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Microstructure and mechanical properties of Mg-Li alloy after TIG welding
LIU Xu-he1, GU Shi-hai1, WU Rui-zhi1, LENG Xue-song2, YAN Jiu-chun2, ZHANG Mi-lin1
1. Key Laboratory of Superlight Materials and Surface Technology of Ministry of Education,
Harbin Engineering University, Harbin 150001, China;
2. State Key Laboratory of Advanced Welding Production Technology,
Harbin Institute of Technology, Harbin 150001, China
Received 6 April 2010; accepted 29 September 2010
Abstract: Tungsten inert gas weld was carried out on super-light magnesium-lithium alloy plates with a thickness of 2 mm, using argon gas as a protecting atmosphere. The microstructure and mechanical properties of the welded joints were investigated. The results indicate that the microstructure in the fusion zone is fine, and the microstructure in the heat-affected zone is coarr than the parent metal. The tensile strength of the welded joint is about 84% that of the parent metal. The fracture occurs in a mixed type of toughness and brittleness in the heat-affected zone. During the welding process, aluminum and cerium are enriched at grain boundaries in the fusion zone.
receivebuffersKey words: Mg-Li alloy; TIG welding; microstructure; mechanical properties; gregation
1 Introduction
Magnesium alloys have low density, high-specific strength, excellent dimensional stability and good energy absorption. The alloys are also recyclable, making them a kind of green metallic structural material for the 21st century[1−2]. Mg-Li alloys with a density smaller than normal magnesium alloys have attracted much attention among rearchers for their potentially broad applications in aerospace, transportation, electronic and military industries[3]. Conquently, rearchers have done a lot of work on the welding of magnesium alloy[4−6], as joints are important for advanced materials with wide applications.
Becau Mg alloys have a low melting point, high thermal conductivity, electrical conductivity and thermal expansion coefficient, they are chemically active and readily oxidized[7−8]. ASAHING[6] pointed out that due to the deformation during welding process, the solidification cracks of TIG welded magnesium alloy were restrained[9−10]. CAO et al[11] found that many difficulties, such as coar grains, oxidation, volatilization and thermal cracking, occur during welding becau magnesium alloys have a low melting point and large thermal conductivity, electrical conductivity and thermal expansion coefficient. Mg-Li alloys have similar problems, and as their applications increa, the welding of the materials caus great concerns.
In this work, a superlight magnesium-lithium alloy is welded by tungsten inert gas (TIG) welding using a homogeneous wire. The microstructure is analyzed and the mechanical properties of the welded joint are discusd. The results provide an effective theoretical and experimental basis for expanding the application of magnesium-lithium alloy.
2 Experimental
The alloy ud in this experiment was melted in a vacuum intermediate induction furnace under the protection of argon atmosphere. The ingot was then extruded with an extrusion ratio of 16 at 653 K and rolled at 473 K. The chemical composition of the
Foundation item: Project (51001034) supported by the National Natural Science Foundation of China; Project (208181) supported by the Key Project of Chine Ministry of Education; Projects (2008AA4CH044, 2009AA1AG065, 2010AA4BE031) supported by the Key Project of Science
and Technology of Harbin City, China; Project (HEUCF101001) supported by the Fundamental Rearch Funds for the Central
Universities, China
Corresponding author: WU Rui-zhi; E-mail:
DOI: 10.1016/S1003-6326(11)60739-5
LIU Xu-he, et al/Trans. Nonferrous Met. Soc. China 21(2011) 477−481
478
magnesium-lithium alloy plates ud in this experiment is shown in Table 1. The density of the alloy was tested by Archimedes’ method and found to be 1.45 g/cm 3. The tensile strength of the ba metal before welding was 160.8 MPa and the elongation was 34.7%. The thickness of the ba metal was 2 mm before welding bevels was procesd as shown in Fig.1 on the plates.
Table 1 Chemical composition of Mg-Li alloy (mass fraction, %)
Li Al Zn Ce Mg 10.36 2.69 0.91 0.81 85.23
Fig.1 Schematic diagram of bevel
Before welding, the surfaces of the specimens and wires were cleaned. The specific process involved sanding, washing with acetone, washing with water, washing with alkali, washing with water, washing with acid, washing with water and drying, conquently.
