DE2658187A1 - MAGNESIUM ALLOYS - Google Patents

Description

EWALD OPPERMANN PATENT ADVOCATE

88 27 21 «B5 OFFENBACH (MAIN) · KAISERSTRASSE 9. TELEPHONE (till) . EWOPAT CABLE

December 20, 1976

Op / ef

37/40

Magnesium Elektron Limited Lumn's Lane, Clifton Junction, Swinton, Manchester M27 2LS, England

Magnesium alloys

The invention relates to magnesium alloys and also includes a method of making cast products from it.

Magnesium alloys find use where light weight is essential and they are particularly useful for the aerospace industries.

709825/0810

Known magnesium alloys with advantageous mechanical properties include alloys which contain zinc and mixtures of rare earth metals which have a high proportion of cerium. Such an alloy contains about 4.5 wt.% Zinc and about 1.0 I of rare earths metals having a high proportion of cerium as a grain refiner with added zirconium. These alloys can achieve good mechanical properties (e.g. 0.2 % yield strength of about T35 N / mm,

2 breaking strength of about 200 N / mm and breaking elongation of about 4 %) , but they are difficult to cast, so that it is difficult to cast large parts of satisfactory quality. Difficulties can be encountered in welding with more difficult castings assembled.

Alloys with improved castability have been obtained by using greater proportions of zinc and rare metals Earths, but these tend to be brittle. Brittleness can be eliminated by hydrating treatment, which has the consequence that the alloy is at a high temperature in a hydrogen atmosphere for is dealt with for a considerable period of time (GB-PS 1 035 260). However, the cost of these alloys is very high high because special ovens and safety measures are required for hydrogen treatment. After treatment these alloys are very difficult to weld in hydrogen.

The invention is based on the object of magnesium alloys containing zinc and rare earth metals provide that have good castability, weldability and satisfactory strength properties without resorting to hydrogen treatment must become,

- 3 709825/0810

.6 *

According to the basic idea of the invention, the object is achieved by using a mixture of rare elements Dissolved earth, which has a high proportion of neodymium and a low or zero proportion of cerium and lanthanum. In particular, these alloys have a greatly improved formability compared to the alloys containing cerium.

According to the invention, the magnesium alloy is characterized in that, in addition to impurities, the contains the following components

Magnesium is at least 80% by weight.

Zinc 4-7 wt.!

Rare earth metals 1 - 5 wt.

where the rare earth metals are at least 60% by weight Contains neodymium and essentially no cerium or lanthanum.

Pure neodymium is expensive, but mixtures of rare earth metals known as "didymium" are commercially available which contain at least 60% by weight neodymium with the remainder being essentially rare earth metals such as e.g. B. Praseodymium with a small or zero content of cerium and lanthanum. Taken together, the content of cerium and lanthanum typically less than 2 to 3 wt.%, The rare earth metals present. Accordingly, the proportion of cerium and lanthanum in the alloy according to the invention is very low.

The rare earth metals preferably contain at least 75 wt.% Of neodymium.

709825/0810

In one embodiment, the alloy contains 1 to 3 liters of rare earth metals and a preferred composition in this range has 5 to 7 % zinc and 1.5 to 3 liters of rare earth metals. It has been found that optimum properties can be achieved with 6 to 7 % zinc and 2 to 3 % rare earth metals.

Normally, it is desirable to incorporate at least 0.4 wt.% As a grain refiner acting zirconium. The zirconium content may be up to 1 wt.%, Respectively .. If desired, the alloy may have other components, in order to improve its properties in other respects. Up to 2.0 % manganese can be present, but the maximum amount is limited by its mutual solubility with zircon when the latter is present. White

15 other possible additions are listed below:

Ag 0-8 wt. I.

Cd 0-5% wt.

Li 0-6% wt.

Ca 0-1% by weight

20 Ga 0-2% wt.

In 0-2% by weight

Tl 0-5 wt

Pb 0-1% wt.

Bi 0-1 wt. ⁰ *

25 Th 0-7 wt. %

Fe up to 0.1 wt.%

Be · O - 0.05 wt

Y 0-5% wt.

Cu 0-0.5% wt.

It should be noted that yttrium is not classified as a rare earth metal.

709825/0810

The alloys of the invention can be used for the casting of objects, heat treatment normally being required to achieve optimal mechanical properties. The heat treatment normally comprises solution heat treatment at an elevated temperature, usually from 450 ° C. to the solidus temperature of the alloy (usually the solidus temperature is about 500 ^° C.), followed by quenching and hardening at a temperature permitting precipitation. The tempering temperature is generally from 100 to 350 ^° C. It is preferred to quench in water in order to achieve optimum properties; quenching in hot water reduces the risk of cracking.

