US2357449A - Aluminum alloy - Google Patents
Aluminum alloy Download PDFInfo
- Publication number
- US2357449A US2357449A US366453A US36645340A US2357449A US 2357449 A US2357449 A US 2357449A US 366453 A US366453 A US 366453A US 36645340 A US36645340 A US 36645340A US 2357449 A US2357449 A US 2357449A
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- Prior art keywords
- alloy
- iron
- manganese
- silicon
- aluminum
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C21/00—Alloys based on aluminium
- C22C21/02—Alloys based on aluminium with silicon as the next major constituent
Definitions
- This invention relates to alloys, and more particularly to machinable aluminum base alloys having low thermal expansion and relatively high wear resistance.
- Aluminum alloys having relatively low thermal expansion, together with relatively high strength and hardness, and, retaining these properties after exposure to prolonged high temperatures, are especially desirable for the manufacture of castings, such as pistons or other parts, for use in internal combustion engines and the like.
- Aluminum-silicon alloys containing suitable amounts of manganese and magnesium have been used in the production of pistons and the like.
- machinability and fatigue resistance are decreased substantially as the percentage of silicon is increased and, therefore, about to silicon is the amount ordinarily used in these alloys, although still greater wear resistance and still lower expansion are sometimes desirable.
- an aluminum base alloy by properly proportioning silicon, magnesium, manganese, iron and copper in the alloy.
- My improved alloy has about or 21% to silicon, .2% to 3% magnesium, .3% to 2% manganese, .4% to 2.5% iron, and 1% to 5% copper, with the balance substantially aluminum which may contain small amounts of minor impurities.
- the alloy may contain some boron or titanium, or other known grain refiner, if de-.
- Silicon is preferably present in the amount of 22% to 26% of the alloy, and increases the hardness and wear resistance of the alloy and decreases the thermal expansion. Silicon in such large proportions, without suitable quantities of the other above mentioned constituents, however, has the tendency to crystallize into relatively large crystals and to decrease machin ability.
- Iron and manganese tend to further harden the alloy and decrease the thermal expansion. These elements also increase the machinability and are beneficial, in that they tend to stabilize the alloy so that itsproperties are maintained at relatively high temperatures, such as encountered in internal combustion engines. The iron and manganese appear to perform substantially the same functions, aiding in themachinability and maintaining the properties of the metal athigh temperatures.
- Iron like silicon, has the property of tending to crystallize in relatively large crystals, but manganese has the additional property of tending to inhibit the growth of large iron crystals. Consequently, it is desirable to have manganese present, even though there, be present a relatively large quantity of iron. With an iron content of 2% or 2.5%, a smaller amount of manganese may be used to obtain the same properties as when a smaller'amount of iron, such as .7% to 1% or 1.5%, be present. Preferably, the amount of iron in the, alloy is about .7% to 1.5%-
- the manganese may be present in an amount ranging from .3% to 3%, and when a substantial amount of iron is present the preferred amount of manganese is from .6% to 1% of the alloy.
- Magnesium as well as improving the hardness and tensile strength of aluminum-silicon alloys increases the elastic properties of the alloy.
- magnesium is presentin the alloy in the amount of .5% to 1% or 1.5%, although. as much as 3% is sometimes desirable.
- the magnesium and also the copper are beneficial in improving the machinability of the alloy, but the copper additionally aids in increasing the fatigue strength.
- the preferred amount of copper is 1.5% to 3%.
- An alloy illustrating the present invention and desirable for the making of pistons contains about 21% to 25% silicon, about 4% to .8% magnesium, about '.6% to 1% manganese, about .7% to 1.5% iron, about 1.5% to'2.5% copper, with the balance commercial aluminum and a small amount of titanium, boron, or other grain refiner, if desired.
- This alloy may be readily square inch, and a Brinell hardness 2 8,867,449 machined withtools now available.
- the alloy has Furthermore, it is to be understood that varirelatively low thermal expansion, is relatively ous modifications of said alloy disclosed herein hard and has relatively great wear resistance. It also has comparatively high heat conductivity, excellent fatigue strength and elastic properties, and maintains these over long exposures at high temperatures, such as those encountered in internal combustion engines, motor parts and the like.
- the alloys of the present invention are particularly desirable for the production of castings. and the castin s are susceptible to the usual heat treatments and have tensile strength and hardnesses substantially improved thereby.
- An aluminum base alloy having relatively low thermal coeificient of expansion and relatively great wear resistance containing about 20% to 30% silicon, about 2% to 3% magnesi- .3% to 2% manganese, about .4% to 2.5% iron, and about 1% to 5% copper, with the balance substantially all aluminum and minor impurities.
- An aluminum base alloy having a low coefli- 15 cient thermal expansion and relatively great wear resistance containing 21% to 26% silicon, .5% td 1.5% magnesium, .6% to 1% manganese, 31% and 1.5% to 3% copper, with the balance substantially all aluminum and minor 3.
