镁-钢异种金属MIG焊接头的显微组织与力学性能-有色金属在线

简介概要

镁-钢异种金属MIG焊接头的显微组织与力学性能

来源期刊：中国有色金属学报(英文版)2015年第8期

论文作者：汪晓勇孙大千殷世强刘东阳

文章页码：2533 - 2542

关键词：AZ31B镁合金；Q235钢；熔化极惰性气体保护电弧焊；异种金属连接

Key words：AZ31B Mg alloy; Q235 steel; metal inert-gas arc welding; dissimilar metal joining

摘要：采用熔化极惰性气体保护电弧焊方法(MIG)实现镁合金和低碳钢的连接，并研究焊接热循环特点和镁-钢对接接头的显微组织及力学性能。研究结果表明，在焊接过程中，接头的温度场分布是不均匀的。镁合金焊缝金属为细小的等轴晶结构。在镁/钢界面存在主要由AlFe、AlFe₃和Mg(Fe,Al)₂O₄相组成的过渡层，这一过渡层是镁-钢接头的最薄弱环节。焊接线能量和焊缝Al含量对镁-钢接头的抗拉强度具有明显的影响。焊接线能量由1680 J/cm增至2093 J/cm，接头强度明显增加，这主要归因于镁/钢界面反应。增加焊缝Al含量至6.20%，镁-钢接头强度可达192 MPa，为AZ31镁合金母材强度的80%。因此，选择合适的焊接线能量和焊缝Al含量有利于改善镁-钢接头的抗拉强度。

Abstract: The joining of Mg alloy to steel was realized by metal inert-gas arc welding, and the weld thermal cycle characteristics and Mg-steel joints were investigated. The results show that the temperature distribution in the joints is uneven. Mg alloy welds present a fine equiaxed grain structure. There exists a transition layer consisting mainly of AlFe, AlFe₃ and Mg(Fe, Al)₂O₄ phases at Mg/steel interface, and it is the weakest link in Mg-steel joints. The welding heat input and weld Al content have the significant effect on the joint strength. The joint strength increases with increasing the heat input from 1680 J/cm to 2093 J/cm, due to promoting Mg/steel interface reaction. When weld Al content is increased to 6.20%, the joint strength reaches 192 MPa, 80% of Mg alloy base metal strength. It is favorable to select the suitable welding heat input and weld Al content for improving joint strength.

Trans. Nonferrous Met. Soc. China 25(2015) 2533-2542

Microstructures and mechanical properties of metal inert-gas arc welded Mg-steel dissimilar joints

Xiao-yong WANG, Da-qian SUN, Shi-qiang YIN, Dong-yang LIU

Key Laboratory of Automobile Materials of Ministry of Education, School of Materials Science and Engineering, Jilin University, Changchun 130025, China

Received 20 October 2014; accepted 25 January 2015

Key words: AZ31B Mg alloy; Q235 steel; metal inert-gas arc welding; dissimilar metal joining

1 Introduction

Magnesium and its alloys have been suggested in transport applications to reduce the fuel consumption and environmental pollution, due to their unique characteristics such as low density, high specific strength along with good damping capacity [1-5]. It is well known that steels are the most common metal materials in transport industry [6]. Hybrid structures of Mg alloy to steel have a widely applied prospect in the field of automotive and railway vehicle industries [7]. Therefore, it has received remarkable attention to joining Mg alloy and steel dissimilar metals.

Some difficulties are encountered in dissimilar welding of Mg alloy and steel. The difficulties mainly result from the great difference between their melting points (649 °C for Mg and 1535 °C for Fe) and the nearly zero solubility of Mg and Fe [8]. In addition, Mg and Fe do not react with each other to form binary compounds at ambient pressure [9]. There are some research activities on joining Mg alloy to steel in recent years. The current methods are generally limited to the solid-state welding processes, such as the diffusion welding [10,11], the friction stir welding [8,12] and the resistance spot welding [13,14]. However, their application is limited by the geometry and size of workpiece, and the mechanical properties of welded joints achieved by these processes are also not satisfactory. The hybrid laser-TIG welding [15-18] and laser penetration brazing (LPB) [19,20] were also used for joining Mg alloy to steel. The results showed that the Ni interlayer favors improving the microstructure and tensile shear strength of Mg-steel joints produced by the hybrid laser-TIG welding. For the LPB, the transition layer at Mg/steel interface region consisted mainly of intermetallic compounds and metal oxides, and the joint strength reached a maximum of 185 MPa at 0.6 mm laser offset.

