Heat resistant magnesium die casting alloys

TECHNICAL FIELD

The present invention relates to a heat resistant magnesium die casting alloy and a die cast product of that alloy.

BACKGROUND ART

In recent years, to deal with the demand for reduction of the weight of vehicles, greater application of alloys of magnesium, the lightest of the practical metals, has been desired. However, conventional die casting magnesium alloys greatly deform at high temperatures. Not much progress has been made for parts having bolted portions exposed to high temperature environments (120° C. or more). Up until now, various heat resistant magnesium die casting alloys have been developed, but it has not been possible to simultaneously improve the heat resistance (high temperature strength and creep resistance) and castability (hot-cracking resistance and die-sticking resistance during die casting) and therefore the range of application has been limited.

Therefore, to achieve both heat resistance and castability, JP-A-2001-316752 has proposed a die casting magnesium alloy comprised of 2 to 6 wt % Al, 0.3 to 2 wt % Ca, 0.01 to 1 wt % Sr, 0.1 to 1 wt % Mn, and the balance of Mg and unavoidable impurities. Due to this, it becomes possible to simultaneously improve the heat resistance and castability and expand the range of application.

Even with the magnesium alloy of the above proposal, however, it has not been possible to sufficiently cover the range of applications required, so development of a heat resistant magnesium die casting alloy with further improved combination of heat resistance and castability has been desired.

DISCLOSURE OF INVENTION

The present invention has as its object to provide a heat resistant magnesium die casting alloy simultaneously improved in heat resistance and castability and expanded in range of applications and a die cast product of the same alloy.

To achieve the above object, according to the present invention, there is provided a heat resistant magnesium die casting alloy comprising, by wt %, the following composition:

Al: over 6% to not more than 10%,

Ca: 1.8 to 5%,

Sr: 0.05 to 1.0%,

Mn: 0.1 to 0.6%, and

Bal: Mg and unavoidable impurities,

the ratio Ca/Al of the Ca content to the Al content being 0.3 to 0.5.

The present invention is characterized by limiting the ratio Ca/Al of the contents of Al and Ca to within a predetermined range so as to improve the combination of the heat resistance and castability over the conventional limits without causing deterioration of characteristics even if adding Al and Ca to high contents considered unsuitable in the past.

For example, JP-A-2001-316752 sets the upper limit of the Al content to 6 wt % and the upper limit of the Ca content to 2 wt %. The reason for the limitations is explained as being that if the Al content is over 6 wt %, the creep resistance rapidly deteriorates, while if the Ca content exceeds 2 wt %, casting cracks easily occur (see paragraph 0010 to 0012 of the publication).

As opposed to this, the inventors newly discovered that by limiting the ratio Ca/Al of the Ca content to the Al content to the range of 0.3 to 0.5, even if adding Al and Ca exceeding the upper limits of the above publication, it is possible to simultaneously achieve an improvement of the high temperature strength and castability, which are the main effects of high Al, and an improvement of the creep resistance, which is the main effect of high Ca, without causing either a drop in the creep resistance due to the higher Al or casting cracks due to the higher Ca. The present invention was completed based on this novel discovery.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a graph comparing the retained bolt loads of various types of Mg alloys.

FIG. 2 is a graph of the relationship between the high temperature retained bolt load and Ca/Al ratio.

FIG. 3 is a graph of the relationship between the casting crack length and Ca/Al ratio.

FIGS. 4A and 4B are graphs of the (A) change in corrosion weight loss and (B) change in corrosion rate with respect to the test duration of a salt water spray test for Mg alloys with various RE contents.

FIG. 5 is a graph of the change in the corrosion rate with respect to the RE content for specific test durations (numbers of days).

FIGS. 6A and 6B are graphs of the (A) 0.2% proof stress and tensile strength and the (B) elongation in the temperature range of room temperature to 250° C.

FIG. 7 is a graph comparing the high temperature retained bolt loads of a 0.44% RE material and no-addition material among the alloys of the present invention and comparing them with the conventional use alloy AZ91D.

BEST MODE FOR CARRYING OUT THE INVENTION

The composition of the heat resistant magnesium die casting alloy of the present invention is limited due to the following reasons. Note that in this description, unless otherwise specified, the “%” in the indications of the content of the components mean “wt %”.

