US1959913A - Magnesium base forging alloy - Google Patents
Magnesium base forging alloy Download PDFInfo
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- US1959913A US1959913A US589762A US58976232A US1959913A US 1959913 A US1959913 A US 1959913A US 589762 A US589762 A US 589762A US 58976232 A US58976232 A US 58976232A US 1959913 A US1959913 A US 1959913A
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- manganese
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C23/00—Alloys based on magnesium
Definitions
- the present invention relates to improved magnesium base alloys containing aluminum and manganese.
- One object of our invention is to produce magnesium base alloys which contain both aluminum and manganese that are capable of being readily forged. Other objects andadvantages will appear as the description proceeds.
- the magnesium base 'alloys containing from 3 to 15 per cent aluminum and manganese in amount usually from 0.1 to 0.5 per cent have a good degree of resistance to corrosion and are among the strongest of the known alloys possessing the characteristic lightness and other valuable properties of the magnesium alloys, but they are difficult to forge or otherwise plastically work satisfactorily. So far as we are aware no one has investigated the possibility of improving the plastic workability of these alloys otherwise highly satisfactory as among the lightest of the com.- flashal structural metals.
- edge cracking is much less pronounced in forgings made by the slow method of pressing the metal between dies than by the more rapid method of hammer forging under similar conditions such as working temperature and amount of reduction in cross sectional area per working operation for a given alloy.
- Even in such cases there is the possibility for the existence of minute cracks in the forging which are not evident by a simple visual inspection.
- the alloys which form the subject of our inventiun,.then contain the four metals consisting of magnesium, aluminum, manganese, and one of the metals of the group cadmium, silicon, and zinc.
- the magnesium content coming within the scope of our invention is in excess of 90 per cent, that of aluminum is between 0.5 and 3.0 per cent, that of manganese is between 0.2 and 1.0 per cent, while the amount of the fourth con- ,stituent, e. g. cadmium. silicon, or zinc, may be .at least 0.2 per cent, but not more than 6.0 per cent.
- the preferred quantity of aluminum to employ will vary with the use to which the alloy is to be put. The higher the aluminum content the less the forgeability, while the tensile strength and other mechanical properties will be increased somewhat, so that the aluminum content within the limits given is to be governed by the choice between maximum forgeability and the highest mechanical properties to suit the particular application of the alloy. Usually about 2 per cent aluminum will meet most requirements.
- the manganese content effective to modify the properties of these alloys is limited by theamount thereof which can exist in the alloys in solid so lution, andapproximately the maximum quantity .of manganese which can be dissolved in the alloys is preferably used.
- This saturating quantity of manganese decreases with increase in the aluminum content. since the latter reduces the solubility of manganese in the alloys.
- the active quantity of manganese varies from about 0.5 to 1.0 per cent as the aluminum content varies from 3 to 0.5 per cent, respectively, these amounts being in accordance with the solubility of the same in magnesium alloys containing aluminum. Silicon also reduces the solubility of manganese in magnesium and therefore somewhat less manganese can be retained in solid solution as the silicon content is increased.
- the cadmium, zinc, and silicon content of the present alloys greatly improves the forgeability and mechanical properties thereof.
- the preferred quantities to employ between the limits stated above are from 0.5 to 2.0 per cent of cad mium or about 0.5 to 1.0 per cent of zinc or of silicon, in order to secure maximum forgeability.
- the improved forgeability of our new alloys may be shown by comparing their forgeability with that of the known magnesium-aluminummanganese alloys.
- comparative forgeability we employ a simple system of visual inspection in which numerical values are assigned to the forged alloy samples, such numbers being based upon the relative amount of cracking which occurs during the forging operation or upon the entire absence of any cracking.
- Forgings showing entire absence of cracking are rated 100; those showing very slight cracking, either on being press for ed or hammer forged with heavy blows, are rated 80; slight, but readily noticeable cracking by press forging or by heavy blows from the hammer, are rated 60; slight cracking by medium hammer blows are rated 40; bad cracking with medium blows or pressing are rated 20; while bad cracking with the press or light blows from the hammer are rated 0.