Metal inert-gas arc welding (MIG welding) is widely applied in automobile and railway vehicle industries for its high efficiency, low cost and good applicability for the geometry and size of workpiece [21,22]. Therefore, it is of important significance to realize the MIG welding of Mg alloy to steel for mass serial production. However, up to now, the report dealing with the MIG welding of Mg alloy and steel is very limited. The present work investigates microstructures and mechanical properties of MIG welded Mg-steel joints produced with different welding heat inputs and filler metals. The purpose is to better understand the weldability of Mg alloy and steel, and to provide some foundation for improving mechanical properties of the Mg-steel joints.

2 Experimental

In this investigation, AZ31B Mg alloy and Q235 low carbon steel plates with dimensions of 200 mm×50 mm×3mm were employed as base metals, and Mg alloy welding wires (AZ31 and AZ61) with a diameter of 1.6 mm were chosen as filler metals. Chemical compositions and mechanical properties of them are listed in Table 1, Table 2 and Table 3, respectively. The Mg alloy base metal has an equiaxed grain structure consisting of α(Mg) solid solution, and the grain size is about 20 μm. The phase composition of the low carbon steel is mainly α(Fe) phase.

Table 1 Chemical compositions of Mg alloy and low carbon steel base metals (mass fraction, %)

Table 2 Chemical compositions of Mg alloy filler metals (mass fraction, %)

Table 3 Mechanical properties of Mg alloy and low carbon steel base metals

Prior to welding, the single groove was machined in the Mg alloy and low carbon steel plates, the bevel angles of Mg and steel plates were 30° and 45° respectively, and then both plates were assembled into a single V-groove with a root opening of 1 mm. The welding of Mg alloy and steel was made using the metal inert-gas arc welding (MIG welding) with Ar shielding gas. During MIG welding, the Mg alloy filler metal wire was directed toward the middle of the steel groove face by welding torch, and was deposited in the V-groove at different welding heat inputs, as shown in Fig. 1. The torch has a drag angle along the welding direction for improving the liquid Mg spreading on solid steel surface and the Mg weld appearance. The welding heat input (E) represents the amount of heat input per unit length of weld, and is determined according

E = ηIU/v (1)

where I is the welding current, U is the arc voltage, v is the welding speed, and η is the heat source efficiency, a constant of 0.7 for the MIG welding process.

The weld thermal cycles in Mg alloy weld and Mg/steel interface were measured using embedded thermocouples. Four holes with 1 mm in diameter were machined in test plates for the placement of thermocouples (TC1, TC2, TC3 and TC4), and high temperature epoxy was used to fix the thermocouples. The layout of the locations of the thermocouples is shown in Fig. 2. During MIG welding, a digital data logger with a total capacity of eight K-type thermocouples was used to record the weld thermal cycles, the thermocouples TC1, TC2, and TC3 for the top, middle and bottom of Mg/steel interfaces, respectively, and TC4 for weld adjacent to the Mg alloy base metal.

Fig.1 Schematic diagram of MIG welding

Fig. 2 Layout of locations of thermocouples

After the welding, Mg-steel joint specimens were cut down from the welded plates. The joint specimens were ground, polished and then etched in the picric acid etchant solution. The nital was also used for steel HAZ. The microstructure and composition of Mg-steel joints were examined by using optical microscope (OM, PMG3), scanning electron microscope (SEM, EVO18) equipped with energy dispersive X-ray spectroscope (EDS, Link-ISIS), transmission electron microscope (TEM, JEM-2100F) and X-ray diffraction (XRD, D/Max 2500PC). The Vickers microhardness of the joints was measured with a load of 50 g and a duration time of 10 s. The tensile test of Mg-steel joints was carried out using the MT810 universal material testing system at room temperature.