[Al: Over 6% to not More than 10%]

Al raises the strength at room temperature and high temperature by dispersion strengthening (in particular grain boundary strengthening) by forming Al—Ca-based, Al—Sr-based, and Mg—Al-based intermetallic compounds. Further, it lowers the melting point (liquidus line) of the alloy to raise the fluidity of the melt and improve the castability. In the present invention, by including Al over 6% under a predetermined range of Ca/Al ratio, it is possible to increase the room temperature and high temperature strength over the conventional limit and secure a good castability. However, even if limiting the Ca/Al ratio to within the predetermined range of the present invention, if Al is present in excess, the creep resistance (high temperature retained bolt load) drops, so the upper limit of the Al content is made 10%.

[Ca: 1.8 to 5%]

Ca improves the proof strength at room temperature and high temperature by grain boundary strengthening by Al—Ca-based intermetallic compounds and simultaneously particularly raises the creep resistance (high temperature retained bolt load). In the present invention, by making the Ca content 1.8% to 5% under a predetermined range of the Ca/Al ratio, it is possible to improve the proof strength and creep resistance over the conventional limits in the copresence with Al. However, even if limiting the Ca/Al ratio to a predetermined range of the present invention, if Ca is presence in excess, hot-cracking and die-sticking easily occur during die casting, so the upper limit of the Ca content is made 5%. The Ca content is preferably over 2% and not more than 5%, more preferably 2.5 to 3.5%.

[Ratio Ca/Al of Ca Content to Al Content: 0.3 to 0.5]

In the present invention, by limiting the Ca/Al ratio to this range, it becomes possible to increase the Al content and Ca content over the conventional limits without causing a drop in the creep resistance due to the higher Al or a deterioration of the castability due to the higher Ca and therefore possible to further raise the high temperature strength and creep resistance over the past and secure a good castability. To stably secure a high creep resistance, it is necessary to make the Ca/Al ratio at least 0.3. To stably suppress the occurrence of hot-cracking during die casting, it is necessary to make the Ca/Al ratio not more than 0.5.

[Sr: 0.05 to 1.0%]

Sr is added to further improve the effect of prevention of casting cracks and securing creep resistance. To obtain this effect, it is necessary to add Sr to at least 0.05%. The effect becomes greater with increasing the amount of addition. However, even if added over 1.0%, the effect does not increase not much at all.

[Mn: 0.1 to 0.6%]

Mn is added to secure a good corrosion resistance. To obtain this effect, it is necessary to make the Mn content at least 0.1%. However, if Mn is present in excess, free Mn precipitates and embrittlement occurs, so the upper limit of the Mn content is made 0.6%.

The magnesium alloy of the present invention is remarkably improved in corrosion resistance by further adding a rare earth metal (RE) to the above composition in the range of 0.1 to 3%. To realize this effect, it is necessary to make the RE content at least 0.1%. However, if the RE content exceeds 3%, the castability rapidly deteriorates, casting cracks and misruns end up occurring, and a sound casting is not obtained, so the upper limit of the RE content is made 3%.

The heat resistant magnesium alloy of the present invention is particularly limited to one for die casting. By die casting, a fine network comprised of Al—Ca-based or Al—Sr-based intermetallic compounds is formed and a good heat resistance can be secured.

The basic process for obtaining a product by applying the alloy of the present invention to die casting is as follows:

Alloy metal→charging into crucible (*1)→melting→temperature adjustment→die casting (*2)→removal of product

*1) The crucible used is made of iron.

*2) The die casting is by a cold chamber, hot chamber, etc.

The die casting heat resistance magnesium alloy of the present invention is particularly advantageous when applied to parts requiring heat resistance such as parts of automobile engines, in particular, oil pans, headlight covers, etc. and also transmission cases.

EXAMPLES
Example 1

The following experiment was performed to confirm the effect of improvement of the castability and heat resistance by alloy compositions of the present invention.

Mg alloys of the compositions of Table 1 were die cast under the following conditions using a 135 ton cold chamber die casting machine.

Shape and dimensions of die: 70 w×150 L (3, 2, and 1 t from gate side) . . . flat plate

- 15φ×120 L . . . rod

Die preheating: 200° C.

Casting temperature: 700 to 720° C.

