型高速往复摩擦磨损试验机和WDW-100D电子万能试验机来分析涂层的性能。结果表明:2种涂层均由W₂C、TiC、Ni₁₇W₃、Ni₃Ti和Ti_xW_1-x相组成,2种涂层不仅与基体呈现出优异的冶金结合,而且组织均匀致密,没有裂纹瑕疵;由于涂层中存在着原位合成的硬质相和细晶强化共同作用使得涂层硬度显著提高,约为TC4基体的2.82倍;2种涂层的摩擦系数(COF)和磨损量都远低于TC4钛合金基体;Ni60+50%WC复合涂层和d22粉末打底+(Ni60+50%WC)复合涂层的抗剪切结合强度分别为188....     

TC4合金表面TiNi/Ti2Ni改性层不同载荷滑动干摩擦性能研究

利用等离子表面合金化技术在Ti6Al4V合金表面制备了TiNi/Ti2Ni合金层,考察了合金层的表面形貌、成分分布、截面组织形貌、相结构。采用球盘磨损试验机分析了TiNi/Ti2Ni合金层在不同载荷下的滑动干摩擦学性能,并与基体进行对比。结果表明,基体和TiNi/Ti2Ni合金层磨损机制主要表现为磨粒磨损。在同一磨损条件下,TiNi/Ti2Ni合金层的摩擦系数略低于基体,耐磨性优于基体。TiNi/Ti2Ni合金层在不同载荷的摩擦系数接近,在0.29~0.32之间波动。随着载荷的增加,磨损率增加。     

Investigations of microstructures and properties in electron beam welded joints of TiAl to TC4

The normally centered electron beam and non-centered electron beam welding of TiAl to TC4 was investigated in order to analyze the electron beam weldability between TiAl/TC4 dissimilar materials. Macroscopic cold crack easily occurred near TiAl substrate in the joints. The optimal tensile strength was related to the welding heat input. The weld structures were composed of bulky columnar grains and equiaxed grains. The isolated phases consisted of large quantities of α2 -Ti3Al phase, small quantity of B2 phase, γ-TiAl phase and YAl2 phase. Insufficient melting of the base metal occurred in the weld when the beam position leaned to the TC4 side. The tensile strength could be improved when the deflection was limited in the optimum range. Otherwise, non-fusion zone was easily generated in the weld, which led to the low tensile strength.     

氩弧熔敷原位合成TiC-TiB2/Ti基复合涂层组织及性能分析

利用氩弧熔敷技术,在TC4合金表面原位合成了TiC-TiB₂增强镍基复合材料涂层,利用SEM和XRD等方法分析了涂层的显微组织并测试了涂层的显微硬度.结果表明,熔敷组织主要由TiC,TiB₂和Ti(Ni,Cr)组成,TiB₂主要以棒状形式存在;在所形成的TiC-TiB₂/Ti复合材料层中,TiC和TiB₂颗粒分布均匀且尺寸细小;熔敷涂层由表及里组织不同;熔敷层与基体呈冶金结合,无气孔、裂纹等缺陷;涂层的显微硬度达到13.8 GPa,较基体提高了4.5倍.     

Structure of Y3TaNi6+xAl26: a filled-up substitution variant of the BaHg11 type

The crystal structure of Y₃TaNi_6+xAl₂₆ (refined composition Y₄TaNi_6+[7]Al_20+[6]) was determined by single-crystal X-ray diffraction (λ(Mo K) −0.71073 A. μ −17.827 mm¹, F(000) = 700, T = 293 K, wR = 0.015 for [8] unique reflections). This new quaternary aluminide crystallizes with a cubic structure. Pearson code cP49-12.85, (221) Pm-3m-ji'gdba, a = 8.3600(1) Å. V = 584.28(2) Å, Z = 1, M₁ = 1510.25, D_x = 4.292 mg mm¹. The structure of Y_xTaNi_6+xAl₂₆ is filled-up substitution variant of the BaHg₁₁ structure type with one additional atom site, partly occupied (around 15%) by Ni atoms, located at the centre of a cube formed by Al atoms. Distinct atom coordinates were refined for Ni and Al atoms on a site for which mixed occupation (approximately 50% Ni/50% Al) was found. The Ta atoms centre regular Al atom cuboctahedra, and the Y atoms 20-vertex polyhedra, formed by Al and Ni atoms, similar to those observed in CeMn₄Al₈ and YbFe₂Al₁₀.     

铬青铜与双相不锈钢异种材料电子束熔钎焊

对QCr0．8与1Cr21Ni5Ti偏铜电子束焊接接头的组织和力学性能进行了研究。研究结果表明，随电子束距对接中线铜侧偏移值的增加，QCr0．8／1Cr21Ni5Ti对接接头焊缝组织及成分逐渐均匀化，接头熔接状态得到改善；铜侧偏移值达0．8．1．0mm时。形成焊缝组织成分均匀化的熔钎接头，其抗拉强度可达330MPa左右，已可满足实际使用要求。     

LaNd对Ti-13Zr-21Cu-9Ni钎料铺展性及TC4接头性能的影响

为了优化Ti-13Zr-21Cu-9Ni钎料性能、获得一种性能优良的Ti合金接头,向Ti-13Zr-21Cu-9Ni钎料中添加了稀土元素LaNd. 以应用普遍的TC4合金为母材,通过真空炉、场发射扫描电镜、X射线衍射仪等设备研究了稀土元素LaNd对Ti-13Zr-21Cu-9Ni钎料铺展性能及TC4接头性能的影响. 结果表明,随着LaNd添加量的增加,Ti-13Zr-21Cu-9Ni-xLaNd钎料的铺展面积和Ti-13Zr-21Cu-9Ni-xLaNd/TC4钎焊接头的抗剪强度先增大后减小. 当LaNd添加量为0.3%时,Ti-13Zr-21Cu-9Ni-xLaNd钎料铺展面积最大,最大值为0.74 cm2,较基体提高了88.8%;当LaNd添加量继续增加时,生成的Cu₅La相会使钎料的铺展性能大幅降低. Ti-13Zr-21Cu-9Ni-xLaNd/TC4钎焊接头抗剪强度在LaNd添加量为0.3%时达到最大值,为157.1 MPa,较基体提高了45.2%. LaNd的最佳添加量应该为0.3%.     

共沉淀法制备LiNi0.8Co0.1Mn0.1O2过程中加料速度对其性能的影响

采用共沉淀法制备Ni0.8Co0.1Mn0.1(OH)2前驱体,与LiOH.H2O混合后在氧气气氛中焙烧得到LiNi0.8Co0.1Mn0.1O2正极材料,探讨共沉淀反应过程中快速加料和慢速加料制度对前驱体形貌和LiNi0.8Co0.1Mn0.1O2正极材料性能的影响。通过X射线衍射(XRD)、扫描电镜(SEM)和电化学测试对样品进行表征。结果表明:慢速加料法减小了材料的粒径,合成了平均粒径在0.5μm左右的球形Ni0.8Co0.1Mn0.1(OH)2前驱体,且粒径分布比较集中;所合成LiNi0.8Co0.1-Mn0.1O2正极材料具有良好的层状结构,且无杂相存在;缓慢加料法得到的样品的电化学性能有很大提高,在0.1 C、0.5 C和1 C下首次放电比容量分别达到223.5、194.3和190.7 mA.h/g,循环30次后,容量保持率为80.09%、80.80%和85.84%。