Title of Invention	NICKEL-BASE ALLOY.
Abstract	The invention relates to a castable weldable nickel-base alloy consisting of, by weight, 10% to 25% cobalt, 20% to 28% chromium, 1% to 3% tungsten, 0.5% to 1.5% aluminum, 1.5% to 2.8% titanium, 0.5% to 1.45% columbium, tantalum in an amount of from 0% to less than Columbian, and Cb + 0.508Ta is 1.15% to 1.45%, 0.001% to 0.025% boron, up to 0.4% zirconium 0.02% to 0.15% carbon, with the balance essentially nickel and incidental impurities.

Title of Invention

NICKEL-BASE ALLOY.

Abstract

The invention relates to a castable weldable nickel-base alloy consisting of, by weight, 10% to 25% cobalt, 20% to 28% chromium, 1% to 3% tungsten, 0.5% to 1.5% aluminum, 1.5% to 2.8% titanium, 0.5% to 1.45% columbium, tantalum in an amount of from 0% to less than Columbian, and Cb + 0.508Ta is 1.15% to 1.45%, 0.001% to 0.025% boron, up to 0.4% zirconium 0.02% to 0.15% carbon, with the balance essentially nickel and incidental impurities.

Full Text	NICKEL-BASH ALLOY BACKGROUND OF THE INVENTION FIELD OF THE INVENTION The present invention generally relates to nickel-base alloys. More particularly, this invention relates to castable and weldable nickel-base alloys exhibiting desirable properties suitable for gas turbine engine applications. DESCRIPTION OF THE RELATED ART The superalloy GTD-222 (U. S. Patent No. 4.810.467) has a number of desirable properties for gas turbine engine applications, such as nozzles (vanes) in the latter (second and third) stages of the turbine section. The nominal composition of GTD- 222 is, by weight, about 19% cobalt, about 22.5% chromium, about 2% tungsten, about 1.2% aluminum, about 2.3% titanium. Al+Ti of about 3.5%, about 0.8% columbium (niobium), about 1.0% tantalum, about 0.01% boron, about 0.01% zirconium, about 0.1% carbon, with the balance essentially nickel and incidental impurities. As with the formulation of other nickel-base alloys, the development of GTD-222 involved careful and controlled adjustments of the concentrations of certain critical alloying elements to achieve a desired mix of properties. For use in turbine nozzle applications, and particularly the latter stage nozzle for which GTD-222 is used, such properties include high temperature strength, castability. weldability. and resistant to low cycle fatigue, corrosion and oxidation. The thermal environment within the second stage of a turbine section is sufficiently severe to require an oxidation-resistant coating, a thermal barrier coating (TBC). and/or internal cooling for nozzles formed of the GTD-222 alloy. The properties of GTD-222 are sufficient to allow third stage nozzles to achieve the design life required of the nozzles without such additional measures. When attempting to optimize any one of the desired properties of a superalloy. other properties are often adversely affected. A particular example is weldability and creep resistance, both of which are of great importance for gas turbine engine nozzles. However, greater creep resistance results in an alloy that is more difficult to weld, which is necessary to allow for repairs by welding. A desirable combination of creep strength and weldability exhibited by GTD-222 is believed to be the result of the use of judicious levels of aluminum, titanium, tantalum and columbium in the alloy. Each of these elements participates in the gamma prime precipitation-strengthening phase (Ni3(Ti,Al)). Aluminum and titanium are the key elements in the formation of the gamma-prime phase, while the primary role of tantalum and columbium is to participate in the MC carbide phase. Tantalum and columbium remaining after MC carbide formation plays a lesser but not insignificant role in the formation of the gamma-prime phase. While GTD-222 has been proven to perform well as the alloy for latter stage nozzles of gas turbine engines, alternatives would be desirable. Of current interest is the reduction in tantalum used in view of its high cost. However, the properties of an alloy with a reduced tantalum content would preferably be closely match those of GTD-222. particularly for use as the alloy for second and third stage nozzles. BRIEF SUMMARY OF THE INVENTION The present invention provides a nickel-base alloy that exhibits a desirable balance of strength (including creep resistance) and resistance to corrosion and oxidation suitable for nozzles of the latter stages of a gas turbine engine, particularly the second and third stage nozzles. The alloy is also castable, relatively easier to weld than GTD- 222, and has acceptable heat treatment requirements. These desirable properties are achieved with an alloy in which tantalum is eliminated or at a relatively low level and a relatively high level of columbium is maintained to achieve properties similar to that of the GTD-222 alloy. According to the invention, the nickel-base alloy consists essentially of by weight, 10% to 25% cobalt. 20% to 28% chromium 1% to 3% tungsten. 0.5% to 1.5% aluminum, 1.5% to 2.8% titanium, 0.8% to 1.45% columbium, tantalum in an amount less than columbium and Cb + 0.508Ta is 1.15% to 1.45%. 0.001 % to 0.025% boron, up to 0.05% zirconium. 