Casting atmosphere: 1% SF₆+CO₂

The obtained alloy samples were subjected to tensile tests (test temperature: room temperature (RT), 150° C.) and measured for crack length at casting and bolt load retention. As the bolt load retention, the retained bolt load was measured under the following conditions. The measurement results are shown all together in Table 2 and Table 3.

Initial bolt load: 8 kN

Holding temperature: 150° C.

Holding time: 300 h

Retained rate: bolt load before and after holding at a high temperature measured at room temperature and calculated as retained bolt load

Further, FIG. 1 is a graph showing the high temperature retained bolt loads of different alloy samples, FIG. 2 the relationship between the high temperature retained bolt load and Ca/Al ratio, and FIG. 3 the relationship between the casting crack length and Ca/Al ratio.

In particular, from the results of FIG. 2, it is clear that the retained bolt load increases with increasing the Ca/Al ratio and that to secure the practically required retained bolt load of at least 70%, it is necessary that Ca/Al ratio≧0.3.

From the results of FIG. 3, it is clear that the casting crack length increases along with an increase in the Ca/Al ratio and that to secure the actually required crack length of not more than 600 mm, it is necessary that Ca/Al ratio≦0.5.

From the above results, it is clear that only when the contents of the components are in the range of the present invention and the Ca/Al ratio is in the range of the present invention can the strength (room temperature and high temperature) and creep resistance (high temperature retained bolt load) be improved while stably suppressing casting cracking.

TABLE 1Analysis values (wt %)No.NameAlCaSrMnCa/Al1M3101013.031.010.110.110.332M3102032.950.960.220.310.333M3105063.161.020.510.620.324M3201033.102.040.130.300.665M3202063.242.060.230.640.646M3205013.091.990.500.110.647M3301063.302.870.120.640.878M3302013.103.090.220.121.009M3305033.183.130.540.310.9810M5102065.191.040.110.310.2011M5105015.311.040.250.640.2012M5105015.131.020.520.110.2013M5201065.342.060.110.620.3914M5202014.992.050.220.100.4115M5205035.122.090.540.330.4116M5301015.263.220.120.130.6117M5302035.003.030.220.320.6118M5305065.323.110.540.630.5819M7101067.281.060.120.580.1520M7102017.161.100.230.130.1521M7105037.081.090.510.330.1522M7201017.221.980.120.120.2723M7202036.992.060.230.290.2924M7205067.332.100.540.570.2925M7301036.983.080.120.290.4426M7302067.323.080.220.580.4227M7305017.193.130.520.110.44

TABLE 2

Proof strength

Tensile strength

(MPa)

(MPa)

No.
RT
150
RT
150

1
133
118
195
144

2
119
115
196
145

3
143
127
198
169

4
165
134
186
170

5
164
137
204
176

6
166
133
187
161

7
166
148
203
179

8
183
145
217
177

9
193
154
200
170

10
199
129
209
162

11
146
133
234
173

12
148
127
220
169

13
155
142
227
182

14
156
135
188
172

15
165
143
207
175

16
177
149
206
195

17
172
146
218
186

18
181
154
215
198

19
160
132
244
178

20
158
133
232
179

21
160
136
234
178

22
174
145
230
189

23
166
146
229
182

24
174
148
217
190

25
176
152
234
197

26
173
156
236
203

27
177
155
231
204

TABLE 3

Crack
Retained

length
rate after

No.
(mm)
300 h (%)

1
2770
55.90

2
3500
61.90

3
2310
63.43

4
2614
70.36

5
1174
70.26

6
1694
79.79

7
792
74.79

8
1852
81.62

9
3098
77.59

10
514
52.73

11
386
48.39

12
544
62.13

13
512
67.71

14
558
78.26

15
346
81.70

16
744
80.69

17
1020
77.39

18
842
80.16

19
0
15.70

20
10
21.43

21
8
30.42

22
300
62.34

23
548
61.38

24
314
68.00

25
456
79.83

26
134
81.61

27
230
88.89

Example 2

The following experiment was performed to confirm the effect of improvement of the corrosion resistance by RE addition in the alloy composition of the present invention.

The Mg alloys of the compositions of Table 4 were die cast in the same way as in Example 1. The alloy compositions of No. 101 to 105 shown in Table 4 were basically comprised (target values) of 7% Al-3% Ca-0.5% Sr-0.3% Mn with amounts of RE added (target values) of successively 0% (no addition), 0.1%, 0.5%, 2.0%, and 3.0% (analysis values of added RE elements of 0.08%, 0.44%, 1.77%, and 2.68%). For the RE addition, a Ce-rich (50%) misch metal was used.