Typical heat treatment conditions include a temperature of 480 ^° C. for about 8 hours, followed by quenching and curing for a period of 16 hours at 250 ^° C.

An alternative heat treatment is high temperature solution heat treatment dispensable and simply consists of curing the cast body at a temperature at which Elimination takes place. It has been found that this treatment has a particularly high yield strength results, but the elongation and the breaking strength are in generally lower than those obtained by solution heat treatment followed by quenching and curing be achieved.

Alloys according to the invention are described below with reference to the examples explained.

709825/0810

• a.

Examples

Alloys of the composition shown in Table 1 were prepared and cast into test pieces by conventional methods. The zinc was incorporated into the melt as pure metal, the rare earth metals (RE) were added as a mixture of rare earth metals with over 75% by weight of neodymium and essentially without any lanthanum or cerium content, and the zirconium was added as a magnesium / zirconium alloy having about 35 wt.% zirconium.

For comparison purposes, a similar alloy was produced which contained about 6 % zinc, 3 % rare earth metals with a high proportion of cerium (at least 50 I) and about 0.75 % zirconium.

TABLE 1

I.
alloy analysis ZnI RE% ZRI 5.96 3.01 0.76 1 6.03 3.07 0.73 2 5.94 2.80 0.83 3 5.88 2.82 0.82 4th 6.23 2.71 0.83 5 6.06 2.53 0.78 6th about 6 I. about 3 % about 0.6% 7th

709825/0810

The specimens were subjected to mechanical tests according to British Standard 18 after the heat treatment. The heat treatments used and the results obtained are shown in Table 2.

- 8 TABLE 2

709825/0810

- 8 TABLE

alloy Heat treatment deterrence I. Hardening Stretch limit 90 Yield stress 97 Break strength strain lsi ! h ⁰ C by h ° C N / mm ² 101 N / mm ² 108 N / mm ² * 8 cn
in 1/2 8 480 Air cooling 93 100 205 7th 9 fj 5 16 180 93 100 234 10 6 00 4th 16 250 229 10 3 4330 93 101 229 10 109 118 CD
tD 1/5/6 8 480 oil - 102 112 229 9 OO 5 16 180 94 102 240 9 ro
cn 2 16 250 184 4th CD 6th 4330 84 97 230 9 1/2 OO 111 122 1/2/6 8 480 Hot water - 123 136 229 9 O. "4 16 180 83 100 195 ^X 3 ^X 3 16 250 85 100 205 ^X 2 1/2 ^X 5 4330 116 127 202 6th 1/2/3 8 480 Cold water - 125 135 219 9 3 16 180 97 107 239 8th 5 16 250 90 102 219 ^X * » 4330 126 136 226 7th 8 490 Cold water - 227 7th 16 250 233

- 9 - TABLE CONTINUED

CO CO IO

alloy Heat treatment
h ⁰ C deterrence Hardening
h ° C Stretch limit
N / mm ² Yield stress
N / mm ² Breaking strength
N / mm ^z strain 7th
7th
7th
7th
7th
5/6
7th
1/3/6 8 470 Cold water 16 250 90
115 102
125 222
212 9
5 Comparison
alloy
A.
B. 8 450 Kait water 16 250 O VO
OO -C- 107
12o 205
204 6th
5 8 430 Cold water 16 180
16 250 102
113
114 NJ to -
vn-C-vji 187
192
189 3
3
3 like poured - - 110 120 154 2 like poured
8 480 Hot water 16 180 - 119
108 160
185 1
4 1/2

= Test rods contained inclusions

From these results it can be seen that the alloys according to the invention have breaking strengths and elongations which are considerably greater than those of the cerium-containing alloys when they have been subjected to a solution heat treatment at a temperature of at least 450 ^° C. with subsequent quenching and hardening.

To determine the sole effect of hardening, the same alloys were hardened from the as-cast state. The curing conditions and the results obtained are shown in Table 3.