3 Results and discussion

3.1 Weld thermal cycle characteristics

The weld thermal cycle represents the temperature distribution and gradient in welded joints during welding. It would be extremely useful to reveal weld thermal cycle characteristics for understanding the changes of microstructures and properties of the joints. Since the temperature distribution at Mg/steel interface is of particular interest for joining Mg to steel, weld thermal cycles at the interface and weld were measured using embedded thermocouples (Fig. 2). Thermocouples TC1, TC2 and TC3 were used to measure the weld thermal cycles at the top, middle and bottom of Mg/steel interfaces, respectively, while TC4 stood for that of weld.

Fig. 3 Weld thermal cycle curves

Figure 3 shows the weld thermal cycle curves recorded by thermocouples during MIG welding at the welding current of 135 A, arc voltage of 24 V and welding speed of 65 cm/min. The peak temperatures, heating and cooling rates of the weld thermal cycles are given in Table 4. From Fig. 3(a), it can be seen that the weld has very quick heating and cooling rates (89.2 °C/s and 16.0 °C/s), at the peak temperature of 725.4 °C, which will increase the nucleation rate and form the fine grain weld metal. During the weld cooling, the cooling rate becomes relatively slow in the temperature range of 625-585 °C, indicating the phase transformation occurring from liquid Mg to solid α(Mg) in this temperature range.

Figure 3(b) shows the weld thermal cycle curves for the top (TC1), middle (TC2) and bottom (TC3) of Mg/steel interface. The heating and cooling rates of the interface are also very quick, and there is a significant difference in peak temperatures. The middle of the Mg/steel interface has the highest peak temperature (1097.7 °C), and the lowest peak temperature (747.8 °C) appears in the interface bottom. It can be explained by the power density distribution of MIG arc heat source. In this investigation, the magnesium alloy filler metal electrode was directed toward the middle of steel groove face, and the arc was established between the anode spot at tip of the filler metal and the cathode spot in the middle of the steel groove face. Since the power density distribution of the heat source was considered Gaussian [23], hence the middle of Mg/steel interface has the highest power density and peak temperature. These characteristics of weld thermal cycles should affect microstructures and mechanical properties of MIG welded Mg-steel joints.

Table 4 Peak temperature, heating rate and cooling rate of weld thermal cycle

3.2 Mg-steel joint microstructures

MIG welding of AZ31B Mg alloy and Q235 low carbon steel was carried out at different welding parameters with AZ31 and AZ61 Mg alloy filler metals. The MIG welding parameters and heat inputs are listed in Table 5.

Table 5 MIG welding parameters and heat inputs used in this investigation

The appearance of weld is one of important factors to evaluate welding quality. The experimental results indicate that welding heat input has a significant effect on the weld appearance, as shown in Fig. 4. At low welding heat input, the Mg alloy weld has small reinforcement due to less deposited metal (Fig. 4(a)), and the weld appearance is improved with an increase of the heat input (Fig. 4(b)), but excess heat input (2254 J/cm) increases the welding spatter and deteriorates the weld appearance, as shown in Fig. 4(c). It is necessary to select suitable welding heat input for improving the weld appearance quality. Based on above experimental results, the satisfactory weld appearance can be obtained in the welding heat inputs of 1744-2171 J/cm.