0.02% to 0.15% carbon, with the balance essentially nickel and incidental impurities. The columbium content of the alloy is preferably at least 0.9%, more preferably at least 1.25%, while the tantalum content of the alloy is preferably less than 0.5%, more preferably entirely omitted from the alloy. The alloy of this invention has properties comparable to those of the GTD-222 alloy, with potentially improved ductility and weldability and with no degradation in castability. Notably, improved weldability of the alloy is achieved without sacrificing creep resistance. These properties and advantages are achieved even though the relative amounts of tantalum and columbium are opposite those of GTD-222. namely, more columbium is present in the alloy than tantalum, with a preferred maximum level of tantalum being below the minimum amount of tantalum required for GTD- 222. The desired properties are believed to be achieved by maintaining a substantially constant combined atomic percent of columbium and tantalum in the alloy, in which columbium contributes greater to the combined amount than does tantalum as a result of specifying the combined amount according to the formula Cb + 0.508Ta. Contrary to GTD-222 (U. S. Patent No. 4,810,467) second and third stage nozzles exhibit excellent properties when cast from the alloy in which tantalum is essentially absent i.e., only impurity levels are present. Consequently, the alloy of this invention provides an excellent and potentially lower-cost alternative to GTD-222 as a result of reducing or eliminating the requirement for tantalum. Other objects and advantages of this invention will be better appreciated from the following detailed description. BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS Figures 1 through 3 are graphs plotting tensile strength yield strength and percent elongation versus temperature for the GTD-222 nickel-base alloy and nickel-base alloys within the scope of the present invention. Figures 4 and 5 are graphs plotting low cycle fatigue life at 1400°F and 1600°F respectively for the GTD-222 alloy and alloys within the scope of the present invention. Figure 6 is a graph plotting creep life at 1450°F and 1600°F for the GTD-222 alloy and alloys within the scope of the present invention. DETAILED DESCRIPTION OF THE INVENTION The present invention was the result of an effort to develop a nickel-base alloy having properties comparable to the nickel-base alloy commercially known as GTD-222 and disclosed in U.S. Patent No. 4.810.467, incorporated herein by reference, but whose chemistry is carefully balanced to allow for the reduction or complete elimination of tantalum. The investigation resulted in the development of a nickel-base alloy whose properties are particularly desirable for nozzles used in the second or third turbine stages of a gas turbine engine. Therefore, particular properties of interest include creep strength, weldability. fatigue life, capability, metallurgical stability and oxidation resistance. The approach of the investigation resulted in the increase in columbium to substitute for the absence of tantalum, and as a result radically altered two of the minor alloying elements of GTD-222 that are known to effect the gamma- prime precipitation hardening phase. The high-temperature strength of a nickel-base superalloy is directly related to the volume fraction of the gamma-prime phase, which in turn is directly related to the total amount of the gamma prime-forming elements (aluminum, titanium, tantalum and columbium) present. Based on these relationships, the amounts of these elements required to achieve a given strength level can be estimated. The compositions of the gamma-prime phase and other secondary phases such as carbides and borides as well as the volume fraction of the gamma-prime phase can also be estimated based on the starting chemistry of the alloy and some basic assumptions about The phases which form. By such a procedure, it was concluded that an alloy having the desired level of creep strength for second and third stage nozzles should contain about 18 volume percent or more of the gamma-prime phase. However, other properties important to gas turbine engine nozzles, such as weldability, fatigue life, capability, metallurgical stability and oxidation resistance, cannot be predicted from amounts of these and other elements. Two alloys having the approximate chemistries set forth in Table I below were formulated and cast during the investigation. Castings of the GTD-222 alloy were also prepared having the following approximate chemistry by weight: 19% cobalt, about 22.5% chromium, about 2% tungsten, about 1.2% aluminum, about 2.3% titanium, about 0.8% columbium, about 1% tantalum, about 0.008% boron, about 0.022% zirconium, about 0.1% carbon, with the balance essentially nickel and incidental impurities. Castings of each alloy underwent a heat treatment cycle that entailed a solution treatment at about 2100°F (about 1150°C) for about two hours, followed by aging at about 1475°F (about 800°C) for about eight hours. The specimens were then machined from the castings in a conventional manner. The above alloying levels were selected to evaluate the effect of substituting columbium for tantalum, but otherwise were intended to retain the GTD-222 composition. Tensile properties of the alloys were determined with standard smooth bar specimens. The normalized data are summarized in Figures 1. 2 and 3, in which "222 baseline. Average" plots the historical average of GTD-222 for the particular property, "222Cb-Supplier 1" designates data for the B1 specimens, and "222Cb- Supplier 2" designates data for the B2 specimens. Also evaluated was a gas turbine engine nozzle cast from the same alloy as the B1 specimens. The data indicate that the tensile strength of the B1 and B2 specimens was about three to about five percent lower than the GTD-222 baseline, but ductility was much higher in the B1 and B2 specimens - on the order of about 30% to 40% higher. The high ductility and similar tensile strength of the B1 and B2 alloys compared with GTD-222 indicated that the experimental alloys might be suitable alternatives to GTD-222. Figures 4 and 5 are graphs plotting low cycle fatigue (LCF) life at 1400°F (about 760°C) and 1600°F (about 870°C), respectively, for the B1 and B2 alloys and GTD- 222. In both tests, 0.25 inch (about 8.2 mm) bars were cycled to crack initiation. In Figure 4. 