TABLE 3

alloy Hardening Stretch limit Yield stress Break-proof strain h ⁰ C N / mm ² N / mm ² speed N / mm ² % 1/2/3 2 180 114 125 198 4th 1/2/3 4 180 110 123 I89 4th 1/2/4 16 180 124 136 188 2 1/2 1/3/4 32 180 126 139 200 2 1/2 2/3/4 64 180 132 145 203 2 1/2 1/3/6 128 180 136 149 198 2 2/3/4 1 250 123 135 I89 3 1/2/3 2 250 132 145 200 2 1/2 1/2/3 4250 137 150 203 1 1/2 1/2/2 16 250 147 158 206 2 1/3/4 32 250 148 159 205 2 4/5/6 1/2 330 135 146 185 1 1/2 2/3/4 1,330 144 156 205 2 1/2/3 2,330 150 161 201 2 1/2/3 4330 150 160 208 2 1/2 1/2/4 16 330 136 151 194 2 1/3/4 32 33o 139 151 193 1 1/2

- 11 -

709825/0810

-H-

From these results it can be seen that hardening alone gives high yield stress and 0.1% yield strength, but lower breaking strength and elongation than the solution-annealed alloys.

Further attempts were made using the same treatment modality as for alloys 1 to 7 but with different alloy combinations given in Table 4 adjustments carried out. The "comparison" alloy contained a mixture of rare earth metals, which contained a high proportion of cerium. The metals rarer Earths of alloys 8 to 27 contained over 75% by weight neodymium and essentially no cerium or lanthanum.

- 12 Table 4

709825/0810

- 12 TABLE 4

O CD OO 5 "O

analysis Zn & RE% ^X IrX Heat treated and hardened (T6) Expansion chip
voltage N / mm Break-proof
speed N / mm strain only hardened (T5) Expanded chipboard
voltage N / mm ² fracture
firm
speed
N / mm ² strain
% 26581 alloy 6.0 2.94
(Cerium) 0.75 0.1% stretch
limit N / min 123 163 2 0.1% stretch
limit N / mm 162 194 2 comparison 4.9
5-0
5-2
5.1 1.51
2.00
2.49
2.83 0.63
0.70
0.70
0.65 113 123
124
120
117 244
in
226
229 9
6th
7th
9 149 156
151
149 207
195
199 2
2
2 8th
9
10
11 5-5
5-5
5.5
5-5 1.55
2.00
2.47
2.79 0.71
0.66
0.69
0.70 110
112
107
103 125
120
122
117 236
206
242
228 7th
4th
9
8th 143
138
138 160
154
153 204
190
209 12th
13th
14th
15th 6.0
5.8
6.0
6.0 1.61
2.00
2.48
2.93 0.73
0.75
0.74
0.71 116
109
109
105 125
126
131
128 221
228
236
239 6th
7th
7th
8th 148
141
140 165
160
160
159 213
212
212
210 2
2
2
2 16
17th
18th
19th 6.4
6.5
6.3
6.6 1.55
2.05
2.40
2.92 0.77
0.73
0.76
0.75 112
114
120
112 125
129
130
134 211
203
230
245 5
3 1/2
6 1/2
9 153
148
148
147 20th
21
22nd
23 7.1
6.9
7.0
6.8 1.65
1.91
2.37
2.67 0.82
0.75
0.80
0.77 114
117
117
122 120
118
133
133 ■ 198
181
180
195 4th
3
1
3 24
25th
26th
27 108
106
121
118

χ: The RE analysis concerns Nd, unless otherwise stated.

All test strips were heat-treated: T6 8 h 4 ₇ 0 ⁰ C. Cold water quenching. Hardened for 16 h at

T5 16 h 250 ° C.

250 ⁰ C

It can be seen from these results that the best results for solution-annealed and quenched and tempered alloys have been obtained with a zinc content of 6 to 7 % and a content of rare earth metals of 2 to 3% by weight. Alloy 24, containing 7.1 % zinc, showed signs of melting on solution heat treatment, indicating that the practical maximum zinc content for fully heat treated alloys is 7 % . Hardening without solution annealing again resulted in high yield stress and low elongation.

In order to check the quality of the castings, the alloys 8 to 27 determined radiographically, the ASTM relationship for 0.75 "thick Zr alloy plate was taken as a basis. The sponge porosity is given on a 0-8 scale and the results are in Table 5 shown.

-U table 5

709825/0810

- 14 table

alloy
No. X-ray determination (porosity) Worst rating Worst Area % Remarks comparison Area of action % 0 0 8th
9
10
11 0 4th
3
2
0 5
80
10
0 Rest estimated
2 - 3 12th
13th
14th
15th 95
100
70
0 1
3
3
2 10
10
20th
10 16
17th
18th 10
50
90
. 90 1
1
1 LA LA LA only near the gate
Il Il Il Il
Il Il Il Il 20th
21
22nd
23 LAUMA 1
0
0
0 LA O O O only near the gate 24
25th
26th
27 LA O O O T-T-OO LA LA O O
CM CM LA LA O O
CM CM

These results show that very low porosity is obtained at 6 to 7 % zinc and above 2 % rare earth metals.

