Ti17合金惯性摩擦焊接头力学性能与组织分析

通过室温拉伸、高温拉伸试验以及金相分析对 Ti17 合金惯性摩擦焊接接头的显微组织和力学性能进行了研究.结果表明,采用惯性摩擦焊焊接 Ti17 合金可获得室温及高温性能良好的焊接接头,其焊接接头的室温及高温抗拉强度都不低于母材;Ti17合金母材组织为α+β相,并且β相呈针状均匀分布在α相的基体上;不同焊接工艺参数对 Ti17 合金惯性摩擦焊接头热影响区和焊缝的组织没有影响,其热影响区组织为α+β相,并且β相呈针状均匀分布在α相的基体上,与母材组织相同,焊缝组织为细小的等轴晶.

Abstract：

The microstructures and properties of Ti17 alloy joints welded by inertia friction welding (IFW) were investigated by room-temperature tensile test, high-temperature tensile test and metallographic analyses. The results show that the joint with good performance at room and high temperature for Ti17 alloy can be obtained in IFW. Both the tensile strengths of welded joints at room temperature and at high temperamre are not less than those of the base metal. The microstructure of Ti17 alloy is α+β phase, and the needle β phase is distributing on the α phase. While welding, different welding parameters can not affect the microstructures of the HAZ and the weld seam. The microstructure of HAZ is the same as that of the base metal, and that of the welded seam is fine equiaxed crystal.     

镁合金MIG焊接工艺及焊接接头组织性能分析

采用脉冲 MIG 焊接工艺,进行 AZ31B 镁合金板材的焊接性分析,焊后利用光学显微镜、扫描电子显微镜、万能拉伸试验机和显微硬度仪等设备对焊接接头的组织与力学性能进行了检测分析.结果表明,通过优化工艺参数,采用脉冲 MIG 焊接工艺可以在不开坡口、不需背面强制成形的条件下,实现镁合金单面焊接双面成形,获得连续、没有表面缺陷的焊接接头.焊接接头的热影响区较窄,晶粒稍有长大.焊缝区组织均匀,晶粒细小,硬度值高于母材.焊接接头的抗拉强度可达到母材的 95% 以上.

Abstract：

The pulsed MIG welding was used to weld AZ31B Mg alloy, and the weldability of the alloy was studied. The microstructure, mechanical property and hardness of the welded joint were investigated via the metal phase microscopy, scanning electron microscope, tensile testing machine and hardness instrument. The results show that one-side welding with back can be obtained through this technique at optimized parameters when there was no groove and no shaped ban, which continuous butt joints have no surface defects.The heat-affected zone of the joints is narrow, and the grains of the zone are slightly larger than that of the base metal. The grains of fusion zone are tiny, the microstructure is homogeneous and the hardness of welded joint is higher than that of the base metal. The tensile strength is up to 95% of the base metal.     

Comparison of 2A12 aluminium alloy joint by ultrasonic assisted friction stir welding and friction stir welding

Ultrasonic assisted friction stir welding （UAFSW） is a recent modification of conventional friction stir welding, which adds ultrasonic energy directly into the friction stir welding area by the pin. In this study, 2A12 aluminum alloy was welded by this process and conventional, respectively. The tensile tests, microstructure and fracture surface of FSW joint and UAFSW joint were analyzed. The research results show that the surface forming texture of ultrasonic assisted friction stir welding joint, compared with conventional, is finer and more uniform, showing metallic matte color. The grains are much finer in weld nugget zone, thermo-mechanically affected zone and heat-affected zone; S-phase particles size is much smaller and distribution is more homogeneous in the matrix. The tensile strength of UAFSW joint is 94. 13% of base metal, and the elongation is 11.77%. The tensile strength of FSW joint is 83.15% of base metal, and the elongation is 8.81%. The tests results reveal that ultrasonic vibration can improve the tensile strength and the elongation of welded joints.     