3s ("3S") is also plotted for the evaluated alloys (averaged) as well as GTD- 222. The 3s plot indicates that the LCF life of the B1 and B2 alloys at 1400°F was essentially the same as the GTD-222 baseline at strain levels above about 0.5%, but was lower by about 15% to 25% at strains less than 0.5%. In Figure 5, the data for the 1600°F LCF test evidence that the B1 and B2 alloys exhibited essentially the same LCF life as GTD-222. Figure 6 is a graph plotting creep life for the B1 and B2 alloys and GTD-222 at a strain level of about 0.5% and temperatures of about 1450°F (about 790°C) and 1600°F (about 870°C). At the 1450°F test temperature, the B1 and B2 alloys exhibited a creep life that was essentially the same as GTD-222. At the 1600°F test temperature, the short-term life of the B1 and B2 alloys was lower than GTD-222 as predicted by the tensile data. However, Figure 6 evidences that the long-term creep life of the B1 and B2 alloys is essentially the same as GTD-222. Additional tests were performed on the B1 and B2 alloys to compare various other properties to GTD-222. Such tests included high cycle fatigue (HCF) and low cycle fatigue (LCF) testing, oxidation resistance, weldability. castability, diffusion coating characteristics, and physical properties. In all of these investigations, the properties of the B1 and B2 alloys were essentially identical to that of the GTD-222 baseline, with the exception of weldability in which the B1 and B2 alloys were surprisingly found to exhibit slightly better weldability than GTD-222 in terms of resistance to cracking. Furthermore, the LCF life of TIG welded joints in the B1 and B2 alloys was determined to be about two times longer than that of TIG welded joints formed in GTD-222, which was consistent with the results of the weldability study. On the basis of the above, an alloy having the broad, preferred and nominal compositions (by weight) and gamma prime content (by volume) summarized in Table II is believed to have properties comparable to GTD-222 and therefore suitable for use as the alloy for the latter stage nozzles of a gas turbine engine, as well as other applications in which similar properties are required. The formula Cb+0.508Ta was derived to maintain a constant atomic percent of combined tantalum and columbium in the alloy, though with a clear preference for columbium. Tantalum is preferably kept below levels allowed in GTD-222. and more preferably is entirely omitted from the alloy in view of the investigation reported above. The ranges established for columbium are believed to be necessary to compensate for the absence or reduced level of tantalum in order to maintain the properties desired for the alloy and exhibited by alloys B1 and B2 during the investigation. It is believed that the alloy identified above in Table II can be satisfactorily heat treated using the treatment described above, though conventional heat treatments adapted for nickel-base alloys could also be used. While the invention has been described in terms of a preferred embodiment, it is apparent that other forms could be adopted by one skilled in the art. Therefore, the scope of the invention is to be limited only by the following claims. WE CLAIM 1. A castable weldable nickel-base alloy consisting of, by weight, 10% to 25% cobalt, 20% to 28% chromium, 1% to 3% tungsten, 0.5% to 1.5% aluminum, 1.5% to 2.8% titanium, 0.5% to 1.45% columbium, tantalum in an amount of from 0% to less than Columbian, and Cb + 0.508Ta is 1.15% to 1.45%, 0.001% to 0.025% boron, up to 0.4% zirconium 0.02% to 0.15% carbon, with the balance essentially nickel and incidental impurities. 2. The alloy as claimed in claim 1, wherein the columbium content is at least 1.25%. 3. The alloy as claimed in claim 1, wherein the tantalum content 0.01% to 0.09%. 4. The alloy as claimed in claim 1, wherein the cobalt content is 18.5% to 19.5%, the chromium content is 22.2% to 22.8%, the tungsten content is 1.8% to 2.25, the aluminum content is 1.1% to 1.3%, the titanium content is 2.2% to 2.4%, the boron content is 0.002% to 0.015%, the zirconium content is 0.005% to 0.4%, and the carbon content is 0.08% to 0.12%. 5. The alloy as claimed in claim 1, wherein the alloy contains at least 18 volume percent of a gamma-prime precipitate phase. 6. The alloy as claimed in claim 1, wherein the alloy is in the form of a cast nozzle of a gas turbine engine. 7. The alloy as claimed in claim 6, wherein the nozzle is installed in a second or third turbine stage of the gas turbine engine. 8. The alloy as claimed in claim 7, wherein the alloy is free of tantalum. 9. The alloy as claimed in claim 7, wherein the alloy contains about 25 to about 38 volume percent of a gamma-prime precipitate phase The invention relates to a castable weldable nickel-base alloy consisting of, by weight, 10% to 25% cobalt, 20% to 28% chromium, 1% to 3% tungsten, 0.5% to 1.5% aluminum, 1.5% to 2.8% titanium, 0.5% to 1.45% columbium, tantalum in an amount of from 0% to less than Columbian, and Cb + 0.508Ta is 1.15% to 1.45%, 0.001% to 0.025% boron, up to 0.4% zirconium 0.02% to 0.15% carbon, with the balance essentially nickel and incidental impurities.