In order to prevent dislocations during the welding process, the two pieces were fixed. There were indentations in the back of the sizing block, which were ud to control the penetration and shape.
The parameters of the welding procedure are shown in Table 2. In order to reduce overheating and prevent burn-through, a high welding speed was ud in the process.
Table 2 Parameters of welding procedure Welding current/A
Welding speed/ (cm·min −1)huihui
Gas flow/ (L·min −1)
Welding arc voltage/V
80 30 13 18
After welding, the sample was cut perpendicularly to the welding am. The specimens were then prepared using standard metallographic procedures. The specimens were etched by a 2% nital for 10−30 s until the microstructure was revealed. The microstructure was subjected to optical and scanning electron microcopy and the distribution of the alloying elements was measured using energy dispersive X-ray spectroscopy.
After removing the residual part of the coronal zone, the plates were machined into tensile specimens according to the ASTM E8M-04 standard procedure. The schematic diagram of tensile specimens is shown in Fig.2,
and the tensile test was brought out at a speed of 5 mm/min on five specimens. Bending properties were also tested.
Fig.2 Dimensions of tensile specimen
3 Results and discussion
3.1 Macro-morphology of welding am
The macro-morphology of the welding am is shown in Fig.3. There are no macroscopic irregulariti
es, such as weld beadings or crater cracks.
Fig.3 Macro-morphology of welded am: (a) Front face; (b) Back face
3.2 Microstructure of welded joint
The TIG-welded joint included a fusion zone, a heat-affected zone (HAZ) and a ba metal zone. The microstructure of the welded joint is shown in Fig.4. The ba metal is compod of single pha (β pha) with equiaxed grains which are not uniform. The microstructure in heat-affected zone is coarr than that in the parent metal. In Fig.4(c), the microstructure of the fusion zone exhibits refined grains. As shown in Fig.4(d), the ba metal and welding am are fud well and the structure is tight.
The microstructures in different areas are not uniform, which are mainly related to the TIG welding
LIU Xu-he, et al/Trans. Nonferrous Met. Soc. China 21(2011) 477−481 479
Fig.4 Microstructures of welded joint: (a) Ba metal; (b) HAZ; (c) Fusion zone; (d) Junction of ba metal and heat-affected zone
thermal cycle process and the physical properties of magnesium alloys. During the welding process, the metal in the fusion zone absorbs a large amount of heat and melts, and then quickly solidifies becau the thermal conductivity coefficient of magnesium alloy is high (154 W/(m·K))[12−13]. On the other hand, the puls in the welding process contribute to the rapid solidification of the metal. Therefore, the microstructure of the fusion zone is refined. During the welding process, becau the melting point of magnesium alloys is low (usually 500−600 °C)[14−15], the heat-affected zone is wide and easily overheated, so the absorbed heat promotes grain growth, resulting in coarr grains in the heat-affected zone. After rolling deformation, the stored energy is relatively high and the grains are extremely unstable. Therefore, the grains grow rapidly when they are heated.
3.3 Mechanical properties of TIG welded plate
The mechanical properties of the TIG welded specimens and the ba metal are given in Table 3. The tensile strength of the TIG welded plate is 84% that of the parent metal.
但是日语Table 3 Tensile properties of Mg-Li alloys
Sample Tensile strength/MPa Fault location Ba metal 170.75 Middle of sample Welded plate 143.76 Welding zone
According to Fig.4, the grains in the heat-affected zone are clearly coarr than tho in the fusion zone and the ba metal. The coar grains result in a decrea of mechanical properties. As proved by the tensile test, fractures occurred in the heat-affected zone, which indicates that coar grains are the main reason for the decrea in the mechanical properties of the weld plate.
Table 4 shows the results of the bend test. The angle
astound
汉译英工具of the normal bend test and the root bend test approach show similar ductility in the front and back. Therefore, it
is confirmed that there is no front/back difference in properties in this welding procedure.
