Al-Mg-Si合金U形型材的组织与力学性能-有色金属在线

简介概要

Al-Mg-Si合金U形型材的组织与力学性能

来源期刊：中国有色金属学报(英文版)2020年第11期

论文作者：王向东刘雄丁浩剡苏荣谢紫华潘柏清李永红潘清林邓运来王维裔

文章页码：2915 - 2926

关键词：Al-Mg-Si合金；U形型材；热挤压；显微组织；力学性能；析出相

Key words：Al-Mg-Si alloy; U-shaped profile; hot extrusion; microstructure; mechanical properties; precipitates

摘要：通过光学显微镜、扫描电镜、透射电镜、硬度测试和拉伸性能测试等方法，研究热挤压工艺、固溶时效工艺对Al-Mg-Si合金U形型材组织与性能的影响。结果表明：在热挤压过程中，型材中部分晶粒会发生动态再结晶，再结晶晶粒随后粗化形成粗晶层。在加工硬化和动态回复的共同作用下，粗晶层间的晶粒呈纤维状和亚结构。时效处理后，晶内形成相互垂直的针状β′′相，晶界处可见明显的无沉淀析出带。Al-Mg-Si合金U型型材的抗拉强度、屈服强度、伸长率分别不低于279.4 MPa、258.6 MPa和21.6%，其断口呈韧窝断裂特征。晶界强化和析出强化对型材强度提高有明显贡献。

Abstract: To get a full understanding of hot extrusion, solid solution treatment and aging process on the Al-0.56Mg- 0.63Si alloy, the microstructure and mechanical properties of a U-shaped profile were studied through optical microscopy, scanning electrical microscopy, transmission electrical microscopy, hardness, and tensile tests. The coarse equiaxed grains existed near the profile edge as a result of the dynamic recrystallization nucleation and exceeding growth during hot extrusion. The fibrous deformed and sub-structured grains located between the two coarse grain layers, due to the occurrence of work-hardening and dynamic recovery. Perpendicular needle β′′ precipitates were distributed inside the grain, and obvious precipitates-free zone appeared after aging treatment. The tensile strength, yield strength and elongation of the aged Al-Mg-Si alloy U-shaped profile were no less than 279.4 MPa, 258.6 MPa, and 21.6%, respectively. The fracture morphology showed dimple rupture characteristics. The precipitates and grain boundaries played key role in the strengthening contribution.

Trans. Nonferrous Met. Soc. China 30(2020) 2915-2926

Microstructure and mechanical properties of Al-Mg-Si alloy U-shaped profile

Xiang-dong WANG¹, Xiong LIU¹, Hao DING¹, Su-rong YAN¹, Zi-hua XIE¹, Bai-qing PAN¹, Yong-hong LI¹, Qing-lin PAN², Yun-lai DENG², Wei-yi WANG²

1. Manufacturing Center, Zhuzhou CRRC Times Electric Co., Ltd., Zhuzhou 412001, China;

2. School of Materials Science and Engineering, Central South University, Changsha 410083, China

Received 19 January 2020; accepted 10 August 2020

Key words: Al-Mg-Si alloy; U-shaped profile; hot extrusion; microstructure; mechanical properties; precipitates

1 Introduction

Similar to the automotive industry, steel and aluminum alloys are predominant materials applied in the structural formation of rail trains, including metros, high-speed trains and electric locomotives [1]. Compared with steel, aluminum alloys offer substantial benefits like relative lightness, good manufacturing performance and corrosion resistance. The 5xxx and 6xxx series aluminum alloys are commonly used in sideboards, roof, floor panels and cant rails and the 7xxx series are used for high strength requirements. For example, 5083 and 7N01 aluminum alloys are used in Japan’s Shinkansen trains, and 5005 sheets, 6061, 6063 and 6005 extruded profiles are applied in German high-speed rail [2-4].

