Wire and arc additive manufacturing of dissimilar 2319 and 5B06 aluminum alloys

doi:10.1016/j.jmst.2022.02.024

Abstract

Abstract:

Aluminum alloy is the most widely used light alloy at present. By combining different types of aluminum alloys, their functional properties can be expanded. In the present research, two components composed of 2319 (Al-6.5Cu) and 5B06 (Al-6.4Mg) dissimilar alloys were fabricated by wire and arc additive manufacturing (WAAM). The deposited component with the bottom half of 2319 and the top half of 5B06 exhibits better mechanical properties than its counterpart deposited vice versa. Its ultimate tensile strength, yield strength, and elongation are 258.5 MPa, 139.3 MPa, and 5.6%, respectively, which are only slightly inferior to the mechanical properties of 2319 base metal. The results show that for both components, fracture occurred at a layer thickness above the interface layer during the tensile test, regardless of the deposition order. It appears that the thermal stress due to the long dwell time and the remelting of the S-Al₂CuMg phase are the main factors promoting crack initiation. Depending on the deposition order, cracks propagate either along the aggregated pores or strip θ-Al₂Cu phase distributed along the grain boundary. By analyzing the heat input and selecting the appropriate depositing order, the strength of WAAM dissimilar aluminum alloys can be effectively improved through the proper control of microstructure and internal defects.

Key words: Wire and arc additive manufacturing, Dissimilar materials, Defects, Microstructure, Mechanical Properties, Aluminum alloy

Tianxing Chang, Xuewei Fang, Gang Liu, Hongkai Zhang, Ke Huang. Wire and arc additive manufacturing of dissimilar 2319 and 5B06 aluminum alloys[J]. J. Mater. Sci. Technol., 2022, 124: 65-75.

Figures/Tables 16

Table 1. Chemical composition of the 2319 and 5B06 wire (%).

Materials	Si	Fe	Cu	Mn	Mg	Zn	V	Ti	Zr	Al
2319	0.028	0.09	6.47	0.284	0.0005	0.016	0.107	0.132	0.203	Rem
5B06	0.09	0.096	0.002	0.737	6.41	0.009	-	0.122	-	Rem

Fig. 1. The schematic diagram of WAAM equipment.

Table 2. WAAM process parameters of 2319 and 5B06.

Material	Parameters
2319	Mode: CMT+PATravel speed: 0.5 m/minWire feed speed: 6.5 m/minGas flowing rate: 20 L/min
5b06	Mode: CMT+PTravel speed: 0.42 m/minWire feed speed: 6.0 m/minGas flowing rate: 20 L/min

Fig. 2. Cutting position of metallographic and tensile samples and the dimension of the tensile sample in millimeters.

Fig. 3. (a) cross-section and the single wall of (b) component A and (c) component B.

Fig. 4. The microstructure of the interface of (a-e) component A and (f-j) component B.

Fig. 5. The SEM and EDS scanning results in the interface layer of (a), (c), (e), and (g) component A and (b), (d), (f), and (h) component B.

Fig. 6. TEM images of the interface. (a) θ'-Al2Cu and (b) θ"-Al2Cu.

Fig. 7. Comparison of mechanical properties of aluminum alloy with different materials. (a) Stress-strain curves and (b) tensile properties.

Table 3. Mechanical properties of 2319/5B06 dissimilar aluminum alloys and 2319 and 5B06 single alloys.

Empty Cell	Mechanical properties
Empty Cell	UTS (MPa)	YS (MPa)	EL (%)
Component A	258.5 ± 24.2	139.3 ± 1.8	5.6 ± 1.0
Component B	174.6 ± 21.6	108.1 ± 3.8	1.3 ± 1.5
WAAM 2319	297.6 ± 3.5	107.2 ± 0.7	13.4 ± 2.6
WAAM 5B06	321.6 ± 7.7	162.1 ± 4.1	9.1 ± 0.9

Fig. 8. Voltage and current when printing of (a) component A and (b) component B.

Fig. 9. The IPF coloring map and fitted ellipse aspect ratio of (a, c) component A and (b, d) component B.

Fig. 10. Crack initiation along (a) θ-Al2Cu and (b) S-Al2CuMg.

Fig. 11. Cracks and their position in (a, c) component A and (b, d) component B.

Fig. 12. Fracture mechanism at (a) fracture location; crack propagation in (b-d) component A and (e-g) component B.

Fig. 13. SEM images of fracture surfaces for (a) component A, (b) component B, (c) WAAM2319, and (d) WAAM5b06.