Table 4 Result of bend test
Bending mode Angle/(°)
Front bend 30.3
Back bend 30.1
3.4 Fracture analysis
According to the macro-fracture morphology, the ba metal fractures in the middle of the specimen, the angle between the fracture plant and the tensile direction
is 45°. The fracture of the TIG welded sample occurs in the heat-affected zone, and the facture face is rough and dark. There is no obvious necking before failure.
Figure 5 shows the fractographs of the ba metal and the TIG welded specimen. The fracture microstructure of the ba metal consists of dimples, which is a typical micro-void coalescence fracture. The fracture microstructure of TIG welded sample is compod of dimples and cleavage planes, which is characteristic of a mixed-type fracture. This is
LIU Xu-he, et al/Trans. Nonferrous Met. Soc. China 21(2011) 477−481 480
Fig.5 Fractographs of ba metal (a) and TIG welded sample (b)
caud by the change of the microstructure.
3.5 Composition analysis
The microstructure of the compouds is shown in Fig.6. The compositions in the fusion zone were analyzed by EDS, and the results are shown in Table 5. The compound mainly consists of magnesium, aluminum and cerium, and the content of zinc is zero. The solid solubility of cerium in magnesium is 0.5%. During solidification, most of the cerium reacts with other elements to form compounds[16]. The electronegative difference between the magnesium and cerium is 0.1, while that between aluminum and cerium, zinc and cerium is about 0.4. Cerium should first react with aluminum. The solid solubility of zinc in magnesium is large. The content of zinc in this work is lower than 1%, and it can be assumed that all the zinc is soluted in magnesium. Considering that magnesium is the matrix, the molar ratio of aluminum to cerium is about 2:1, so it can be predicted that the compound is Al2Ce.
During the welding process, the alloy in the welding zone undergoes re-solidification. Therefore, gregation may occur.
As shown in Table 5, the contents of magnesium and zinc at the intracrystalline phas (Point A) are higher than tho at grain boundaries (Point B), and the contents of aluminum and cerium at the intracrystalline pha are lower than tho at grain boundaries. This illustrates that during re-solidification, aluminum and cerium enrich at the front of the solid-liquid interface after reacting, so that the contents of aluminum and cerium in the matrix decrea, leading to under cooling
and refinement of grains in the weld zone.
Fig.6 SEM images of compound in fusion zone (a) and grain boundary and intracrystalline pha (b)
Table 5 Microanalysis of positions in Fig.6 (molar fraction, %) Element Point
A Point
B Point C
Mg 46.11 88.76 83.40
Al 34.97 0.21 1.65
Zn 0 0.79 0.41 Ce 18.62 0.20 2.40 4 Conclusions
1) Using the same material as wire, a TIG weld was implemented on the Mg-10.36Li-2.7Al-0.91Zn-0.81Ce alloy. There are no obvious weld defects.
2) The microstructure in the fusion zone is fine, while that in the heat-affected zone is coar. The heat-affected zone is the weaker part of the weld plate.
3) The tensile strength of the TIG welded plate is 143.73 MPa, which is 84% that of the parent metal. Fractures occurred in the heat-affected zone, which exhibits a mixed-mode fracture of ductile-brittle.
4) The gregation and enrichment of Al and Ce are
LIU Xu-he, et al/Trans. Nonferrous Met. Soc. China 21(2011) 477−481 481
found at the grain boundaries.
References
[1]SANSCHAGRIN A, TREMBLAY R, ANGERS R, DUBE D.
Mechanical properties and microstructure of new magnesium-lithium
ba alloys [J]. Materials Science and Engineering A, 1996, 220(1−2): 69−77
[2]ZHANG Mi-lin, WU Rui-zhi, WANG Tao, LIU Bin, NIU Zhong-yi.
Microstructure and mechanical properties of Mg-x Li-3Al-1Ce alloys
[J]. Transactions of Nonferrous Metal Society of China, 2007, 17(s1):
s381−s384.
[3]WU Rui-zhi, DENG Yong-shu, ZHANG Mi-lin. Microstructure and
mechanical properties of Mg-5Li-3Al-2Zn-x RE alloys [J]. Journal of
Materials Science, 2009, 44(15): 4132−4139.