Fig. 4 Weld appearance with AZ31 filler metal at different heat inputs

Figure 5 illustrates typical microstructures of MIG welded Mg-steel joint. The joint includes weld zone, heat-affected zone in Mg alloy side (HAZ₁) and heat-affected zone in steel side (HAZ₂), as shown in Fig. 5(a). The chemical composition of welds depends on that of filler metals. With the AZ31 filler metal, Al content in the weld is 3.17%, and it increases to 6.20% when the AZ61 filler metal was used. From Figs. 5(b) and (c), it can be seen that both welds present the finer equiaxed grain structure (grain size of 10-13 mm), compared with Mg alloy base metal, due to very quick cooling rate for the welds. According to XRD analysis results (Fig. 6), the phase composition of the weld with 3.17% Al is mainly α(Mg) solid solution, similar to the Mg alloy base metal, while the α(Mg) and β-Mg₁₇Al₁₂ intermetallic compound were detected in the weld containing 6.20% Al, and the β-Mg₁₇Al₁₂ phases mainly distribute at α(Mg) grain boundaries (Fig. 5(d)). It is mainly associated with the increased weld Al content. From Fig. 5(e), it can also be seen that the Mg-steel joint has a typical fusion welding characteristic in the Mg alloy side, and the grain coarsens obviously in HAZ₁ due to welding heat effect. There exists a transition layer between Mg alloy weld and steel base metal, and HAZ₂ in steel side consists mainly of pearlite and ferrite, as shown in Fig. 5(f). During MIG welding, the Mg alloy was molten, whereas the steel retained solid. The joining of Mg and steel was achieved by means of the wetting and spreading of liquid Mg on solid steel surface and Mg/steel interface reaction to form the transition layer. Therefore, it has the characteristic of brazed joint in steel side.

Fig. 5 Microstructures of Mg-steel joint

In this investigation, the thickness of transition layers at Mg/steel interfaces depends on weld Al contents (Fig. 7). When weld Al content is 3.17%, the transition layer thickness is about 1.0 μm (Fig. 7(a)), and it increases to 2.5 μm (Fig. 7(b)) for the weld containing 6.20% Al. EDS analysis results indicate that the chemical composition of transition layers mainly includes Mg, Al and Fe elements. From Mg alloy weld to steel base metal across the transition layers, the concentration of Mg element decreases, that of Fe element increases, and the concentration of Al element has an increased tendency in the transition layers, as shown in Fig. 8. XRD was used to determine phase compositions of the transition layer. Since the fracture of Mg-steel joints occurred in the transition layer, XRD analysis was done on the joint fracture surface in steel side. The AlFe and AlFe₃intermetallic compounds, and Mg(Fe,Al)₂O₄ metal oxide were detected in the transition layer (Fig. 9).

Fig. 6 XRD patterns of welds

Fig. 7 Transition layers at Mg/steel interfaces

Fig. 8 Element distribution across transition layers

Based on above results, the inter-diffusion of Mg, Al and Fe elements occurred during MIG welding, and joining of Mg alloy and steel was realized by Mg/steel interface reaction. Since Mg and Fe do not react with each other to form binary compounds, Al plays an important role in the interface reaction. An increase of the transition layer thickness with increasing the weld Al content is mainly related to promoting Mg/steel interface reaction to form more Al-Fe compounds.

It should be pointed out that the temperature of Mg/steel interface also has an important effect on interface joining quality. Higher interface temperature favors the wetting and spreading of liquid Mg on solid steel surface, and promotes the element diffusion and interface reaction. The relative low interface temperature (747.8 °C) at the bottom of Mg/steel interface could result in discontinuous interface reaction layer ( Fig. 10), affecting the interface joining quality.

Fig. 9 XRD pattern of transition layer

Fig. 10 Microstructures at bottom of Mg/steel interface

3.3 Mg-steel joint properties

The Vickers microhardness profiles across Mg-steel joints are illustrated in Fig. 11. From Fig. 11(a), it can be seen that the microhardness distribution is uneven. Mg alloy HAZ₁ has the lowest microhardness, which is mainly associated with the grain coarsening in this zone. Compared with HAZ₁, Mg alloy weld shows higher hardness values because it has a fine equiaxed grain structure. The highest hardness appears at the Mg/steel interface because it contains AlFe and AlFe₃ intermetallic compounds. The welding heat input has an effect on the joint microhardness (Fig. 11(b)). With an increase of the heat inputs, the microhardness decreases in HAZ₁ and increases at Mg/steel interface. It can be explained by forming coarser grain in HAZ₁and more Al-Fe intermetallic compounds at Mg/steel interfaces.

