Recent Progress and Development in Extrusion of Rare Earth Free Mg Alloys: A Review

doi:10.1007/s40195-018-00871-2

Abstract

Abstract:

Mg and its alloys are the lightest structural metals available and are extremely attractive for applications as lightweight components, particularly in the automobile, electronic, and aerospace industries. The global market for wrought Mg alloys has steadily expanded over the past decade. And numerous studies have been carried out to meet this increasing demand of high-performance Mg alloys. However, Mg extrusion alloys have had a very limited usage so far. To overcome existing industrial challenges, one desirable approach is the development of low-cost rare earth (RE) free Mg extrusion alloys with superior mechanical properties. This review will introduce the recent research highlights in the extrusion of Mg alloys, specifically focusing on low-cost RE-free Mg alloy. The results from both the literature and our previous study are summarized and critically reviewed. Several aspects of RE-free Mg extrusion alloys are described in detail: (1) novel alloying designs including Mg-Al-, Mg-Zn-, Mg-Ca-, Mg-Sn-, and Mg-Bi-based alloys, (2) advanced extrusion techniques, and (3) extrusion-related severe plastic deformation (SPD) processing. Accordingly, considering the large gap in mechanical properties between the current RE-free Mg alloys and high-performance aluminum alloys, new alloy design, processing route control, and recommendations for future research on RE-free Mg extrusion alloys are also proposed. We hope this review will not only offer insightful information regarding the extrusion of RE-free Mg alloys but also inspire the development of new Mg extrusion technologies.

Key words: Mg alloy, Extrusion, Rare earth free, Novel processing, Mechanical properties

Shuai-Ju Meng, Hui Yu, Shao-Da Fan, Qi-Zhi Li, Sung Hyuk Park, Joung Sik Suh, Young Min Kim, Xiao-Long Nan, Ming-Zhe Bian, Fu-Xing Yin, Wei-Min Zhao, Bong Sun You, Kwang Seon Shin. Recent Progress and Development in Extrusion of Rare Earth Free Mg Alloys: A Review[J]. Acta Metallurgica Sinica (English Letters), 2019, 32(2): 145-168.

Figures/Tables 15

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Compositions (wt%)	Extrusion parameters T, v (m/min), r	TYS (MPa)	UTS (MPa)	EL (%)	YR	Ref.
AZ80-0.5Ca	450°C, -, 12:1, T5	180	253	7.8	-	[21]
Mg-4Al-2Sr-0.3Mn	360°C, -, -	262.4	296.4	6.2	-	[22]
Mg-4Al-2Sr-1Ca-0.3Mn	360°C, -, -	299.1	326.7	3.6	-	[22]
AM80	250°C, 15.06, 25:1	178	319	17.1	-	[23]
AM80-3Sn	250°C, 15.06, 25:1	199	340	16	-
AM80-5Sn	250°C, 15.06, 25:1	242	349	9.9	-
AM80-7Sn	250°C, 15.06, 25:1	251	345	8.2	-
ATM110	300°C, 25, 25:1	260	292	21.0	0.89	[24]
ATM310	250°C, 25, 25:1	229	293	16.0	0.88
	300°C, 25, 25:1	213	281	20.5	0.76
	350°C, 25, 25:1	201	271	20.0	0.74
ATM610	250°C, 25, 25:1	241	319	12.0	0.76
ATM130	300°C, 25, 25:1	253	288	19.5	0.85
ATM330	250°C, 25, 25:1	225	306	15.4	0.74
ATM630	250°C, 25, 25:1	220	318	8.6	0.69
Mg-8Al-4Sn-2Zn-0.15Mn	250°C, 0.12, 20:1	371	415	9.1	1.02	[25]
AZ82	250°C, 1.2, 20:1	233	347	13.4	0.97	[26]
AZT822	250°C, 1.2, 20:1	258	361	11.2	1.03
AZT824	250°C, 1.2, 20:1	280	370	10.1	1.09
AZT826	250°C, 1.2, 20:1	287	354	7.8	1.09
Mg-3.6Al-3.3Ca-0.4Mn	DC, 350°C, 0.12, 20:1	410	420	5.6	0.83	[27]
Mg-3.6Al-3.3Ca-0.4Mn	PM, 350°C, 0.12, 20:1	304	314	9.5	0.81	[28]
Mg-3.6Al-3.3Ca-0.4Mn	DC, 400°C, 0.12, 20:1	409	413	8	0.82	[28]
Mg-0.30Al-0.21Ca-0.47Mn	350°C, 60, 20:1	206	240	29	0.68	[29]
	400°C, 60, 20:1	200	233	24	0.65
	450°C, 60, 20:1	190	233	20	0.55
	500°C, 60, 20:1	177	222	17.5	0.54
Mg-0.30Al-0.21Ca-0.47Mn	500°C, 60, 20:1, T5	207	254	13.6	-	[30]
Mg-0.30Al-0.21Ca-0.47Mn	500°C, 60, 20:1	170	218	15.5	-
AZ31	500°C, 1.2, 20:1, T5	177	248	20	-
Mg-0.31Al-0.19Ca-0.43Mn	275°C, 24, 20:1, T6	230	262	26	0.72	[31]
Mg-1.19Al-0.20Ca-0.46Mn	275°C, 24, 20:1, T6	287	306	20	0.67
Mg-2.48Al-0.20Ca-0.44Mn	275°C, 24, 20:1, T6	240	283	18	0.62

