US2656270A - Aluminum alloy containing mischmetal - Google Patents
Aluminum alloy containing mischmetal Download PDFInfo
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- US2656270A US2656270A US121217A US12121749A US2656270A US 2656270 A US2656270 A US 2656270A US 121217 A US121217 A US 121217A US 12121749 A US12121749 A US 12121749A US 2656270 A US2656270 A US 2656270A
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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
Definitions
- This invention relates to aluminum alloys and particularly to aluminum alloys containing cerium and other alloying additions.
- the cerium used in the alloys of this invention was added in the form or mischmetal, a by-product of the thorium industry consisting of cerium and other rare-earth elements.
- the mischmetal used in the experimental work leading to this invention contained approximatee 1y 50% cerium and 45% lanthranum, balance, other rare-earth metals.
- the term mischmetal is used throughout this specification to indicate that composition, although it will be understood that minor variations in the quantitative composition may be made without changing the properties of the material and thus without taking it outside the scope of the term 7 mischmetal as used in defining this invention.
- the general object of this invention is to provide a new series of aluminum alloys which will have improved mechanical properties.
- Another object is to provide such alloys which will be of the non-age hardening type.
- Another object is to provide such alloys that will have improved mechanical properties at the high temperatures encountered in certain special types of service, e. g., internal combustion engine pistons.
- this invention comprises a series of alloys of aluminum and mischmetal with other metals in the particular qualitative and quantitative relationships as will hereinafter appear.
- the proportion of mischmetal in the aluminum alloy is limited to between about 6% and about 14%. This minimum required for substantial effect has been determined empirically, and the proportion of the individual elements within the range specified in order to emphasize properties which may be desired for particular service conditions is indicated.
- Silicon is present in quantities ranging from residual up to 6%. The most desirable quantity was found to be around 1-3%. Although the silicon content probably does not bear a strong direct relation to the mechanical properties of the finished alloy, its presence effects other proper ties such as fluidity in casting and hot strength. Since these alloys are designed to be used in either wrought or cast condition a considerable range of silicon content is specified. In general, silicon should be on the high side for casting alloys and lower for wrought alloys.
- Copper when present with manganese or nickel or both, is found to have a general strengthening eliect on the alloys, both as to stress-rupture and tensile properties, which is greater than a mere cumulative efiect.
- the optimum copper content is from about 2 to 3% and for tensile properties around 4%.
- the recommended quantities of manganese and nickel are roughly 1-2% for each.
- Chromium is surprisingly effective as a strengthening addition in these mischmetal alloys in quantities less than 1%. With larger amounts of chromium the ductility drops rapidly. Cobalt appears to have a similar though Weaker eiiect. The presence of the specified quantities of chromium and cobalt, and the improvement in properties incidental thereto, is believed to be one of the more important features of the invention which distinguish it from the prior art.
- Titanium is present in small quantities in most of the experimental alloys. It is believed to contribute to strength through formation of one or more intermetallic compounds of aluminum, and perhaps with other elements present. That vanadium in combination with other elements contributes to ultimate strength at 400 C., but detracts at room temperature is seen by comparison of alloys 5 and 6.
- Tungsten, molybdenum and zirconium were Iron wasfound 'tobe desirable in all of the Alloys coming 'Withinthe invention may contested in some of thematerials and found to 55 have favorable efiects particularly on tensile properties. They are-present in more than grain refining amounts. As would be expected, tungsten andmolybdenum are substantial equivamischmetal alloys in quantities less than 1.5%.
- alloys may further contain up to about 1% chromium-and up to about 1.5% iron. Titanium, co balt, tungsten, molybdenum, vanadium'and zirconium may also be present'in the alloys in 75 small amounts, for example, up to about 0.25%
- Particular alloys of the invention are those containing to 12% mischmetal, 2 to 3% silicon, 1 to 2% copper, 0.5 to 1% manganese, .01 to 0.1% titanium, l to 2% nickel, 0.2 to 0.4% chromium, 0.2 to 0.4% iron and the balance aluminum.
- alloy 3 The best particular composition from the point of view of all the properties investigated in this Work is believed to be that of alloy 3. This material has outstanding stress-rupture strength at 370 C. and very good tensile properties at room temperature and at 400 C., in both the cast and wrought condition. Note that invariably the properties of the cast material exceed those of the wrought material at 400 C. and vice versa at room temperature.
- the average mischmetal-containing experimental alloy is seen to be superior to four of the five standard reference alloys in every property tested except room temperature strength.
- the reference alloys are materials which are at present or recently have been used as standard high-temperature aluminum alloys.
- An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, about 0.5 to 3% manganese and the balance aluminum.