References 50

[1]	B.T. Wu, Z.X. Pan, D.H. Ding, D. Cuiuri, H.J. Li, J. Xu, J. Norrish, J. Manuf. Process. 35 (2018) 127-139. DOI URL
[2]	Z. Huda, P. Edi, Mater. Des. 46 (2013) 552-560. DOI URL
[3]	W.C. Ke, X.Z. Bu, J.P. Oliveira, W.G. Xu, Z.M. Wang, Z. Zeng, Opt. Laser Technol. 133 (2021) 106540. DOI URL
[4]	Y. Li, B. Hu, B. Liu, A.M. Nie, Q.F. Gu, J.F. Wang, Q. Li, Acta Mater. 187 (2020) 51-65. DOI URL
[5]	Y. Li, Y. Jiang, B. Liu, Q. Luo, B. Hu, Q. Li, J. Mater. Sci. Technol. 65 (2021) 190-201. DOI URL
[6]	L.H. Shah, M. Ishak, Mater. Manuf. Process. 29 (2014) 928-933. DOI URL
[7]	K.P. Mehta, V.J. Badheka, Mater. Manuf. Process. 31 (2015) 233-254. DOI URL
[8]	J. Yang, J.P. Oliveira, Y.L. Li, C.W. Tan, C.K. Gao, Y.X. Zhao, Z.S. Yu, J. Mater. Pro- cess. Technol. 301 (2022) 117443.
[9]	A. Ramalho, T.G. Santos, B. Bevans, Z. Smoqi, P. Rao, J.P. Oliveira, Addit. Manuf. 51 (2022) 102585.
[10]	W.C. Ke, J.P. Oliveira, B.Q. Cong, S.S. Ao, Z.W. Qi, B. Peng, Z. Zeng, Addit. Manuf. 50 (2022) 102513.
[11]	T.A. Rodrigues, N. Bairrão, F.W.C. Farias, A. Shamsolhodaei, J.J. Shen, N. Zhou, E. Maawad, N. Schell, T.G. Santos, J.P. Oliveira, Mater. Des. 213 (2022) 110270. DOI URL
[12]	J.L. Gu, M.J. Gao, S.L. Yang, J. Bai, J.L. Ding, X.W. Fang, Addit. Manuf. 30 (2019) 100900.
[13]	X.W. Fang, L.J. Zhang, G.P. Chen, K. Huang, F. Xue, L. Wang, J.Y. Zhao, B.H. Lu, Mater. Sci. Eng. A 800 (2021) 140168. DOI URL
[14]	Z.W. Qi, B.J. Qi, B.Q. Cong, R.Z. Zhang, Mater. Lett. 233 (2018) 348-350. DOI URL
[15]	O. Panchenko, D. Kurushkin, I. Mushnikov, A. Khismatullin, A. Popovich, Mater. Des. 195 (2020) 109040. DOI URL
[16]	B.L. Dong, X.Y. Cai, S.B. Lin, X.L. Li, C.L. Fan, C.L. Yang, H.R. Sun, Addit. Manuf. 36 (2020) 101447.
[17]	P.J. Morais, B. Gomes, P. Santos, M. Gomes, R. Gradinger, M. Schnall, S. Bozorgi, T. Klein, D. Fleischhacker, P. Warczok, A. Falahati, E. Kozeschnik, Materials 13 (2020) 1060. DOI URL
[18]	H. Zhong, B.J. Qi, B.Q. Cong, Z.W. Qi, H.Y. Sun, Chin. J. Mech. Eng. 32 (2019) 92. DOI URL
[19]	C.P. Xue, Y.X. Zhang, P.C. Mao, C.M. Liu, Y.L. Guo, F. Qian, C. Zhang, K.L. Liu, M.S. Zhang, S.Y. Tang, J.S. Wang, Addit. Manuf. 43 (2021) 102019.
[20]	Y.H. Zhou, X. Lin, N. Kang, W.D. Huang, J. Wang, Z.N. Wang, J. Mater. Sci. Tech- nol. 37 (2020) 143-153.
[21]	Y.B. Tian, J.Q. Shen, S.S. Hu, Z.J. Wang, J. Gou, J. Manuf. Process. 46 (2019) 337-344. DOI URL
[22]	Y.B. Tian, J.Q. Shen, S.S. Hu, J. Gou, Y. Cui, J. Mater. Sci. Technol. 74 (2021) 35-45. DOI URL
[23]	Y.B. Tian, J.Q. Shen, S.S. Hu, J. Gou, E. Kannatey-Asibu, Sci. Technol. Weld. Join. 25 (2019) 73-80. DOI URL
[24]	B.T. Wu, Z.J. Qiu, Z.X. Pan, K. Carpenter, T. Wang, D.H. Ding, S.V. Duin, H.J. Li, J. Mater. Sci. Technol. 52 (2020) 226-234. DOI URL