The experimental results indicated that the welding heat input has a significant effect on the tensile strength of Mg-steel joints (Fig. 12). At low welding heat input the joint strength is very poor, it is improved obviously in the heat inputs of 1919-2254 J/cm, and the maximum joint strength (184.2 MPa) is achieved at the welding heat input of 2093 J/cm. The joint fracture mainly occurs at the Mg/steel interface layer (Fig. 13), indicating that it is the weakest link in the Mg-steel joints.

Fig. 11 Microhardness distributions of joints with AZ31 filler metal at different heat inputs

Fig. 12 Tensile strength of Mg-steel joints with AZ31 filler metal at different heat inputs

Fig.13 Fracture sites of Mg-steel joints with AZ31 filler metal

Fig. 14 Fracture surface morphologies of Mg-steel joint with AZ31 filler metal in steel side

In order to further clarify reasons for joint strength changes, the fracture surface morphology of Mg-steel joints was investigated. Figure 14 shows typical fracture surface morphologies in steel side. The fracture surface can be divided into two regions, Region A and Region B,as shown in Fig. 14(a). In Region A, a large amount of retained Mg alloys are observed on the steel surface and there are some features of plastic deformation on the fracture surface (Fig. 14(b)), indicating that the sound joining is realized in this region. Hence, it is called the joined region in this investigation. The Region B is mainly located at the bottom of Mg/steel interface. Its fracture surface is relative smooth with less retained Mg alloy (Fig. 14(c)), which means that Mg alloy and steel are joined partially in this region. According to the weld thermal cycle curves at the Mg/steel interface, the bottom of the interface has the lowest peak temperature, which affects the element diffusion, interface reaction and joining quality. Figure 15 shows the ratio of areas between joined region and Mg/steel interface at different welding heat inputs. The higher the welding heat input, the larger the joined region area is, which is similar to the change of joint strength. Therefore, it is favorable to increase the welding heat input for improving the joining quality and joint strength.

Fig. 15 Area ratio between joined region and interface at different heat inputs

In addition, in this investigation, it was found that Al content in the Mg alloy weld also has a significant effect on the tensile strength of Mg-steel joints. When the weld Al content is increased to 6.20%, the joint strength can reach 192 MPa. It is mainly related to the increased Al promoting Mg/steel interface reaction. Therefore, it is effective ways to select suitable welding heat input and weld Al content for improving the Mg-steel joint strength.

4 Conclusions

1) The joining of AZ31B Mg alloy to Q235 low carbon steel can be realized by the MIG welding process with Mg alloy filler metals. In the Mg-steel butt joint, there exist two kinds of joining mechanisms, the fusion welding in the Mg alloy side and brazing in steel side.

2) During MIG welding, the temperature distribution in the Mg-steel joint is uneven. The weld appearance and joint microstructures depend on the welding heat input and weld Al content. The satisfactory weld appearance is obtained in the heat inputs of 1744-2171 J/cm. Mg alloy welds containing 3.17% Al and 6.20% Al have fine equiaxed grain structure, consisting mainly of the α(Mg) and the α(Mg)+ β-Mg₁₇Al₁₂ phases, respectively. The transition layer at Mg/steel interface includes AlFe, AlFe₃ and Mg(Fe,Al)₂O₄ compounds. Increasing the weld Al content and heat input favors promoting the Mg/steel reaction to form the continuous interface transition layer.

3) The welding heat input and weld Al content have a significant effect on the Mg-steel joint strength. The joint strength increases obviously in the heat inputs of 1919-2254 J/cm. When the weld Al content is increased to 6.20%, the joint strength reaches 192 MPa, 80% of Mg alloy base metal strength. It is effective ways to select the suitable welding heat input and weld Al content for improving the Mg-steel joint strength.

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