Al-Mg-Si alloys have moderate strength, good processing formability and fine anti- corrosion [5,6]. However, they face a great challenge in the design and manufacture of differently shaped extrusion profiles since different parts may suffer unequal force, temperature rise and other processing variations [7,8]. A comprehensive understanding of the relationship between mechanical properties and microstructure is essential to ensure the endurance and safety of the extruded profiles. The deformation behaviors in neat-shaped Al-Mg-Si alloy have been systematically studied in the past decade. In the benefit of these simulation tests, most typical deformation characteristics, including dynamic recovery (DRV), dynamic recrystallization (DRX), void formation and cracking, can be determined. SUN et al [9] constructed 3D processing maps to study the hot deformation of 6A02 aluminum alloy and determined that the optimum hot working domains were (450-470 °C, 0.1-1 s^-1) and (430- 450 °C, 0.01-0.1 s^-1). LIU et al [10] studied the hot deformation behaviors of Al-Mg-Si-Mn-Cr alloy through constitutive models and found that lattice diffusion was the dominate mechanism. However, the realistic extrusion of complex shaped profiles in the industry is quite different by considering the fraction and lubrication, the shape and structure of modules [11]. The inhomogeneous deformation and low recrystallization temperature result in the generation of coarse grains, which is not beneficial for the mechanical properties of extrudates [12-14]. For better utilization of these profiles, the mechanical properties and microstructure of complex extruded profiles should be studied.

Heat treatments are efficient ways to improve the mechanical properties of Al-Mg-Si alloys. The generally accepted precipitation sequence during the aging process can be expressed as [15-19]: supersaturated solid solution (SSSS) → clusters → GP zone → β" precipitates → β'/U₁/U₂/B' precipitates → β precipitates. The SSSS formed after solid solution treatment and water quenching. The clusters containing numerous Mg and Si atoms would form in the early stage of aging treatment. The needle-shaped β" precipitates (Mg₅Si₆) and rod-shaped β' precipitates (Mg₉Si₅) appeared with the prolongation of aging time. Other metastable precipitates like β', U₁ (Al₂MgSi₂), U₂ (Al₄Mg₄Si₄), and B' (Al₃Mg₉Si₇) could also be detected before the equilibrium β phase formation [20]. However, the characteristics of the precipitates and their effects on the mechanical properties have not been determined.

The objective of this study is to have a full understanding of thermal and mechanical processes on an Al-0.56Mg-0.63Si alloy U-shaped profile. The chemical compositions of different parts were determined by inductively coupled plasma atomic emission spectrometry (ICP-AES). The mechanical properties were determined through hardness tests and room temperature tensile tests. The microstructures were observed by optical microscopy (OM), scanning electron microscopy (SEM) with energy-dispersive spectroscopy (EDS) and electron backscattered diffraction (EBSD), and transmission electron microscopy (TEM). The microstructure evolution during extrusion and the strengthening mechanisms were discussed.

2 Experimental

The chemical composition of the alloy is listed in Table 1, which can be classified as 6005A aluminum alloy [21]. Pure aluminum, magnesium ingots, and Al-Mn, Al-Cr, Al-Cu, Al-Si master alloys were melted in the resistance furnace at about 1023 K. The ingots were cast through semi- continuous casting method. After homogenization at 570 °C for 10 h, the Al-Mg-Si alloy U-shaped profiles were extruded with 4 m/min in temperature range of 460-490 °C, and quenched by water online. The solid solution treatment is (550 °C, 1 h), followed by water quenching to room temperature (25 °C) and the typical aging regime is (175 °C, 10 h). The schematic diagram of the entire extrusion and heat treatment process is shown in Fig. 1.

Table 1 Chemical composition of Al-Mg-Si alloy U-shaped profile (wt.%)

Fig. 1 Schematic diagram of entire extrusion and heat treatment

The microstructures were observed by using an OLYMPUS BX51M (OM), Zeiss M10A (SEM), and TECNAI G²20 (TEM). The OM specimens were mechanically polished and etched with a caustic containing 1% HF, 1.5% HCl and 3% HNO₃. The SEM observation was operated at 20 kV. The statistics of recrystallization fraction was achieved by the recrystallized fraction function in HKL channel 5 software. The filter type is circle, which can distinguish the original large angle grain boundary (>15°) and recrystallized grain boundary (>15°). The deformed and sub-structured grains were low angle grain boundaries, which were lower than 15°, of which the sub-structured grains were defined as 2°-15° and the deformed grain was below 2°. The TEM samples were sectioned from the middle part of the U-shaped profile, and the TEM observations were carried out at 200 kV. The hardness tests were carried out on the surface of the profile cross- section with loading at 980 N for 15 s and the interval distance of each point was about 5 mm. The room temperature (25 °C) tensile tests were carried out at 2 mm/min. The samples were sectioned along the longitudinal direction of the extruded profile, and the dimensions are shown in Fig. 2. The typical sampling positions are shown as A and B in Fig. 3.