- a number of samples of each of the alloys were forged and in each case a forgeability number was assigned and an average value of the several determinations for each alloy composition was obtained, representing its forgeability.
- alloys may be mechanically deformed in any of the usual ways, such as by hammer or press forging, rolling, extruding, etc., without cracking or otherwise fracturing the metal at temperatures from 750 to 900 F., or even at slightly higher or lower temperatures.
- the temperature range for working should be controlled within narrower limits and adapted to the quantity of the alloying metals present. For example, alloys containing approximately 2 per cent aluminum and 0.5 per cent manganese with either approximately 2 per cent of cadmium or 0.5 per cent 'zinc and thebalance magnesium, are best forged or otherwise plastically worked at a temperature near 800 F.
- Heat treatment according to the methods known to those skilled in the art of treating magnesium alloys may be practiced with these improved alloys but it is not necessary to apply the heat treatment before the forging operations.
- the cooling of the worked article may be artificially retarded or otherwise maintained at a suitable temperature to give a precipitation 'heat treatment to the alloys containing alloying metal in greater amount than corresponds to saturation at lower temperatures, or to redissolve metal not in solid solution in the alloy as forged.
- alloys may be prepared in any convenient manner by employing any of the well known metallurgical methods of melting and alloying magnesium and following this they may be cast,
- a magnesium base alloy consisting of magnesium in amount from to 99 per cent, aluminum from 0.5 to 3.0 per cent, manganese from 1.0 to 0.2 per cent, and from 0.2 to 6.0 per cent of at least one of the metals cadmium, silicon.
- a magnesium base alloy consisting of magnesium in amount from 90 to 98.5 per cent, aluminum from 0.5 to 3.0 per cent, manganese from 1.0 to 0.5 per cent, and from 0.5 to 6.0 per cent of cadmium.
- a magnesium base alloy consisting of from 0.5 to 3.0 per cent of aluminum, from 0.5 to 1.0
- a magnesium base alloy consisting of approximately 95.5 per cent of magnesium, 2 per cent aluminum, 0.5 per cent manganese and 2.0 per cent cadmium.
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- Chemical & Material Sciences (AREA)
- Engineering & Computer Science (AREA)
- Materials Engineering (AREA)
- Mechanical Engineering (AREA)
- Metallurgy (AREA)
- Organic Chemistry (AREA)
- Forging (AREA)
Description
Patented May 22, 1934 MAGNESIUM BASE FORGING ALLOY John A. G'ann, Fred-L. Reynolds and Arthur W. Winston, Midland, Mich., assignors to The Dow Chemical Company, Midland, Mich., a corporation of Michigan No Drawing. Application January 29, 1932, Serial No. 589,762
6 Claims.
The present invention relates to improved magnesium base alloys containing aluminum and manganese. One object of our invention is to produce magnesium base alloys which contain both aluminum and manganese that are capable of being readily forged. Other objects andadvantages will appear as the description proceeds.
The magnesium base 'alloys containing from 3 to 15 per cent aluminum and manganese in amount usually from 0.1 to 0.5 per cent have a good degree of resistance to corrosion and are among the strongest of the known alloys possessing the characteristic lightness and other valuable properties of the magnesium alloys, but they are difficult to forge or otherwise plastically work satisfactorily. So far as we are aware no one has investigated the possibility of improving the plastic workability of these alloys otherwise highly satisfactory as among the lightest of the com.- mercial structural metals.
Heretofore when it has been attempted to shape the above-mentioned magnesium alloys containing aluminum and small amounts of manganese by forging, rolling, or by similar methods, particularly hammer forging, flaws tend to develop in the article being forged. These flaws usually appear in the form of cracks which are especially noticeable at the outermost portions of the metal mass, such as the edges, where they may open up making voids of considerable size. The only known procedure employed at present to minimize this flaw formation has been to control the speed of working and the amount of working between heatings. For example, edge cracking is much less pronounced in forgings made by the slow method of pressing the metal between dies than by the more rapid method of hammer forging under similar conditions such as working temperature and amount of reduction in cross sectional area per working operation for a given alloy. In order to obtain a forging free from edge cracking, it has been necessary in the past to use a somewhat larger piece of metal than is required by the size of the forging desired and, after forging to shape, the outer portions which involve cracked or otherwise spoilt metal are removed by machining or otherwise. Even in such cases there is the possibility for the existence of minute cracks in the forging which are not evident by a simple visual inspection. These difliculties are encountered even when particular care is used in most suitably controlling the temperature of the metal and the working rate during the deformation operation.v
In the following description we have employed the term "forgeability to define the capacity of the alloys for plastic deformation by pressure,
which may be applied not only by hammering,-.