[4]SU S, HUANG J, LIN H, HO N. Electron-beam welding behavior in
Mg-Al bad alloys [J]. Metallurgical and Materials Transactions, 2002, 33(5):1641−1673.
[5]MARYA M, EDWARDS G LIN S. An investigation on the effects of
gass in GTA welding of a wrought AZ80 magnesium alloy [J].Welding Journal, 2004(7): 203−212.
[6]ASAHING T, TOKISUJE H, KATOH K. Solidification crack
nsitivity of TIG welded AZ31 magnesium alloy [J]. Journal of Japan Institute of Light Metals, 1999, 49(12): 595−599.
[7]ZHU Tian-ping, CHEN Zhan W, GAO Wei. Incipient melting in
partially melted zone during arc welding of AZ91D magnesium alloy
[J]. Materials Science and Engineering A, 2006, 416(1−2): 246−252.commander in chief
[8]MUNITZ A, COTLER C, STERN A, KOHN G. Mechanical
properties and microstructure of gas tungsten arc welded magnesium
AZ91D plates [J]. Materials Science and Engineering A, 2001, 302:
68−73.
[9]LIU Sheng-xin, CHEN Yong, WANG Xi-he, LIU Xiao-fang, LI
Qing-kui, GUAN Shao-kang. Study on microstructure and mechanical properties of He-Ar mixed gas TIG welded joint for
AZ31 magnesium alloy plates. [J] Metal Hotworking Technology,
2007, 6(7): 12−14.
[10]ZHENG Rong, LIN Ran. TIG welding of thin plate in AZ31B Mg
alloy [J]. Welding and Joining, 2003, 4: 43−44.
[11]CAO X, JAHAZI M, IMMARIGEON J, WALLACE W. A review of
lar welding techniques for magnesium alloys [J]. Journal of Materials Processing Technology, 2006, 58(8): 188−204.
[12]WANG Xi-he, LIU Sheng-xin, CHEN Yong, KUANG Ying-huan,
GUAN Shao-kang, NIU Ji-tai. Effect of He-to-Ar ratio on weld
baccanoability of TIG of AZ31 magnesium alloy [J]. Light Alloy Fabrication
Technology, 2006, 34(12): 43−45. (in Chine)
[13]SUN Si-quan, WANG Li-jun. Mechanical properties of magnesium
alloys welded joints [J]. Welding Technology, 2004 33(5): 110−115. [14]DING Wrn-bin, JIANG Hai-yan, ZENG Xiao-qin, YAO Shou-shan.
Progress in welding technology of magnesium alloy [J]. Light Alloy
Fabrication Technology, 2005, 32(3):123−126. (in Chine)
[15]WANG Zhe, LI Dao-gang, WANG Guo-ping. Analysis of structure
and property of cast Mg alloy AZ91 weld joints [J]. Modern Welding,
2008, 6: 26−28.
accompany翻译
[16]WANG Tao, ZHANG Mi-lin, WU Rui-zhi. Microstructure and
properties of Mg-8Li-1Al-1Ce alloy [J]. Materials Letters, 2008, 62:
1846−1848.
一种镁锂合金的TIG焊接组织与力学性能
刘旭贺1,顾世海1,巫瑞智1,冷雪松2,闫久春2,张密林1
1. 哈尔滨工程大学超轻材料与表面技术教育部重点实验室,哈尔滨 150001
2. 哈尔滨工业大学现代焊接生产技术国家重点实验室,哈尔滨 150001外壳英文
摘 要:以氩气为保护气体,用同种合金的焊丝对一种2 mm厚的超轻镁锂合金板进行TIG焊接,研究焊接接头的显微组织和力学性能。结果表明,与母材相比,焊缝区晶粒细小,热影响区晶粒粗大。焊件的抗拉强度为母材的84%,断裂发生在热影响区,属于韧-脆混合性断裂。焊接后,焊缝区的Al和Ce
在晶界处富集。
关键词:镁锂合金;TIG焊接;显微组织;力学性能;偏析
(Edited by FANG Jing-hua)