3 Results

3.1 Microstructure

Fig. 2 Dimensions of tensile sample (unit: mm)

Fig. 3 OM microstructures at different parts of Al-Mg-Si alloy U-shaped profile

Figure 3 shows the schematic illustration and OM microstructures at different parts of the Al-Mg-Si alloy U-shaped profile. It presents the multi-layer structure, and the overall thickness is 12 mm. Most grains are in fibrous structure, whereas some coarse equiaxed-grains locate near the profile edge. The thickness of these coarse equiaxed-grains layer at the inner edge is similar to that of the outer edge in Part A, which is 50-110 μm. For Part B, the thickness is more than 200 μm, which is thicker than that of Part A. The grains in both edges contacting with the die experienced complete recrystallization.

Besides, the grain size of those coarse equiaxed grains at the inner edge is smaller than that of the outer edge. The friction between the billet and die induces a great portion of the heat, resulting in the temperature rise in this part. Consequently, it will drive the grain nucleation. The growth and coarsening of nucleated grains lead to the formation of a coarse-grains zone. Generally, the coarse-grains layer is affected by the shape and quantity of the extrusion die hole. For unequal wall profiles, the coarse-grains layer of the thickened section is often deeper than thinner section. In the equal wall profile, the coarse-grain layer may have a similar thickness. The refined grains with recrystallization texture at the edge may have secondary recrystallization, and the grains grow unevenly and rapidly to form coarse grains during subsequent heat treatment. However, those in the middle part are compressed and elongated. Hence, it might consist of deformed and sub-structure grains as a result of deformation and that of DRV.

Figure 4 presents the OM microstructures at the corners (marked by the arrow) of the U-shaped profile. The coarse equiaxed-grains can be observed at the six right-angles and the biggest thickness is about 500 μm. In contrast, the grains of the two R-angles inside the U-shaped profile show a streamlined structure.

The typical SEM images in the given zones of the U-shaped profile are shown in Fig. 5. The corresponding chemical compositions of the relative second phases are listed in Table 2. Generally, numerous secondary particles displayed different shapes, including rod, spot or bulk. The sizes of these particles were in the range of 5-15 μm. The white secondary particles contained Mn, Cr, Fe, Si and Al, which might exist as Al(FeCrMn)Si. The low melting point metal, i.e., magnesium, dissolved into the Al matrix and the high melting point metals such as Mn, Cr, Fe, could not diffuse into the matrix during solid solution treatment.

Fig. 4 OM microstructures of Al-Mg-Si alloy U-shaped profile

Fig. 5 SEM microstructures in different parts of Al-Mg-Si alloy U-shaped profile

Table 2 Chemical compositions of second phases in marked zones (at.%)

The EBSD images in Parts A and B of the U-shaped profile in Fig. 3 are displayed in Figs. 6 and 7, respectively. The microstructure presents different characteristics in different zones, classified as the recrystallized, sub-structured and deformed grains. Detailed fractions of the recrystallized, sub- structured and deformed grains are listed in Table 3. For Part A (Fig. 6), the recrystallized grains occupy the majority, and the number of deformed grains is the least near the outer edge. The recrystallized grains have obvious abnormal grain growth near the edge. However, the main microstructure is the sub-structured grains in the interior. The amount of deformed grains is the least for both edge and interior zones. For Part B (Fig. 7), the grain size in the interior is smaller than that of the outer edge. The main microstructures are recrystallized and sub-structured grains near the edge and in the interior, respectively. This phenomenon indicates no obvious difference between Parts A and B in this U-shape profile.

Fig. 6 EBSD images of alloy profile at Part A in Fig. 3

Fig. 7 EBSD images of alloy profile at Part B in Fig. 3

Figure 8 shows the TEM images along [100]_Al axis of this Al-Mg-Si alloy profile. The precipitate-free zone (PFZ) locates along the grain boundary and the width of which is 210 nm, as shown in Fig. 8(a). Large amounts of mutually perpendicular precipitates distribute inside the grain, which display needle shape (Fig. 8(b)). The maximum length of the precipitates is around 80 nm. It has been proved by the TEM bright-field images that the transformation of GP zones is completed. Combined with the mechanical properties, the corresponding weak streaks in SAED pattern (red arrows) indicated that the precipitates of the alloy were β′′. Moreover, some circular precipitates are present in the “intercept” way. The TEM microstructures show similar characteristics in Part B (Figs. 8(c, d)). The width of the PFZ is about 280 nm. The mutually perpendicular needle precipitates and circular precipitates exist inside the grain, as shown in Fig. 8(d). The maximum length of the needle precipitates is 100 nm, which is longer than that of Part A.