but also by other means such as slow pressing between dies in an hydraulic press, by the rolls of a rolling mill or by any means in which a change in cross sectional area is brought about by applying pressure.
We have found that the comparative lack of forgeability of the alloys mentioned above is dependent upon the quantity of aluminum present as well as upon that of manganese and that the presence of manganese, while valuable as a means to increase the resistance of the alloys to corrosion and to increase the yield point, has at the same time a disadvantageous tendency to de-- crease the forgeability, especially at fast working rates, such as the comparatively high rate of working when the forging is carried out by means of hammer blows. We have further discovered that these disadvantages can be overcome by suitably regulating the quantity of aluminum employed to less than 3 per cent if there is added at the same time a small quantity of one of the metals cadmium, silicon, or zinc. In this manher, we are enabled to retain the valuable properties conferred upon the alloys by manganese and aluminum as well as to produce alloys with as good mechanical properties as the corresponding known magnesium-aluminum-manganese alloys, but which possess a combination of mechanical properties, together with a degree of forgeability and resistance to corrosion, hitherto unknown in the art of producing magnesium alloys.
The alloys which form the subject of our inventiun,.then, contain the four metals consisting of magnesium, aluminum, manganese, and one of the metals of the group cadmium, silicon, and zinc. The magnesium content coming within the scope of our invention is in excess of 90 per cent, that of aluminum is between 0.5 and 3.0 per cent, that of manganese is between 0.2 and 1.0 per cent, while the amount of the fourth con- ,stituent, e. g. cadmium. silicon, or zinc, may be .at least 0.2 per cent, but not more than 6.0 per cent.
The preferred quantity of aluminum to employ will vary with the use to which the alloy is to be put. The higher the aluminum content the less the forgeability, while the tensile strength and other mechanical properties will be increased somewhat, so that the aluminum content within the limits given is to be governed by the choice between maximum forgeability and the highest mechanical properties to suit the particular application of the alloy. Usually about 2 per cent aluminum will meet most requirements.
The manganese content effective to modify the properties of these alloys is limited by theamount thereof which can exist in the alloys in solid so lution, andapproximately the maximum quantity .of manganese which can be dissolved in the alloys is preferably used. This saturating quantity of manganese decreases with increase in the aluminum content. since the latter reduces the solubility of manganese in the alloys. The active quantity of manganese varies from about 0.5 to 1.0 per cent as the aluminum content varies from 3 to 0.5 per cent, respectively, these amounts being in accordance with the solubility of the same in magnesium alloys containing aluminum. Silicon also reduces the solubility of manganese in magnesium and therefore somewhat less manganese can be retained in solid solution as the silicon content is increased.
The cadmium, zinc, and silicon content of the present alloys greatly improves the forgeability and mechanical properties thereof. The preferred quantities to employ between the limits stated above are from 0.5 to 2.0 per cent of cad mium or about 0.5 to 1.0 per cent of zinc or of silicon, in order to secure maximum forgeability.
The improved forgeability of our new alloys may be shown by comparing their forgeability with that of the known magnesium-aluminummanganese alloys. In order to set forth the comparative forgeability we employ a simple system of visual inspection in which numerical values are assigned to the forged alloy samples, such numbers being based upon the relative amount of cracking which occurs during the forging operation or upon the entire absence of any cracking. Forgings showing entire absence of cracking are rated 100; those showing very slight cracking, either on being press for ed or hammer forged with heavy blows, are rated 80; slight, but readily noticeable cracking by press forging or by heavy blows from the hammer, are rated 60; slight cracking by medium hammer blows are rated 40; bad cracking with medium blows or pressing are rated 20; while bad cracking with the press or light blows from the hammer are rated 0. A number of samples of each of the alloys were forged and in each case a forgeability number was assigned and an average value of the several determinations for each alloy composition was obtained, representing its forgeability.