Microstructure and Its Influence on the Mechanical Properties of Ni–28W–6Cr-Based Alloy-Welded Joints by GTAW

Microstructure and mechanical properties of Ni–28W–6Cr alloy-welded joints produced by gas tungsten arc welding were investigated in this work.Results showed that original fine-grain base metal near fusion line totally transformed into coarse heat affected zone after welding.Carbides with different shapes were found in the weld metal and base metal, which all were determined as M6C carbides.In comparison with carbides in base metal, M6C carbides in weld metal are rich in Si and Cr but deficient in W.Moreover, M6C carbides are extremely scarce and hard to be detected in weld metal.Mechanical tests show that the hardness value of weld metal is only about 60% of base metal; the yield strength and tensile strength of welded joint are much lower than those of base metal due to the absence of carbides in weld metal.     

大厚度TC21钛合金电子束焊接试验

对56mm厚TC21钛合金进行了电子束对接试验,对接头显微组织和力学性能进行了研究.结果表明,接头焊缝区组织形态以柱状β晶粒为基体,针状的马氏体弥散其中;热影响区从焊缝到母材分为三个区域,依次为等轴再结晶β晶粒区、片状和针状а相形成的魏氏组织区以及片状α相聚集长大的区域;熔合区内柱状晶与等轴晶联生.接头强度达到母材水平,断裂发生在母材内,接头厚度方向性能一致.接头塑性损失较大,只达到母材的50%左右.接头焊缝区硬度最高,其次是热影响区的等轴晶区和魏氏组织区,而热影响区内片状α相聚集长大的区域硬度值最低.

Abstract：

Electron beam welding of TC21 56 mm titanium alloy was carried out. The microstructure and the mechanical properties of welded joints were analyzed and tested. The results showed that the weld zone consisted of the columnar β gains, and in which the transgranular acicular α' martensite were dispersedly distributed. HAZ can be divided into three parts from base metal to weld zone, which are the equiaxed recrystallized β grain zone, Widmanstaten structure zone formed by lamellar and aeicular α phases and lamellar a phase coarsening zone. Fusion zone consists of the adnate columnar and equiaxed grains. Tensile strength of joints reaches to that of base metal and the failure appears in the base metal. The mechanical properties are uniform along the vertical direction. Plasticity in the welded joint is greatly decreased and only up to 50% of that of the base metal. The microhardness in weld zone is the highest, and that of the equiaxed grain zone and Widmanstaten structure zone in HAZ is higher, and the microhardness in columnar a phase coarsening zone is the lowest.     

工业纯钛光纤激光-MIG复合焊接工艺及性能

采用光纤激光与熔化极惰性气体保护电弧焊(MIG焊)复合焊接工业纯钛,分别对激光焊、MIG焊和复合焊接头的焊缝表面成形、横断面进行了观察,并进行了激光焊和复合焊接头的拉伸试验及杯突试验.结果表明,复合焊的电弧稳定性比MIG焊显著提高,焊接速度可提高7倍;复合焊与激光焊接头的抗拉强度高于母材;复合焊接头的杯突值优于激光焊接头的杯突值,这是因为复合焊焊缝的微观组织有利于接头的塑性.因此,采用光纤激光-MIG电弧复合焊接方法很好地实现了工业纯钛的高速焊接,焊缝成形良好,接头的塑性优于单一激光焊的塑性.

Abstract：

Fiber laser-metal inert gas (MIG) arc hybrid welding was used to weld the commercial pure titanium (CP-Ti). The weld appearance, cross section, tensile strength, Erichsen value and microstructure of the CP-Ti welded joints were studied. The results show that the arc stability is substantially improved and the welding speed can be increased to 7 times by fiber laser-MIG hybrid welding. The welded joints by laser welding and the hybrid welding exhibit the higher ultimate tensile strength than those of the base metal. In addition, the welded joint by the fiber laser-MIG hybrid welding has higher Erichsen values than that by laser joints. The difference in plasticity is attributed to the microstructure changes in the welded joint of hybrid welding. Thus, the fiber laser-MIG hybrid welding of CP-Ti can be carried out suecessfully at higher welding speed with a good combination of weld bead appearance and plasticity.     