Compositions (wt%)	Extrusion parameters T, v (m/min), r	TYS (MPa)	UTS (MPa)	EL (%)	YR	Ref.
AZ80-0.5Ca	450°C, -, 12:1, T5	180	253	7.8	-	[21]
Mg-4Al-2Sr-0.3Mn	360°C, -, -	262.4	296.4	6.2	-	[22]
Mg-4Al-2Sr-1Ca-0.3Mn	360°C, -, -	299.1	326.7	3.6	-	[22]
AM80	250°C, 15.06, 25:1	178	319	17.1	-	[23]
AM80-3Sn	250°C, 15.06, 25:1	199	340	16	-
AM80-5Sn	250°C, 15.06, 25:1	242	349	9.9	-
AM80-7Sn	250°C, 15.06, 25:1	251	345	8.2	-
ATM110	300°C, 25, 25:1	260	292	21.0	0.89	[24]
ATM310	250°C, 25, 25:1	229	293	16.0	0.88
	300°C, 25, 25:1	213	281	20.5	0.76
	350°C, 25, 25:1	201	271	20.0	0.74
ATM610	250°C, 25, 25:1	241	319	12.0	0.76
ATM130	300°C, 25, 25:1	253	288	19.5	0.85
ATM330	250°C, 25, 25:1	225	306	15.4	0.74
ATM630	250°C, 25, 25:1	220	318	8.6	0.69
Mg-8Al-4Sn-2Zn-0.15Mn	250°C, 0.12, 20:1	371	415	9.1	1.02	[25]
AZ82	250°C, 1.2, 20:1	233	347	13.4	0.97	[26]
AZT822	250°C, 1.2, 20:1	258	361	11.2	1.03
AZT824	250°C, 1.2, 20:1	280	370	10.1	1.09
AZT826	250°C, 1.2, 20:1	287	354	7.8	1.09
Mg-3.6Al-3.3Ca-0.4Mn	DC, 350°C, 0.12, 20:1	410	420	5.6	0.83	[27]
Mg-3.6Al-3.3Ca-0.4Mn	PM, 350°C, 0.12, 20:1	304	314	9.5	0.81	[28]
Mg-3.6Al-3.3Ca-0.4Mn	DC, 400°C, 0.12, 20:1	409	413	8	0.82	[28]
Mg-0.30Al-0.21Ca-0.47Mn	350°C, 60, 20:1	206	240	29	0.68	[29]
	400°C, 60, 20:1	200	233	24	0.65
	450°C, 60, 20:1	190	233	20	0.55
	500°C, 60, 20:1	177	222	17.5	0.54
Mg-0.30Al-0.21Ca-0.47Mn	500°C, 60, 20:1, T5	207	254	13.6	-	[30]
Mg-0.30Al-0.21Ca-0.47Mn	500°C, 60, 20:1	170	218	15.5	-
AZ31	500°C, 1.2, 20:1, T5	177	248	20	-
Mg-0.31Al-0.19Ca-0.43Mn	275°C, 24, 20:1, T6	230	262	26	0.72	[31]
Mg-1.19Al-0.20Ca-0.46Mn	275°C, 24, 20:1, T6	287	306	20	0.67
Mg-2.48Al-0.20Ca-0.44Mn	275°C, 24, 20:1, T6	240	283	18	0.62