- An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, about 0.5 to 3% manganese, up to 3% nickel, with the combined content of manganese and nickel not exceeding 5%,
- An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, about 0.5 to 3% manganese, up to 3% nickel with the combined content of manganese and nickel not exceeding 5%, up to about 1% chromium and the balance aluminum.
- An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, up to about 3% each of manganese and nickel but not exceeding a total of 5% for both, up to about 1% chromium, up to about 1.5% iron and the balance aluminum.
- An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, about 1 to 2% manganese, about 1 to 2% nickel and the balance 6.
- An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containin about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, about 2 to- 4% copper, about 1 to 2% manganese, about 1 to 2% nickel and the balance aluminum.
- An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, about 2 to 4% copper, about 1 to 2% manganese, about 1 to 2% nickel, up to about 1% chromium and the balance aluminum.
- An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 2 to 3% silicon, about 1 to 2% copper, about 0.5 to 1% manganese, about 1 to 2% nickel, about 0.2 to 0.4% chromium and the balance aluminum.
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Description
Patented Oct. 20, 1953 OFFICE ALUMINUM ALLOY CONTAINING MISCHMETAL James B. RusselLSpokane, Wash.
N Drawing. Application October 13, 1949, Serial No. 121,217
8 Claims. (Cl. 75-439) (Granted under Title 35, U. S. Code (1952),
sec.
This invention relates to aluminum alloys and particularly to aluminum alloys containing cerium and other alloying additions.
Since metallic cerium is quite expensive and diflicult to obtain, the cerium used in the alloys of this invention was added in the form or mischmetal, a by-product of the thorium industry consisting of cerium and other rare-earth elements. The mischmetal used in the experimental work leading to this invention contained approximatee 1y 50% cerium and 45% lanthranum, balance, other rare-earth metals. Thus, the term mischmetal is used throughout this specification to indicate that composition, although it will be understood that minor variations in the quantitative composition may be made without changing the properties of the material and thus without taking it outside the scope of the term 7 mischmetal as used in defining this invention.
The general object of this invention is to provide a new series of aluminum alloys which will have improved mechanical properties.
Another object is to provide such alloys which will be of the non-age hardening type.
Another object is to provide such alloys that will have improved mechanical properties at the high temperatures encountered in certain special types of service, e. g., internal combustion engine pistons.
It is the particular object to provide suchflalloys that will have high resistance to long-time stresses at high temperatures. f
Accordingly, this invention comprises a series of alloys of aluminum and mischmetal with other metals in the particular qualitative and quantitative relationships as will hereinafter appear.
The proportion of mischmetal in the aluminum alloy is limited to between about 6% and about 14%. This minimum required for substantial effect has been determined empirically, and the proportion of the individual elements within the range specified in order to emphasize properties which may be desired for particular service conditions is indicated.
Silicon is present in quantities ranging from residual up to 6%. The most desirable quantity was found to be around 1-3%. Although the silicon content probably does not bear a strong direct relation to the mechanical properties of the finished alloy, its presence effects other proper ties such as fluidity in casting and hot strength. Since these alloys are designed to be used in either wrought or cast condition a considerable range of silicon content is specified. In general, silicon should be on the high side for casting alloys and lower for wrought alloys.
Alloys containing up to almost 10% magnesium were investigated. With respect to stress-rupture properties this addition has a cumulative derogatory effect as is seen from the accompanying tables. Thus the alloys having the best stressrupture properties contained little or no ma nesium, and in those with the larger quantities of magnesium said properties were uniformly bad, in spite of the variety of other addition elements. However, the tensile properties both at room temperature and at 400 C. aresomewhat enhanced by magnesium in lower proportions and depending on the service desired from zero to about 2% magnesium is recommended. It may be pointed out that the case of magnesium is a good illustration of the unpredictability of hightemperature properties on the basis of propertycomposition relationship at ordinary temperatures.
Copper, when present with manganese or nickel or both, is found to have a general strengthening eliect on the alloys, both as to stress-rupture and tensile properties, which is greater than a mere cumulative efiect. For maximum stressrupture properties the optimum copper content is from about 2 to 3% and for tensile properties around 4%. The recommended quantities of manganese and nickel are roughly 1-2% for each.
Chromium is surprisingly effective as a strengthening addition in these mischmetal alloys in quantities less than 1%. With larger amounts of chromium the ductility drops rapidly. Cobalt appears to have a similar though Weaker eiiect. The presence of the specified quantities of chromium and cobalt, and the improvement in properties incidental thereto, is believed to be one of the more important features of the invention which distinguish it from the prior art.
Titanium is present in small quantities in most of the experimental alloys. It is believed to contribute to strength through formation of one or more intermetallic compounds of aluminum, and perhaps with other elements present. That vanadium in combination with other elements contributes to ultimate strength at 400 C., but detracts at room temperature is seen by comparison of alloys 5 and 6.