In the examples given below showing the comparative forgeability, all the forgings were made from the same size of extruded stock under approximately the same conditions of temperature, and the reduction in area by forging was the same in every case. The hammer forging was started with light blows from a steam hammer and continued with heavier blows. The starting blows were delivered at the rate of about 90 per minutes-and the rest of the blows at about 150 per minute. The forging was completed in about 22 seconds. The press forging was carried out by pressing the sample between dies brought together in an hydraulic press at such a rate that the forging was completed in about 30 seconds.
Examples showing forgeability and properties of binary magnesium-aluminum alloys are given in Table I below wherein the forgeability is rated according to the system just described.
Table I Forgeability of the binary Mg-Al alloys Composition percent Al 1n alloy (balance Mg) Tensile Yield point Forge/w strength lbs Is in bility lbs/sq. in. number Thus it is seen that a small percentage of aluminum in magnesium produces a readily forgeable alloy but the forgeability tends to decrease as the aluminum content increases. If to these alloys manganese is now added to form the magnesiumaluminum-manganese ternary alloys having low percentages of aluminum and manganese, the forgeability is materially decreased in spite of the valuable increase in yield point and corrosion resistance imparted by the manganese. This increased yield point and decreased forgeability is shown by the examples in the following Table 111- Table II Forgeability oi the ternary MgAl-Mn alloys Composition 05.5-07.5 Mg,
about 0.5 Mn, and Alas T 1 F e ow ensi e i orgestrength '{ggg 1 5 ability lbs/sq. in. number Examples of the forgeability and properties of our improved quaternary magnesium alloys are given in the following Table III:-
Table I II Forgeability of the quaternary Mg alloys Approxiniate colhnpfsition T l 1 F a ance g ensi e orgestrength fag l ability' lbs/sq. in. number Percent A1 2.0 Mn 05 35,000 21, 000 100 Cd from 0.5 to 2.0..
Thus it is evident that in spite ofthe presence of manganese the foregability has been increased by the addition of cadmium, silicon, or zinc to the magnesium-aluminum-manganese alloys in accordance with our invention and at the same time the increased yield'point and resistance to corrosion due to manganese has been retained.
These alloys may be mechanically deformed in any of the usual ways, such as by hammer or press forging, rolling, extruding, etc., without cracking or otherwise fracturing the metal at temperatures from 750 to 900 F., or even at slightly higher or lower temperatures. When it is desired. to secure a maximum improvement in tensile strength and other properties, the temperature range for working should be controlled within narrower limits and adapted to the quantity of the alloying metals present. For example, alloys containing approximately 2 per cent aluminum and 0.5 per cent manganese with either approximately 2 per cent of cadmium or 0.5 per cent 'zinc and thebalance magnesium, are best forged or otherwise plastically worked at a temperature near 800 F. Similar working temperatures are suitable for the alloys with about 0.5 to 1.0 per varies also with the amount of reduction in cross sectional area of the metal. Usually a reduction in area of about 90 per cent of the original area considered brings about as great an improvement in properties as it is possible to attain, other factors being equal.
Heat treatment according to the methods known to those skilled in the art of treating magnesium alloys may be practiced with these improved alloys but it is not necessary to apply the heat treatment before the forging operations. Following plastic deformation, the cooling of the worked article may be artificially retarded or otherwise maintained at a suitable temperature to give a precipitation 'heat treatment to the alloys containing alloying metal in greater amount than corresponds to saturation at lower temperatures, or to redissolve metal not in solid solution in the alloy as forged.
These alloys may be prepared in any convenient manner by employing any of the well known metallurgical methods of melting and alloying magnesium and following this they may be cast,
' extruded, or otherwise brought into suitable forms for plastic working.