The strength properties and the casting behavior of the alloys containing more than 3 % rare earths were also measured. The results are shown in Table 6.

- 16 Table 6

709825/0810

- 16 table

CD CO CO K>

alloy
No. composition RE *
060%
Nd) Zr
% Strength properties Breaking strength
ke i t N / mrn ^ strain
% Determination of the lack of casting defects Worst porosity
Degree 28
29
30th Zn
% 3-5
kO
kO 0.7
0.7
0.7 Stretch
border
N / mm ² 218
226
214 7th
11
6th % Area of action small amount
none
small amount 5-75
5.25
5-75 113
103
109 5
0
5

K) CT)

cn oo ^

Casting flawlessness was assessed by a "slope" casting method described in "Slope Casting Test Results on Some Established and Experimental Magnesium Casting Alloys", ¹ DJ Whitehead, "Light Metals" 1958, pp 391-395 cut off the lower end of the plate, rolled to 0.75 ", and examined radiographically.

It can be seen that good elongation values were maintained with high levels of rare earth metals. The yield strengths of alloys 28 to 30 were somewhat lower than the optimum because of the lower zinc content.

The alloys with a higher content of metals Seitener Soils exhibited improved castability.

In order to show the influence of neodymium additions with lower proportions, an alloy (31) was produced which contained about 4.5 % Zn, 1.2 % rare earth metals with at least 60 % neodymium and 0.74 % zirconium. In addition, a comparative alloy (32) was produced,

20 which contained about 4.3 % Zn, 1.1 % rare earth metals with a high proportion of cerium and 0.75 % zirconium. These alloys were cast and subjected to strength tests as before. The results are shown in Table 7.

- 18 Table 7

709825/0810

- 18 table

to do is>

alloy 31 % Elongation Hardness hand
H lung
° C Legi eration 32 % Elongation O. 1% stretch
border
(N / mm ² ) Tensile strength
speed
(N / mm ² ) 6th 16 200 0.1% stretch
border
(N / mm ² ) 4 1/2 129 225 5 16 250 109 4th 142 232 5 16 300 125 4th 137 231 6th 16 350 125 4 1/2 122 224 7th 16 400 116 5 105 216 10 16 450 102 6th 88 217 13th 16 500 86 8th 69 228 69 Tensile strength
ability -
(N / mm) 199 211 217 203 189 185 193

It can be seen that the neodymium-rich alloy has higher elongation and markedly better tensile strength yields as the cerium-rich alloy.

- 20 claims

709825/0810

Claims (11)

Claims 1. / Magnesium alloy, characterized in that it contains the following components in addition to impurities Magnesium is at least 80% by weight. Zinc 4-7% wt. Rare earth metals 1-5% by weight, the rare earth metals at least 60% by weight Contains neodymium and essentially no cerium or lanthanum. 2. Alloy according to claim 1, characterized in that it contains 1 - 3% rare earth metals. 3. Alloy according to claim 2, characterized in that it contains 5-7 % zinc and 1.5-3 % rare earth metals. 4. Alloy according to claim 3, characterized in that it contains 6-7 % zinc and 2-3 % rare earth metals. 5. Alloy according to one of claims 1 to 4, characterized in that the rare earth metals contain at least 75% neodymium. 6. Alloy according to one of Claims 1 to 5, characterized in that " it also contains up to 0.5 % copper. 709825/0810 -M- 7. Alloy according to one of claims 1 to 6, characterized in that it further contains up to 1 % zirconium. 8. Alloy according to one of claims 1 to 7, characterized in that it contains at least one of the following elements in the specified amounts Silver 0-81 Cadmium 0 - 5 % Lithium 0 - 6 % Calcium 0-1 Gallium 0-2 Indium - 0-2 Thallium 0-5 0 0 Lead 0 - 1 % Bismuth 0 - 1 % Thor 0-71 Iron 0 - 0.1% Beryllium 0 - 0.05 % Yttrium 0 - 5 % Manganese 0 - 2 % , the maximum contents of zirconium and manganese together are limited by their mutual solubility, if both are present. 9. A method for producing a casting from a magnesium alloy according to one of claims 1 to 8, characterized in that an object cast from the alloy is subjected to a tempering heat treatment at a temperature of 450 ⁰ C to the solidus temperature of the alloy, then quenched and at a Temperature is cured at which precipitation occurs. - 22 - 709825/0810 -GT- .3. 10. The method according to claim 9, characterized in that the object is quenched in water. 11. The method according to claim 9 or 10, characterized in that the object is solution annealed for about 8 hours at 480 ° C, quenched and cured for 16 hours at 250 ° C. 709825/0810