Tungsten, molybdenum and zirconium were Iron wasfound 'tobe desirable in all of the Alloys coming 'Withinthe invention may contested in some of thematerials and found to 55 have favorable efiects particularly on tensile properties. They are-present in more than grain refining amounts. As would be expected, tungsten andmolybdenum are substantial equivamischmetal alloys in quantities less than 1.5%. This favorable efiect is contrary to general aluminum technology'and is'one of the critical featain about 10 to 12% mischmetal, about 11:0 3% silicon, up to about 5% copper, about 015110 3% manganese, up to about 3% nickel, with the combihedcontent of manganese and nickel not exceeding 5%, and the balancealuminum; The alloys may further contain up to about 1% chromium-and up to about 1.5% iron. Titanium, co balt, tungsten, molybdenum, vanadium'and zirconium may also be present'in the alloys in 75 small amounts, for example, up to about 0.25%
TABLE I CEemicaZ-fcomppsifion A-EXPERIMENTIALALLOYS t t1 .5 r r e mmawwwaam wanna we 1.2m i m mzovv .100 m m 1 n U n n R PM 0 n n QM M E m n N d 000 n v v n 0 N 1., u n a at m m a n w m n m m M m a mam. m ma an a m V n r 1 z e 0... u "00 0 0 00 3 0 S S u n m m "Mama m m wummm m m o n u e "LLZ 7 t t I p p .322 4. 0 n .1; m 1 n 9 t1 0 n 7 1 u u m T 000000100 2 S S W S L P 0 m mm t N Y 0 4 m u 0 O n 1 m u m .1 t t :l m n n S m 2a ma 0 5 0 Y C Y H .1 S 6 6 r M m m m a O D. u Y 85124. C C m m m. m 1 WW O 222224.222 N A .s 0 m m w. in e m L a mam mw m L 0 u A 2 E .1 .u at T tn 0 l S F u m 4 a we. N. C Y .1 E m n m m n t a N ta my 2 35%. o 7 T R a e 0S nwm L Pa 1 a 7 Y .w nwamwmmmm L u m 3424961930 D n u a R FL 3 0 a p 74m78554 A e d F m 3 314 R u fit E e s. m E t L m m E 110110111 m u m W 1 R M m D C 1 p l t F N 00000 H manammaam m wanna p n B I .w L E mafia C 1 0 LLLLQ0 0 T 3 1 m4n0 r i H d m swan R 2:42.22, S .S I)! e 5.65. E V 4 47:4 H g m m m. man i m w m? m. m Wm w m w w 1. r M m 012 5 w m w m p m R 5 m 0 2111113 6 R D Hewett at? 1 m1 ,1 T m m R .QWhO QO X m m t :L 000 m0 00 E S 297 5 85 102977158 2 RM a P 0114. m m 039676141 8 2 C y 1 1 a 1 1 2 Y 675 56660 A mmmmmum m m p n w. 0 m u M at e .i. wmmmwwwmm m N n m t oflammneem t B m 4 0 m 676777666 S 123456789 i n RRRRR 123456739 N M N R Ti, up to about 1% Go, up to about 1% W, up to about 0.5% Mo, with the combined content of tungsten and molybdenum being not more than 1%, up to about 1% V and up to about 0.3% Zr. Particular alloys of the invention are those containing to 12% mischmetal, 2 to 3% silicon, 1 to 2% copper, 0.5 to 1% manganese, .01 to 0.1% titanium, l to 2% nickel, 0.2 to 0.4% chromium, 0.2 to 0.4% iron and the balance aluminum.
The best particular composition from the point of view of all the properties investigated in this Work is believed to be that of alloy 3. This material has outstanding stress-rupture strength at 370 C. and very good tensile properties at room temperature and at 400 C., in both the cast and wrought condition. Note that invariably the properties of the cast material exceed those of the wrought material at 400 C. and vice versa at room temperature.
The average mischmetal-containing experimental alloy is seen to be superior to four of the five standard reference alloys in every property tested except room temperature strength. The reference alloys are materials which are at present or recently have been used as standard high-temperature aluminum alloys.
The foregoing observations and discussions are based on analysis of the experimental data and, are presented to suggest possible variations in compositions within the ranges defined by the claims which may be desirable for obtaining optimum properties for special service requirements. It is not pretended that all the specific compositions falling within the ranges disclosed and claimed are strict equivalents, but rather that they constitute a continuum, within which no structural division is possible, and substantially beyond which either no new and unforseen results were found or no improvements were obtained.
The invention disclosed herein may be manufacured and used by or for the Government of the United States of America for governmental purposes without the payment of any royalties thereon or therefor.
What is claimed is:
1. An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, about 0.5 to 3% manganese and the balance aluminum.
2. An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, about 0.5 to 3% manganese, up to 3% nickel, with the combined content of manganese and nickel not exceeding 5%,
and the balance aluminum.