Other modes of applying the principle of our invention may be employed instead of the one explained, change being made as regards the proportions of the ingredients employed within the limits specified, provided the ingredients stated by any of the following claims or the equivalent of such stated ingredients be employed.
We therefore particularly point out and distinctly claim as our invention:---
1. A magnesium base alloy consisting of magnesium in amount from to 99 per cent, aluminum from 0.5 to 3.0 per cent, manganese from 1.0 to 0.2 per cent, and from 0.2 to 6.0 per cent of at least one of the metals cadmium, silicon.
2. A magnesium base alloy consisting of magnesium in amount from 90 to 98.5 per cent, aluminum from 0.5 to 3.0 per cent, manganese from 1.0 to 0.5 per cent, and from 0.5 to 6.0 per cent of cadmium.
3. A magnesium base alloy consisting of from 0.5 to 3.0 per cent of aluminum, from 0.5 to 1.0
per cent of manganese, and from 0.5 to 2.0 per cent of silicon, the balance being magnesium.
4. A magnesium base alloy consisting of approximately 95.5 per cent of magnesium, 2 per cent aluminum, 0.5 per cent manganese and 2.0 per cent cadmium.
5. A magnesium base alloyconsisting of ap-.
JOHN A. GANN. FRED L. REYNOLDS. ARTHUR W. WINSTON.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US589762A US1959913A (en) | 1932-01-29 | 1932-01-29 | Magnesium base forging alloy |
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US589762A US1959913A (en) | 1932-01-29 | 1932-01-29 | Magnesium base forging alloy |
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2575273A (en) * | 1947-12-05 | 1951-11-13 | Bendix Aviat Corp | Process for producing a magnesium die-casting alloy |
US2671039A (en) * | 1946-05-02 | 1954-03-02 | Bendix Aviat Corp | Magnesium die casting alloy and process |
US3162552A (en) * | 1961-06-02 | 1964-12-22 | Dow Chemical Co | Magnesium-base extrusion alloy |
US3630726A (en) * | 1968-06-26 | 1971-12-28 | Magnesium Elektron Ltd | Magnesium base alloys |
US3718460A (en) * | 1970-06-05 | 1973-02-27 | Dow Chemical Co | Mg-Al-Si ALLOY |
WO2004005564A1 (en) * | 2002-07-05 | 2004-01-15 | Daimlerchrysler Ag | Am-magnesium pressure die cast alloy and method for producing an interior fitting from an am-magnesium pressure die cast alloy |
US20050238524A1 (en) * | 2002-07-05 | 2005-10-27 | Andreas Barth | As-magnesium pressure die cast alloy and method for producing a subassembly part from an as-magnesium pressure die cast alloy of this type |
-
1932
- 1932-01-29 US US589762A patent/US1959913A/en not_active Expired - Lifetime
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2671039A (en) * | 1946-05-02 | 1954-03-02 | Bendix Aviat Corp | Magnesium die casting alloy and process |
US2575273A (en) * | 1947-12-05 | 1951-11-13 | Bendix Aviat Corp | Process for producing a magnesium die-casting alloy |
US3162552A (en) * | 1961-06-02 | 1964-12-22 | Dow Chemical Co | Magnesium-base extrusion alloy |
US3630726A (en) * | 1968-06-26 | 1971-12-28 | Magnesium Elektron Ltd | Magnesium base alloys |
US3718460A (en) * | 1970-06-05 | 1973-02-27 | Dow Chemical Co | Mg-Al-Si ALLOY |
WO2004005564A1 (en) * | 2002-07-05 | 2004-01-15 | Daimlerchrysler Ag | Am-magnesium pressure die cast alloy and method for producing an interior fitting from an am-magnesium pressure die cast alloy |
DE10230275A1 (en) * | 2002-07-05 | 2004-01-22 | Daimlerchrysler Ag | AM die casting alloy and method of making an interior seal from such an AM die cast alloy |
US20050238524A1 (en) * | 2002-07-05 | 2005-10-27 | Andreas Barth | As-magnesium pressure die cast alloy and method for producing a subassembly part from an as-magnesium pressure die cast alloy of this type |
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