The obtained alloy samples were subjected to salt water spray tests under the following conditions to evaluate the corrosion resistance.

1. Cut out test piece (width 70 mm×length 50 mm×thickness 3 mm) from the die cast product in the as-cast state.

2. Immerse the test piece in acetone and ultrasonically clean it for 15 minutes, then measure its weight (initial weight).

3. Mask the parts of the surface of the test piece finished being measured for weight other than the as-cast surface (test surface).

4. Perform the salt spray test by a 5% NaCl aqueous solution under conditions defined in JIS Z2371.

5. After the end of the test, boil and clean the test piece by a 15% chromic acid aqueous solution for 1 minute so as to remove the corrosion product on the surface of the test piece.

6. Dry, then measure the weight of the test piece and use the difference from the initial weight as the corrosion weight loss. Further, divide the value of the corrosion weight loss by the test area and the number of test days and use the result as the corrosion rate.

FIG. 4A and FIG. 4B show changes in the corrosion weight loss and corrosion rate for different test durations (numbers of days). Compared with the no-RE material 101, the RE-added materials 102 to 105 all had small corrosion weight losses and small corrosion rates. At FIG. 4A showing the change along with time of the corrosion weight loss, the curves are convex upward. In FIG. 4B converting this to the change along with time of the corrosion rate, the curves are convex downward. Along with the elapse of the test duration, there is a tendency for the corrosion to proceed slower.

FIG. 5 is a graph of the effects of the RE content on the progression of corrosion. The corrosion rate was plotted against the RE content for a test duration of one day and 10 days. At both test durations, the corrosion rate clearly decreases by the addition of 0.08% of RE as compared with no RE (0%). With increasing the amount of addition of 0.44% and 1.77%, the corrosion rate further decreases. However, if increasing the amount of addition to 2.68%, the corrosion rate conversely starts to increase, but even so the corrosion rate is far smaller than with no addition. By adding RE in a range of 0.1% to 3% according to the present invention, it is learned that the corrosion resistance is remarkably improved compared with no addition.

Next, the effects of the addition of RE on the strength properties and creep resistance properties were investigated.

As a typical composition of the RE-added material, a 0.44%-added material (103) was compared with the non-addition material (101). FIGS. 6A and 6B show the (A) 0.2% proof strength and tensile strength and (B) elongation at the test temperature from room temperature to 250° C. At all test temperatures, it was learned that the 0.44% RE material (♦ plot) was provided with similar strength characteristics to the non-addition material (o plot).

FIG. 7 compares the high temperature retained bolt loads of a 0.44% RE material (103), a non-addition material (101), and an AZ91D (typical known heat resistant Mg die casting alloy). The test procedure was the same as that in Example 1.

First, it is learned that the alloy of the present invention is far larger in retained bolt load compared with the conventional use alloy AZ91D regardless of the addition of RE.

Further, in the alloys of the present invention, the 0.44% RE material (103) fell in retained bolt load by about 10% compared with the non-addition material (101), but sufficiently secured the practically required at least 70%, so was provided with both the practically sufficient heat resistance and corrosion resistance. Simultaneously, an excellent castability was also provided and it was possible to die cast without any problem.

TABLE 4Analysis values (wt %)Basic alloy componentsRare earth metalNo.NameAlCaSrMnTotalCeLaNdCa/Al101M7305037.082.860.500.3100000.40102M730503016.753.240.540.160.080.040.030.010.48103M730503056.832.850.500.260.440.220.130.090.42104M730503206.852.890.480.251.770.910.550.310.42105M730503307.132.930.500.342.681.330.780.570.41

INDUSTRIAL APPLICABILITY

According to the present invention, a heat resistant magnesium die casting alloy simultaneously improved in heat resistance and castability and able to be used for a wider range of applications than the past is provided.

Further, due to the RE addition, in addition to the heat resistance and castability, the corrosion resistance may also be simultaneously improved.

Number	Date	Country	Kind
2003-326563	Sep 2003	JP	national
2004-150393	May 2004	JP	national

Heat resistant magnesium die casting alloys

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