Tensile properties and failure analysis of Ti–6Al–4V joints by electron beam welding

The microstructural and mechanical characterization of electron beam welded joints of forged Ti–6Al–4V were investigated. Microhardness tests indicate that the hardness of the fusion zone(FZ) is higher than that of the heat-affected zone(HAZ) and base metal. The tensile results show that the mechanical properties of the welded joints are comparable with those of the base metal in terms of static strength and are in accordance with the relationship between microstructure and mechanical properties of welded joints. The ultimate tensile strength of the weld is equal to that of the hourglass joint, which indicates that the mechanical properties of the longitudinal FZ and those of the transverse FZ are the same. Macromechanical behavior and macrofracture and microfracture of the base material,joint, and weld specimens are observed. A comparison among the three types of specimen fracture phenomena reveals the following distinctive differences:(1) the fracture mode,(2) the micrograph of the dimple pattern at the central region, and(3) the size of the dimple at the central region and the transition region.     

Microstructural zones and tensile characteristics of friction stir welded joint of TC4 titanium alloy

TC4 titanium alloy was friction stir welded using a W-Re pin tool,and the defect-free weld was produced with proper welding parameters.The joint consists of stir zone,heat affected zone and base material.The stir zone is characterized by equiaxed dynamically recrystallized α phases and transformed β phases with fine α+β lamellar microstructure.The microstructure of the heat-affected zone is similar to that of the base material,but there is an increase in the volume fraction of β.Transverse tensile strength of the joint is 92% that of the base material,and the joint is fractured in the stir zone and the fracture surface possesses typical plastic fracture characteristics.The stir zone is the weakest part of the joint,through which the tensile characteristics of the TC4 joint can be explained.     

紫铜与低碳钢厚板搅拌摩擦焊工艺分析

用搅拌摩擦焊方法成功焊接了 10 mm 厚的紫铜与低碳钢板,得到了内部无缺陷、外观成形良好的接头.紫铜位于搅拌摩擦焊返回边时,能使焊缝形成良好接头.反之,位于前进边时则有沟槽和未焊合等缺陷.右旋螺纹搅拌针会使焊缝材料向上作螺旋形运动,接头有明显的轴肩影响区,缺陷容易在焊缝底部出现.左旋螺纹搅拌针使搅拌针周围的塑化金属向下迁移,在焊缝下部形成明显的呈"洋葱环"形焊核区,缺陷容易在焊缝上部出现.搅拌针偏移量对焊缝形貌有较大影响.接头抗拉强度达 233 MPa,为铜母材强度的 95%,断裂位置在铜侧热影响区.焊核区抗拉强度达 296 MPa,远超过紫铜母材的强度.

Abstract：

The joining of dissimilar metals, T2 copper and Q235 mild steel plates with 10 mm thickness, is carried out in friction stir welding. Excellent welds can be gained when copper is fixed at the retreating side, but defects can be produced in welds when copper is fixed at the advancing side. The pin shapes influence the flow of the plasticized metal in the weld, which results in the variety of the morphology of the weld. If the screw thread on the pin is clockwise, the metal around the pin will move upwards to the root of the pin, which causes that the shoulder affected zone is clear and the weld defects would form at the lower part of the weld section. If the screw thread on the pin is counter-clockwise, the metal around the pin will move downwards, which drives the metal around the pin tip to move around and upwards. The onion ring pattern, which appears like lamellar structure, is observed in the stir zone. The shoulder-affected zone is not clear; the weld defects will form at the upper part of the weld section. Various pin offsets will affect the flow of weld metal. If an optimization of the process parameters is performed, defeet-free joints can be formed. The tensile test results show that the maximum joint tensile strength can reach 233 MPa, which is 95% of the parent materials of copper, and the fracture happens in the HAZ of copper. The maximum tensile strength of the nugget zone can reach 296 MPa, which is very considerably larger than that of the parent materials of copper.     

Microstructures and properties of welded joint of TiNi shape memory alloy and stainless steel

The fracture characteristics of the joint were analyzed by means of scanning electron microscope(SEM).Microstructures of the joint were examined by means of optical microscope, SEM and an image analyzer. The results show that the tensile strength of the inhomogeneous joint of TiNi shape memory alloy and stainless steel is lower than that of the homogeneous joint and a plastic field appears in the heat affected zone on the side of TiNi shape memory alloy. Because TiNi shape memory alloy and stainless steel melted, a brittle as-cast structure was formed in the weld. The tensile strength and the shape memory effect of the inhomogeneous joint are strongly influenced by the changes of composition and structure of the joint. Measures should be taken to reduce the base metal melting and prevent the weld metal from the invasion by O for improving the properties of the TiNi shape memory alloy and stainless steel inhomogeneous joint.     