- An aluminum base alloy containing about about .2 to 3% magnesium, about .8% to 2% manganese, about 1% to 2.5% iron, and about 1.5% to 3% copper, with the balance substan ially all aluminum and minor impurities.
Description
Patented Sept. 5, 1944 ALUMINUM ALLOY Walter Bonsack, South Euclid,
Ohio, asslgnor to The National smelting Company, Cleveland, Ohio, a corporation of Ohio No Drawing. Application November 20, 1940, Serial No. 366,453
Claims. (01. 75-142) This invention relates to alloys, and more particularly to machinable aluminum base alloys having low thermal expansion and relatively high wear resistance.
Aluminum alloys having relatively low thermal expansion, together with relatively high strength and hardness, and, retaining these properties after exposure to prolonged high temperatures, are especially desirable for the manufacture of castings, such as pistons or other parts, for use in internal combustion engines and the like.
Aluminum-silicon alloys containing suitable amounts of manganese and magnesium have been used in the production of pistons and the like.
In these alloys, as the proportion of the silicon is increased, the thermal expansion of the alloy is decreased and the hardness increased. The
machinability and fatigue resistance are decreased substantially as the percentage of silicon is increased and, therefore, about to silicon is the amount ordinarily used in these alloys, although still greater wear resistance and still lower expansion are sometimes desirable.
It is an object of the present invention to provide a ma'chinable aluminum alloy having improved wear resistance and greater hardness than alloysheretofore used.
It is another object of this invention to provide a machinable aluminum base casting alloy having relatively low thermal expansion, improved resistance to wear, and relatively high thermal conductivity.
It is a further object of the invention to provide a machinable alloy having improved wear resistance, relatively high strength and fatigue resistance, and, a low thermal expansion, and which will retain these properties when exposed to relatively high temperatures encountered in the operation of internal combustion engines.
It has now been found that these objects are accomplished 'in an aluminum base alloy by properly proportioning silicon, magnesium, manganese, iron and copper in the alloy. My improved alloy has about or 21% to silicon, .2% to 3% magnesium, .3% to 2% manganese, .4% to 2.5% iron, and 1% to 5% copper, with the balance substantially aluminum which may contain small amounts of minor impurities. The alloy may contain some boron or titanium, or other known grain refiner, if de-.
sired, depending upon the casting technique used.
Silicon is preferably present in the amount of 22% to 26% of the alloy, and increases the hardness and wear resistance of the alloy and decreases the thermal expansion. Silicon in such large proportions, without suitable quantities of the other above mentioned constituents, however, has the tendency to crystallize into relatively large crystals and to decrease machin ability.
Iron and manganese tend to further harden the alloy and decrease the thermal expansion. These elements also increase the machinability and are beneficial, in that they tend to stabilize the alloy so that itsproperties are maintained at relatively high temperatures, such as encountered in internal combustion engines. The iron and manganese appear to perform substantially the same functions, aiding in themachinability and maintaining the properties of the metal athigh temperatures.
Iron, like silicon, has the property of tending to crystallize in relatively large crystals, but manganese has the additional property of tending to inhibit the growth of large iron crystals. Consequently, it is desirable to have manganese present, even though there, be present a relatively large quantity of iron. With an iron content of 2% or 2.5%, a smaller amount of manganese may be used to obtain the same properties as when a smaller'amount of iron, such as .7% to 1% or 1.5%, be present. Preferably, the amount of iron in the, alloy is about .7% to 1.5%-
The manganese may be present in an amount ranging from .3% to 3%, and when a substantial amount of iron is present the preferred amount of manganese is from .6% to 1% of the alloy.
Magnesium as well as improving the hardness and tensile strength of aluminum-silicon alloys increases the elastic properties of the alloy. Preferably, magnesium is presentin the alloy in the amount of .5% to 1% or 1.5%, although. as much as 3% is sometimes desirable. The magnesium and also the copper are beneficial in improving the machinability of the alloy, but the copper additionally aids in increasing the fatigue strength. The preferred amount of copper is 1.5% to 3%. v
An alloy illustrating the present invention and desirable for the making of pistons contains about 21% to 25% silicon, about 4% to .8% magnesium, about '.6% to 1% manganese, about .7% to 1.5% iron, about 1.5% to'2.5% copper, with the balance commercial aluminum and a small amount of titanium, boron, or other grain refiner, if desired. This alloy may be readily square inch, and a Brinell hardness 2 8,867,449 machined withtools now available. The alloy has Furthermore, it is to be understood that varirelatively low thermal expansion, is relatively ous modifications of said alloy disclosed herein hard and has relatively great wear resistance. It also has comparatively high heat conductivity, excellent fatigue strength and elastic properties, and maintains these over long exposures at high temperatures, such as those encountered in internal combustion engines, motor parts and the like.