Table 3 Percentage of recrystallized, sub-structured and deformed grains

3.2 Mechanical properties

The hardness points of the U-shaped profile are marked with numbers 1-51 in Fig. 9, and the corresponding hardness values are shown in Fig. 10. The distance between each point is 5 mm. The overall hardness values vary from HBW 88.1 to HBW 101.3, with the average at HBW 93.7. The mean hardness value at Part B is HBW 93.6 while HBW 94.3 for Part A. The mean hardness at the R-angles between Part A and Part B is HBW 96.8.

Fig. 8 TEM microstructure and SAED pattern along [100]_Al axis of Al-Mg-Si alloy U-shape profile

Fig. 9 Hardness points of Al-Mg-Si alloy U-shaped profile

Fig. 10 Hardness values at different points of Al-Mg-Si alloy U-shaped profile

The ultimate tensile strength, yield strength and elongation of the U-shaped profile are listed in Table 4. The tensile strength, yield strength and elongation are 283.0 MPa, 262.6 MPa and 21.6% at Part A, and 279.4 MPa, 258.6 MPa and 22.3% at Part B, respectively. The strength of Part A is slightly higher, whereas the elongation is lower than Part B. The fracture image presents similar characteristics in both parts. The typical fracture morphologies of various zones in the U-shaped profile are shown in Fig. 11. The fracture images present typical dimple rupture characteristics in different zones.

Table 4 Mechanical properties of different parts in Al-Mg-Si alloy U-shaped profile

4 Discussion

The mechanical properties, including hardness and strength are representatives of microstructure variation in grain size, dislocation, precipitate, and precipitate-free zones (PFZs) of the Al-Mg-Si alloy U-shaped profile, as a consequence of hot extrusion, solid solution and aging treatments. Especially in the process of hot extrusion, various metallurgical phenomena occur, dislocation generation, motion, and annihilation, grain deformation, DRV and DRX. The multi-layer microstructure is composed of coarse equiaxed- grains in the outer edge and inner edge, which are mainly caused by DRX. Large white Al(FeCrMn)Si particles were mainly distributed along the grain boundaries, and perpendicular needle-precipitates existed inside grains. The width of PFZs between two neighbor grains is more than 200 μm. In the interior of the profile, fibrous grains formed by deformation.

ZHANG et al [22] proposed a model to estimate the grain size evolution by combing DRX kinetic model, DRX grain size model and deformed grain size model. The formula of the average grain thickness (d_t )and length (d_l) can be expressed as

(1)

where X_DRX stands for the fraction of DRX grains, and the expression is represented as

(2)

where ε_c is the critical strain for the onset of DRX, ε_ss is the saturated strain, and k and m are materials constants, respectively. The mean recrystallized grain size can be represented as

(3)

where L(T), M(T) and N(T) are functions of deformation temperature, respectively. Besides, the deformed grain size is determined by combining the experimental observation and numerical simulation. The results showed high consistency in the predicted and realistic grain size.

Fig. 11 Typical fracture morphologies of various zones in Al-Mg-Si U-shape profile

In light of this model, the complete vision can be reasonably drawn that the grains between two coarse equiaxed layers of the profile are relatively small. The edge of extrudate originates from the intensive shear zone, and the material of the dead metal zone stays in the die cavity. The velocity of the inner edge and outer edge, including the six right-angles during extrusion, can be treated as almost. The flow rate of two right-angles contacting with the die is low, whereas the strain is high. The middle part in the billet has relatively low strains and comparable velocity to ram speed [23]. The obvious decrease in grain size from the profile edge to the middle part can be attributed to different metallurgical mechanisms. As the strain is induced to the billet, the energy accumulates. As a consequence, the motion of dislocations activates. The mobile dislocations tend to interact with other dislocations in the cells or dislocation walls. When large amounts of dislocations pile up, the sub-grain will form. The well-developed DRV process occurs as a result of high stacking fault energy for aluminum alloy. When the stored energy reaches the maximum, and the dissipation rate decreases to the critical value, the DRX will occur. The temperature rise induced by deformation in the middle part can only trigger partial DRX nucleation. However, the profile edge has a sufficient compact with the die. The temperature increment induced by deformation and fraction leads to the continuous nucleation of DRX.