1Cr18Ni9Ti不锈钢超窄间隙焊接接头组织与性能分析

采用超细颗粒焊剂约束电弧超窄间隙焊接方法进行了1Cr18Ni9Ti奥氏体不锈钢的超窄间隙焊接试验,并对所得超窄间隙焊接接头的组织及性能进行了测试和分析。结果表明,1Cr18Ni9Ti奥氏体不锈钢超窄间隙焊接接头的根焊焊缝区晶粒为等轴晶,而填充焊和盖面焊的焊缝区晶粒则为粗大的柱状晶。等轴晶和柱状晶的基体均为奥氏体,晶粒内部均分布有少量板条状铁素体。超窄间隙焊接接头的填充焊缝和根焊焊缝具有与母材相当的硬度,而盖面焊缝的硬度则略低于母材。超窄间隙焊接接头除了收缩率和冲击功比母材的略低外,抗拉强度、屈服强度及伸长率明显高于母材所对应性能的最低值。此外,试验还测得超窄间隙焊接接头的腐蚀速率为0.417 g/(m2·h),该值明显低于母材的腐蚀速率。     

高强钢CO2激光-MAG复合焊接性能

为了研究CO₂激光-熔化极活性气体保护焊（MAG）复合焊接性能,采用CO₂激光和CO₂激光-MAG复合焊接590MPa级高强度钢,对其焊接接头的显微组织和力学性能进行了研究.结果表明,激光-MAG复合焊接的焊缝金属中,MAG电弧作用区主要为珠光体和贝氏体,激光作用区主要为马氏体;激光-MAG复合焊接的焊缝金属中Mo和Mn合金元素的分布具有不均匀性;激光和激光-MAG复合焊接的试件焊接接头拉伸性能完全满足要求,焊缝强度高于基体强度;激光-电弧复合焊缝金属在-60℃～+15℃试验温度范围内的冲击韧性比激光焊缝金属高;激光-MAG复合焊接焊缝金属硬度在250～400 HV之间,高于基体金属的硬度.     

钛及钛合金焊接接头的组织、性能和断裂特性

研究了钛及钛合金经钨极氩弧焊焊接接头的显微组织、力学性能和冲击断裂特征。焊缝区的显微组织为片状或针状α组织,接头强度可达到基材水平,并有较高的塑性和韧性,冲击断裂特征主要是塑性断裂。     

焊接电流对Ti2AlNb/TC18焊接界面性能及元素扩散的影响

采用真空电子束焊接对Ti2AlNb和TC18合金进行连接,研究了不同焊接电流时焊接界面的性能及元素扩散情况。结果表明:焊接接头在室温和高温下均获得了较高的抗拉强度。采用同一电流焊接时,TC18侧热影响区的显微硬度值高于该合金基体却低于该侧焊缝区,而Ti2AlNb合金侧热影响区的显微硬度值均高于该侧焊缝区和Ti2AlNb合金基体;在28 mA的焊接电流下,焊接界面的整体显微硬度值均较高,这是因为焊接界面形成了含量较多且尺寸较小的α′马氏体和O相,对界面起到了强化作用。在不同的焊接电流下,合金元素均在焊缝和两侧母材交界处存在较大的浓度梯度,其原因是焊缝金属的快速凝固使得各合金元素没有足够的时间和能量进行充分扩散。     

钛合金激光焊接接头的组织和力学性能

对2.5mm厚BT20钛合金激光焊接接头各区域(包括焊缝和热影响区)的组织特征进行了观察,并测试了焊接接头各区域的显微硬度分布以及室温条件下的接头拉伸、弯曲、疲劳及断裂韧度等力学性能.研究结果表明,焊接接头各区域的微观组织均以"网篮状"马氏体组织为特征,接头各区域显微硬度均高于母材.接头静抗拉强度基本与母材相当,塑性略低于母材.接头中值疲劳寿命与应力水平有很大的关系.在低应力水平下,接头中值疲劳寿命与母材相当,而在高应力水平下,接头中值疲劳寿命远低于母材.接头焊缝金属的断裂韧度显著低于母材,而热影响区断裂韧度则介于母材和焊缝金属之间.     