Compositions (wt%)	Extrusion parameters T, v (m/min), r	YS (MPa)	UTS (MPa)	El (%)	YR	Ref.
Mg-1.0Zn	350°C, 0.12, 16:1	148	230	16.2	-	[37]
Mg-2Zn	320°C, -, 23.6:1	115	192	22.8	-	[38]
Mg-6Zn	250°C, -, 8:1	169.5	279.5	18.8	-	[39]
Mg-6.2Zn (Z6)	350°C, 0.12, 20:1.	162	290	21	-	[40]
Mg-6.2Zn (Z6)	350°C, 0.12, 20:1, T6	254	318	17.3	-
Mg-6.2Zn-0.6Zr	350°C, 0.12, 20:1.	244	317	13.8	-
Mg-6.2Zn-0.6Zr	350°C, 0.12, 20:1, T6	275	318	17.1	-
Mg-6Zn-0.2Ca	300°C, 0.12, 20:1	148	275	26	0.91	[41]
Mg-6Zn-0.2Ca-0.8Zr	300°C, 0.12, 20:1	310	357	18	0.84	[41]
Mg-4.69Zn-0.48Ca	250°C, -, 18:1	291	329	15.8	-	[42]
Mg-1.0Zn-0.2Ca	350°C, 0.12, 16:1	120	200	40	-	[37]
Mg-1.0Zn-0.5Ca	330°C, 0.12, 16:1	105	205	44	-	[37]
ZM61	350°C, 0.2-2.8, 25:1	209	305	11.5	-	[43]
ZM61	350°C, 0.2-2.8, 25:1, double aged	338	366	5.2	-	[43]
Mg-6Zn-1Mn-4Sn	350°C, 3, 25:1	250	330	11	-	[44]
Mg-6Zn-1Mn-4Sn	350°C, 3, 25:1, double aged	378	390	4.16	-
Mg-5.25Zn-0.6Ca	300°C, 0.12, 20:1	220	265	21.4	-	[45]
Mg-5.25Zn-0.6Ca-0.3Mn	300°C, 0.12, 20:1	272	303	18.9	-	[45]
Mg-6Zn-1Si-0.5Mn	350°C, 0.48, 25:1	200	316	20.6	-	[46]
Mg-6Zn-1Si-0.5Mn	350°C, 0.48, 25:1, T5	290	320	16	-
Mg-6Zn-1Si-0.5Mn-0.2Ca	350°C, 0.48, 25:1, double aged	330	360	12.5	-
Mg-0.21Zn-0.3Ca-0.14Mn	300°C, 6, 20:1	100	185	32	-	[47]
Mg-0.21Zn-0.3Ca-0.14Mn	300°C, 60, 20:1	~70	~177	~28	-
Mg-0.53Zn-0.24Ca-0.27Mn	300°C, 6, 20:1	108	200	33	-
Mg-0.53Zn-0.24Ca-0.27Mn	300°C, 60, 20:1	~75	~190	~30	-
Mg-0.71Zn-0.36Ca-0.07Mn	300°C, 6, 20:1	108	220	37	-
Mg-0.71Zn-0.36Ca-0.07Mn	300°C, 24, 20:1	95	193	34	-
Mg-0.21Zn-0.30Ca-0.14Mn	300°C, 1.2, 20:1	310	310	22	0.54	[48]
Mg-0.21Zn-0.30Ca-0.14Mn	400°C, 1.2, 20:1	115	210	32	0.78	[48]
Mg-5.99Zn-1.76Ca-0.35Mn	300°C, 0.12, 20:1	289	303	16	0.89	[49]
Mg-3.0Zn-1.0Sn-0.3Mn-0.3Ca	200°C, 60, 30:1	220	282	12	-	[50]
Mg-3.0Zn-1.0Sn-0.3Mn-0.3Ca	300°C, 60, 30:1	187	301	19.6	-	[50]
Mg-4Zn-2Al-2Sn	225°C, 1-2, 61:1	211	317	27.6	0.88	[51]
	250°C, 1-2, 61:1	176	296	24	0.89
	275°C, 1-2, 61:1	173	293	23.6	0.95