While it is unnecessary to use a grain reflner in the alloy if the alloy is to be cast in. permanent and chill molds and the molds are of such a design that the casting is chilled relatively rapidly throughout its thicknesses, yet it is within the purview of this invention to use boron or titanium, or other known grain reliners, when it is desired to have the beneilt of such known grain reilners. When used, titanium should be present in the amount of about .1% or 2%, or so.
An alloy containing 22% silicon, .7% magnesiuni, 31% manganese, .8% iron, and 1.8% copper was chill cast, and upon being tested, it was found to have a thermal expansion of 165x10 inch per inch per degree centigrade, between a temperature range of 20 and 100' C. It had a Brinell hardness of 130 to 145 kilogr m per square millimeter, and a tensile strength 26,000 to 30,000 lbs. per square inch. This al- 10y, when heat treated six hours at 975 F., quenched, and aged at 355' 1". for twelve hours, had a tensile strength of 34,000 to 38,000 lba per of 120 to 140 kilograms per square millimeter.
The alloys of the present invention are particularly desirable for the production of castings. and the castin s are susceptible to the usual heat treatments and have tensile strength and hardnesses substantially improved thereby.
um, about to 2% iron,
impurities.
1.5% iron, and about 35 20% to 30% silicon,
can be made without departing from my invention as defined in the appended claims.
What I claim is:
1. An aluminum base alloy having relatively low thermal coeificient of expansion and relatively great wear resistance, containing about 20% to 30% silicon, about 2% to 3% magnesi- .3% to 2% manganese, about .4% to 2.5% iron, and about 1% to 5% copper, with the balance substantially all aluminum and minor impurities.
2. An aluminum base alloy having a low coefli- 15 cient thermal expansion and relatively great wear resistance, containing 21% to 26% silicon, .5% td 1.5% magnesium, .6% to 1% manganese, 31% and 1.5% to 3% copper, with the balance substantially all aluminum and minor 3. An aluminum base alloy containing about 21% to 26% silicon, about .2%'to .8% magnesium, about .6% to 1% manganese, about 17% to 1.5% iron, and about 1.5% to 3% copper,
impurities. 4. An aluminum base alloy containing about 21% to 26% silicon, about .5% to 1% magnesium, about .3% to 1% manganese,
1% to 5% copper, with the balance substantially all aluminum and minor impurities.
5. An aluminum base alloy containing about about .2 to 3% magnesium, about .8% to 2% manganese, about 1% to 2.5% iron, and about 1.5% to 3% copper, with the balance substan ially all aluminum and minor impurities.
' WALTER BONSACK.
with. the balance substantially all aluminum and minor
Priority Applications (1)
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US366453A US2357449A (en) | 1940-11-20 | 1940-11-20 | Aluminum alloy |
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US366453A US2357449A (en) | 1940-11-20 | 1940-11-20 | Aluminum alloy |
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US2357449A true US2357449A (en) | 1944-09-05 |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP0144898A2 (en) * | 1983-12-02 | 1985-06-19 | Sumitomo Electric Industries Limited | Aluminum alloy and method for producing same |
FR2573777A1 (en) * | 1984-11-28 | 1986-05-30 | Honda Motor Co Ltd | HEAT-RESISTANT HEAT-RESISTANT ALUMINUM ALLOY AND METHOD FOR MANUFACTURING CARRIER COMPONENT THEREOF |
US4842822A (en) * | 1986-12-19 | 1989-06-27 | Howmet Corporation | Aluminum-lithium alloy and method of investment casting an aluminum-lithium alloy |
-
1940
- 1940-11-20 US US366453A patent/US2357449A/en not_active Expired - Lifetime
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP0144898A2 (en) * | 1983-12-02 | 1985-06-19 | Sumitomo Electric Industries Limited | Aluminum alloy and method for producing same |
EP0144898A3 (en) * | 1983-12-02 | 1985-07-24 | Sumitomo Electric Industries Limited | Aluminum alloy and method for producing same |
US4702885A (en) * | 1983-12-02 | 1987-10-27 | Sumitomo Electric Industries, Ltd. | Aluminum alloy and method for producing the same |
FR2573777A1 (en) * | 1984-11-28 | 1986-05-30 | Honda Motor Co Ltd | HEAT-RESISTANT HEAT-RESISTANT ALUMINUM ALLOY AND METHOD FOR MANUFACTURING CARRIER COMPONENT THEREOF |
US4834941A (en) * | 1984-11-28 | 1989-05-30 | Honda Giken Kogyo Kabushiki Kaisha | Heat-resisting high-strength Al-alloy and method for manufacturing a structural member made of the same alloy |
US4867806A (en) * | 1984-11-28 | 1989-09-19 | Honda Giken Kogyo Kabushiki Kaisha | Heat-resisting high-strength Al-alloy and method for manufacturing a structural member made of the same alloy |
US4842822A (en) * | 1986-12-19 | 1989-06-27 | Howmet Corporation | Aluminum-lithium alloy and method of investment casting an aluminum-lithium alloy |
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