厚板Ti6Al4V合金低真空激光焊接接头组织及力学性能

采用低真空激光焊接技术对40 mm厚Ti6Al4V合金进行焊接,对比分析不同位置的微区组织与力学性能. 结果表明,母材由等轴初生α相和β转变组织组成,热影响区组织为α相、残余β相和急冷准稳态的α'马氏体,焊缝熔凝区组织主要包括不同尺寸及分布状态的α'马氏体以及慢冷却速率下形成的α相. 焊接接头抗拉强度平均值为988 MPa,断裂位置均位于母材. 焊缝上部和中部焊缝区的平均冲击吸收能量为28.8 J,明显优于下部24.8 J. 焊缝熔凝区底部区域存在细长状、密集程度较高的α'马氏体会劣化材料冲击韧性. 相比之下熔凝区中、上部形成的短粗状、密集程度较低的α'马氏体组织的冲击韧性较高, 为Ti6Al4V合金板材的连接及进一步提高接头的力学性能提供了数据支撑及相关理论依据.     

基于Ti中间层的SiCp/6061-T6Al MMCs低功率激光-TIG复合焊组织与性能

以0.1mm厚的Ti箔做中间夹层,使用低功率激光-TIG复合焊的方式对SiCp/6061-T6Al MMCs 进行焊接,并对接头的宏观形貌、显微组织、物相、电阻率、抗拉强度及断口形貌进行分析。结果表明：激光功率对焊缝的成形有着较大影响;Ti箔的加入基本抑制了焊缝中针状Al₄C₃生成,并生成TiC增强相以及条状TiAl₃;焊缝区为等轴晶组织,熔合区为柱状晶组织,热影响区组织变化不明显;随着激光功率的增加接头的电阻率呈现出增加的趋势,并明显高于母材;在554W时接头的抗拉强度可达196.98MPa,是母材强度的54.71%。接头断口中几乎没有气孔,韧窝中的第二相粒子以TiC为主,接头呈现出以脆性断裂为主的脆-韧性混合断裂特征。     

Incoloy 825镍基高温合金电子束焊工艺及接头组织与力学性能分析

采用电子束焊,对空冷器管箱Incoloy 825镍基高温合金进行对接焊试验. 通过对焊接接头的组织观察,并结合拉伸力学性能以及接头的冲击韧性等试验,分析镍基高温合金电子束焊接头的组织和力学性能. 结果表明, 采用电子束焊焊接镍基高温合金可以得到良好的焊接接头,焊缝区组织由大片等轴晶和少量柱状晶组成;焊缝区没有出现明显的元素烧损现象;焊缝、热影响区硬度达到母材硬度值;焊缝接头抗拉强度达到600 MPa,接近母材抗拉强度,接头断裂形式为韧性断裂;焊缝和热影响区的冲击吸收能量高于母材区,其中焊缝区的冲击吸收能量达到了262 J,冲击断口形貌为韧窝状.     

铸造Ti-Al-Mo-Zr钛合金电子束焊接接头组织与性能

选用电子束焊接方式对14 mm厚铸态Ti-Al-Mo-Zr钛合金进行焊接,在合适的工艺参数下获得成形良好、无内部缺陷的焊接接头。室温下测试与分析焊接接头的显微组织、显微硬度和力学性能,结果显示焊缝处主要由β相基体和粗大的针状α相组成,热影响区处受焊接热循环作用部分转变为网状片层组织。焊缝处硬度略高于母材处,接头整体硬度分布均匀,无明显弱化区域;接头焊缝处抗拉强度优于母材,焊缝处冲击值AKV达到75 J/cm~2,热影响区冲击值为73 J/cm~2,Ti-Al-Mo-Zr钛合金电子束焊接接头冲击韧性良好。