Compositions (wt%)	Extrusion parameters T, v (m/min), r	YS (MPa)	UTS (MPa)	El (%)	YR	Ref.
Mg-1.0Zn	350°C, 0.12, 16:1	148	230	16.2	-	[37]
Mg-2Zn	320°C, -, 23.6:1	115	192	22.8	-	[38]
Mg-6Zn	250°C, -, 8:1	169.5	279.5	18.8	-	[39]
Mg-6.2Zn (Z6)	350°C, 0.12, 20:1.	162	290	21	-	[40]
Mg-6.2Zn (Z6)	350°C, 0.12, 20:1, T6	254	318	17.3	-
Mg-6.2Zn-0.6Zr	350°C, 0.12, 20:1.	244	317	13.8	-
Mg-6.2Zn-0.6Zr	350°C, 0.12, 20:1, T6	275	318	17.1	-
Mg-6Zn-0.2Ca	300°C, 0.12, 20:1	148	275	26	0.91	[41]
Mg-6Zn-0.2Ca-0.8Zr	300°C, 0.12, 20:1	310	357	18	0.84	[41]
Mg-4.69Zn-0.48Ca	250°C, -, 18:1	291	329	15.8	-	[42]
Mg-1.0Zn-0.2Ca	350°C, 0.12, 16:1	120	200	40	-	[37]
Mg-1.0Zn-0.5Ca	330°C, 0.12, 16:1	105	205	44	-	[37]
ZM61	350°C, 0.2-2.8, 25:1	209	305	11.5	-	[43]
ZM61	350°C, 0.2-2.8, 25:1, double aged	338	366	5.2	-	[43]
Mg-6Zn-1Mn-4Sn	350°C, 3, 25:1	250	330	11	-	[44]
Mg-6Zn-1Mn-4Sn	350°C, 3, 25:1, double aged	378	390	4.16	-
Mg-5.25Zn-0.6Ca	300°C, 0.12, 20:1	220	265	21.4	-	[45]
Mg-5.25Zn-0.6Ca-0.3Mn	300°C, 0.12, 20:1	272	303	18.9	-	[45]
Mg-6Zn-1Si-0.5Mn	350°C, 0.48, 25:1	200	316	20.6	-	[46]
Mg-6Zn-1Si-0.5Mn	350°C, 0.48, 25:1, T5	290	320	16	-
Mg-6Zn-1Si-0.5Mn-0.2Ca	350°C, 0.48, 25:1, double aged	330	360	12.5	-
Mg-0.21Zn-0.3Ca-0.14Mn	300°C, 6, 20:1	100	185	32	-	[47]
Mg-0.21Zn-0.3Ca-0.14Mn	300°C, 60, 20:1	~70	~177	~28	-
Mg-0.53Zn-0.24Ca-0.27Mn	300°C, 6, 20:1	108	200	33	-
Mg-0.53Zn-0.24Ca-0.27Mn	300°C, 60, 20:1	~75	~190	~30	-
Mg-0.71Zn-0.36Ca-0.07Mn	300°C, 6, 20:1	108	220	37	-
Mg-0.71Zn-0.36Ca-0.07Mn	300°C, 24, 20:1	95	193	34	-
Mg-0.21Zn-0.30Ca-0.14Mn	300°C, 1.2, 20:1	310	310	22	0.54	[48]
Mg-0.21Zn-0.30Ca-0.14Mn	400°C, 1.2, 20:1	115	210	32	0.78	[48]
Mg-5.99Zn-1.76Ca-0.35Mn	300°C, 0.12, 20:1	289	303	16	0.89	[49]
Mg-3.0Zn-1.0Sn-0.3Mn-0.3Ca	200°C, 60, 30:1	220	282	12	-	[50]
Mg-3.0Zn-1.0Sn-0.3Mn-0.3Ca	300°C, 60, 30:1	187	301	19.6	-	[50]
Mg-4Zn-2Al-2Sn	225°C, 1-2, 61:1	211	317	27.6	0.88	[51]
	250°C, 1-2, 61:1	176	296	24	0.89
	275°C, 1-2, 61:1	173	293	23.6	0.95

Compositions (wt%)	Extrusion parameters T, v (m/min), r	YS (MPa)	UTS (MPa)	El (%)	YR	Ref.
Mg-1.05Ca-0.097Mn	300°C, 2.4, 20:1	310	-	6.5	-	[55]
Mg-1.05Ca-0.097Mn	350°C, 2.4, 20:1	280	-	11	-	[55]
Mg-0.41Ca-0.4Al-0.02Mn	350°C, 0.86-1.41, 19.6:1	~165	~234	~34	-	[56]
Mg-0.84Ca-0.4Al-0.02Mn	350°C, 0.86-1.41, 19.6:1	~185	~239	~19.5	-
Mg-1.89Ca-0.4Al-0.02Mn	350°C, 0.86-1.41, 19.6:1	~204	~252	~14.9	-
Mg-2.85Ca-0.4Al-0.02Mn	350°C, 0.86-1.41, 19.6:1	~248	~273	~7.3	-
Mg-0.5Ca	350°C, -, 4:1+236°C, -, 25:1	420	-	~7.5	-	[57]
Mg-1.0Ca-0.5Sr	275°C, -, 25:1	~304	~307	~10.4	~0.82	[58]
	340°C, -, 25:1	~202	~234	~18.3	~0.90
	400°C, -, 25:1	~157	~215	~18.7	~0.87
Mg-1Ca-1Zn-0.6Zr	350°C, 0.18, 30:1	306	314	10.3	-	[59]
Mg-1Ca-1Zn-0.6Zr	400°C, 0.18, 30:1	262	291	11.7	-
Mg-2Sn-2Ca	220°C, 0.36, 20:1	443	460	1.2	0.72	[60]
	240°C, 0.36, 20:1	420	435	3.0	0.73
	280°C, 0.36, 20:1	386	414	5.8	0.90
	320°C, 0.36, 20:1	358	365	8.9	-