3. An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, about 0.5 to 3% manganese, up to 3% nickel with the combined content of manganese and nickel not exceeding 5%, up to about 1% chromium and the balance aluminum.
4. An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, up to about 3% each of manganese and nickel but not exceeding a total of 5% for both, up to about 1% chromium, up to about 1.5% iron and the balance aluminum.
5. An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, up to about 5% copper, about 1 to 2% manganese, about 1 to 2% nickel and the balance 6. An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containin about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, about 2 to- 4% copper, about 1 to 2% manganese, about 1 to 2% nickel and the balance aluminum.
'7. An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 1 to 3% silicon, about 2 to 4% copper, about 1 to 2% manganese, about 1 to 2% nickel, up to about 1% chromium and the balance aluminum.
8. An aluminum base alloy having high temperature strength in the cast condition consisting essentially of about 10 to 12% mischmetal containing about 50% cerium and the balance other rare earth metals, about 2 to 3% silicon, about 1 to 2% copper, about 0.5 to 1% manganese, about 1 to 2% nickel, about 0.2 to 0.4% chromium and the balance aluminum.,
JAMES B. RUSSELL.
References Cited in the file of this patent UNITED STATES PATENTS Name Date Sarbey Feb. 10, 1942 OTHER REFERENCES Number
Claims (1)
1. AN ALUMINUM BASE ALLOY HAVING HIGH TEMPERATURE STRENGTH IN THE CAST CONDITION CONSISTING ESSENTIALLY OF ABOUT 10 TO 12% MISCHMETAL CONTAINING ABOUT 50% CERIUM AND THE BALANCE OTHER RARE EARTH METALS, ABOUT 1 TO 3% SILICON, UP TO ABOUT 5% COPPER, ABOUT 0.5 TO 3% MANGANESE AND THE BALANCE ALUMINUM.
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US121217A US2656270A (en) | 1949-10-13 | 1949-10-13 | Aluminum alloy containing mischmetal |
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3282745A (en) * | 1963-05-27 | 1966-11-01 | Dow Chemical Co | High strength fabrications of aluminum base alloys containing copper |
EP0202044A1 (en) * | 1985-04-27 | 1986-11-20 | Showa Aluminum Kabushiki Kaisha | Aluminium alloy |
US5240517A (en) * | 1988-04-28 | 1993-08-31 | Yoshida Kogyo K.K. | High strength, heat resistant aluminum-based alloys |
US5320688A (en) * | 1988-04-28 | 1994-06-14 | Yoshida Kogyo K. K. | High strength, heat resistant aluminum-based alloys |
US9963770B2 (en) | 2015-07-09 | 2018-05-08 | Ut-Battelle, Llc | Castable high-temperature Ce-modified Al alloys |
US11608546B2 (en) | 2020-01-10 | 2023-03-21 | Ut-Battelle Llc | Aluminum-cerium-manganese alloy embodiments for metal additive manufacturing |
US11986904B2 (en) | 2019-10-30 | 2024-05-21 | Ut-Battelle, Llc | Aluminum-cerium-nickel alloys for additive manufacturing |
Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2272779A (en) * | 1939-12-27 | 1942-02-10 | Hartford Nat Bank & Trust Co | Flash lamp |
-
1949
- 1949-10-13 US US121217A patent/US2656270A/en not_active Expired - Lifetime
Patent Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2272779A (en) * | 1939-12-27 | 1942-02-10 | Hartford Nat Bank & Trust Co | Flash lamp |
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3282745A (en) * | 1963-05-27 | 1966-11-01 | Dow Chemical Co | High strength fabrications of aluminum base alloys containing copper |
EP0202044A1 (en) * | 1985-04-27 | 1986-11-20 | Showa Aluminum Kabushiki Kaisha | Aluminium alloy |
US5240517A (en) * | 1988-04-28 | 1993-08-31 | Yoshida Kogyo K.K. | High strength, heat resistant aluminum-based alloys |
US5320688A (en) * | 1988-04-28 | 1994-06-14 | Yoshida Kogyo K. K. | High strength, heat resistant aluminum-based alloys |
US5368658A (en) * | 1988-04-28 | 1994-11-29 | Yoshida Kogyo K.K. | High strength, heat resistant aluminum-based alloys |
US9963770B2 (en) | 2015-07-09 | 2018-05-08 | Ut-Battelle, Llc | Castable high-temperature Ce-modified Al alloys |
US11986904B2 (en) | 2019-10-30 | 2024-05-21 | Ut-Battelle, Llc | Aluminum-cerium-nickel alloys for additive manufacturing |
US11608546B2 (en) | 2020-01-10 | 2023-03-21 | Ut-Battelle Llc | Aluminum-cerium-manganese alloy embodiments for metal additive manufacturing |
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