[25]	T. Abe, H. Sasahara, Precis. Eng. 45 (2016) 387-395. DOI URL
[26]	C. Dharmendra, S. Shakerin, G.D.J. Ram, M. Mohammadi, Materialia 13 (2020) 100834. DOI URL
[27]	L.M. Liu, Z.L. Zhuang, F. Liu, M.L. Zhu, Int. J. Adv. Manuf. Technol. 69 (2013) 2131-2137. DOI URL
[28]	M.R.U. Ahsan, A.N.M. Tanvir, T. Ross, A. Elsawy, M.S. Oh, D.B. Kim, Rapid Pro- totyp. J. 26 (2019) 519-530.
[29]	A. Kumar, K. Maji, J. Mater. Eng. Perform. 30 (2021) 5413-5425. DOI URL
[30]	X.Y. Chen, J. Han, J. Wang, Y.C. Cai, G.Y. Zhang, L.Z. Lu, Y. Xin, Y.B. Tian, Mater. Lett. 300 (2021) 130141. DOI URL
[31]	Z.W. Yang, Q. Liu, Y. Wang, Z.Q. Ma, Y.C. Liu, Mater. Res. Lett. 8 (2020) 477-482. DOI URL
[32]	S. Chandrasekaran, S. Hari, M. Amirthalingam, Mater. Sci. Eng. A 792 (2020) 139530. DOI URL
[33]	T. Hauser, R.T. Reisch, S. Seebauer, A. Parasar, T. Kamps, R. Casati, J. Volpp, A.F.H. Kaplan, J. Manuf. Process. 69 (2021) 378-390. DOI URL
[34]	C. Cheng, Q.Q. Li, S.B. Lin, J. Zhou, C.L. Fan, C.L. Yang, Rare Met. Mater. Eng. 48 (2019) 775-781.
[35]	N. Çömez, H. Durmu ¸s, J. Cent. South Univ. 27 (2020) 18-26. DOI URL
[36]	R.P. Verma, Mater. Today Proc. 46 (2021) 10306-10309.
[37]	Q. Luo, Y.L. Guo, B. Liu, Y.J. Feng, J.Y. Zhang, Q. Li, K. Chou, J. Mater. Sci. Technol. 44 (2020) 171-190. DOI
[38]	Y.P. Pang, D.K. Sun, Q.F. Gu, K.C. Chou, X.L. Wang, Q. Li, Cryst. Growth Des. 16 (2016) 2404-2415. DOI URL
[39]	A. Elrefaey, N.G. Ross, Acta Metall. Sin. 28 (2015) 715-724. DOI URL
[40]	X.W. Fang, J.N. Yang, S.P. Wang, C.B. Wang, K. Huang, H.N. Li, B.H. Lu, J. Mater. Process. Technol. 300 (2021) 117430. DOI URL
[41]	X.W. Fang, L.J. Zhang, G.P. Chen, X.F. Dang, K. Huang, L. Wang, B.H. Lu, Materials 11 (2018) 2075. DOI URL
[42]	S. Kou, Welding Metallurgy, A John Wiley & Sons, Inc., Hoboken, New Jersey, 2003.
[43]	T. Yuan, Z.L. Yu, S.J. Chen, M. Xu, X.Q. Jiang, J. Manuf. Process. 49 (2020) 456-462. DOI URL
[44]	E.S. Salomatova, M.F. Kartashev, D.N. Trushnikov, G.L. Permykov, T.V. Olshan-skaya, I.R. Abashev, E.M. Fedoseeva, E.G. Koleva, IOP Conf. Ser. Mater. Sci. Eng. 758 (2020) 012064. DOI URL
[45]	T. DebRoy, H.L. Wei, J.S. Zuback, T. Mukherjee, J.W. Elmer, J.O. Milewski, A.M. Beese, A. Wilson-Heid A. De, W. Zhang, Prog. Mater. Sci. 92 (2018) 112-224. DOI URL
[46]	Z.W. Qi, B.Q. Cong, B.J. Qi, H.Y. Sun, G. Zhao, J.L. Ding, J. Mater. Process. Technol. 255 (2018) 347-353. DOI URL
[47]	K. Huang, K. Marthinsen, Q.L. Zhao, R.E. Logé, Prog. Mater. Sci. 92 (2018) 284-359. DOI URL
[48]	J.L. Gu, J.L. Ding, S.W. Williams, H.M. Gu, P.H. Ma, Y.C. Zhai, J. Mater. Process. Technol.(2016) 26-34.
[49]	Y.D. Jing, X.W. Fang, N.Y. Xi, X.L. Feng, K. Huang, Mater. Charact. 182 (2021) 111571. DOI URL
[50]	C.R. Cunningham, J.M. Flynn, A. Shokrani, V. Dhokia, S.T. Newman, Addit. Manuf. 22 (2018) 672-686.