The dispersoids and precipitates are also influenced by these thermal and mechanical processes. The Al(MnCrFe)Si dispersoids existed after extrusion and heat treatment, which were usually incoherent with the Al matrix and acted as the heterogeneous nucleation sites for quench- induced precipitates [24,25]. The quench-induced precipitates nucleated preferentially on the Al(MnCrFe)Si dispersoids and grew quickly, the size of which could reach 100 nm. The nucleation, growth and coarsening of these quench-induced precipitates consumed solutes nearby, resulting in the shortage of solutes for Mg₂Si precipitates. Consequently, the PFZ formed in the following aging treatment. However, the Al(MnCrFe)Si dispersoids and the quench-induced precipitates might have a limited strengthening effect. A large amount of the coarse quench-induced precipitates lead to a weak strengthening effect after artificial aging. Besides, Al(MnCrFe)Si dispersoids, grain boundaries and dislocations are preferential nucleation sites for heterogeneous precipitation. The precipitates at grain boundaries might lead to a decrease in the effect of boundary strengthening [26,27]. Meanwhile, the grain boundary precipitates (GBPs) play an essential role in the corrosion behaviors of the profile due to the potential difference between the matrix and the precipitates. The solute migration also contributes to the formation of PFZ during aging treatment. The dislocations are generated and multiplied as a consequence of induced strain during hot extrusion and are still retained in the profile after solid- solution treatment though the quantity decrease. Dislocations are thermodynamically unstable and can be treated as an effective nucleation sites for heterogeneous precipitates of the new phase. After the quench-induced precipitates nucleate around, the missing part of the dislocations releases the corresponding distortion energy, which increases the driving force for nucleation. Meanwhile, solute atoms are often segregated on dislocations, and the dislocations can act as a diffusion channel for solute atom precipitates, which satisfies the requirement of new phase formation [28].

The mechanical properties (tensile strength, yield strength and hardness) are influenced by the microstructures. The effects of coarse equiaxed- grains on tensile properties can be ignored in this U-shaped profile, praised for two reasons. First of all, from the size of the tensile sample, it can be seen that 12 mm is the whole width of the section. The samples must contain coarse equiaxed-grains. However, the width of the coarse equiaxed-grains layer is around 2×200 μm (0.4 mm) in Parts A and B, as shown in Fig. 3(a). Compared with the total width (12 mm), the effects of coarse equiaxed- grains are negligible. Secondly, coarse equiaxed- grains are located at the edge, and reduced by the grinding process before testing, which can further weaken their influence on tensile properties. The overall strength or hardness is the combination of the Al matrix, dislocations, grain boundaries, solute atoms, dispersoids and precipitates, among which the effects of precipitates and grain boundaries should be more remarkable. The contribution of the solid solution might be low due to the limited solute quantity in the matrix and continuous precipitation during aging. The dislocations would recombine and annihilate during heat treatment processes, and thus, the effect of dislocation strengthening was not counted as the primary factor. The precipitation strengthening and grain boundary strengthening could be interpreted by the Orowan strengthening mechanism and the Hall-Petch effect [29], respectively. The yield strength contributed by precipitates is 112 MPa after solid-solution treatment and aging at 180 °C in an Al-2.08Mg- 1.98Si-0.3Mn-0.15Zr-0.1Cr-0.15Ti alloy [30]. For this alloy, precipitation strengthening and grain boundary strengthening might play key roles in the contribution of yield strength.

5 Conclusions

(1) The typical multi-layer structure is shown in the cross-section of the U-shaped profile. The coarse equiaxed-grains existed near the profile edge with a thickness of more than 200 μm. The fibrous deformed and sub-structured grains were present between the two coarse grain layers.

(2) The tensile strength, yield strength and elongation of the profile are no less than 279.4 MPa, 258.6 MPa and 21.6%, respectively. The fracture morphology shows the dimple rupture characteristics.

(3) The strengthening mechanisms were assessed and determined. The β′′ precipitates and grain boundary played key role in the strengthening contribution.

Acknowledgments

The authors want to acknowledge the financial support of project on reliability and life research of typical components in rail trains (K10TZ20P0500) of CRRC Zhuzhou Electric Locomotive Research Institute.

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