Full Text

NICKEL-BASH ALLOY
BACKGROUND OF THE INVENTION
FIELD OF THE INVENTION
The present invention generally relates to nickel-base alloys. More particularly, this
invention relates to castable and weldable nickel-base alloys exhibiting desirable
properties suitable for gas turbine engine applications.
DESCRIPTION OF THE RELATED ART
The superalloy GTD-222 (U. S. Patent No. 4.810.467) has a number of desirable
properties for gas turbine engine applications, such as nozzles (vanes) in the latter
(second and third) stages of the turbine section. The nominal composition of GTD-
222 is, by weight, about 19% cobalt, about 22.5% chromium, about 2% tungsten,
about 1.2% aluminum, about 2.3% titanium. Al+Ti of about 3.5%, about 0.8%
columbium (niobium), about 1.0% tantalum, about 0.01% boron, about 0.01%
zirconium, about 0.1% carbon, with the balance essentially nickel and incidental
impurities. As with the formulation of other nickel-base alloys, the development of
GTD-222 involved careful and controlled adjustments of the concentrations of certain
critical alloying elements to achieve a desired mix of properties. For use in turbine
nozzle applications, and particularly the latter stage nozzle for which GTD-222 is
used, such properties include high temperature strength, castability. weldability. and
resistant to low cycle fatigue, corrosion and oxidation. The thermal environment
within the second stage of a turbine section is sufficiently severe to require an
oxidation-resistant coating, a thermal barrier coating (TBC). and/or internal cooling
for nozzles formed of the GTD-222 alloy. The properties of GTD-222 are sufficient
to allow third stage nozzles to achieve the design life required of the nozzles without
such additional measures.
When attempting to optimize any one of the desired properties of a superalloy. other
properties are often adversely affected. A particular example is weldability and creep
resistance, both of which are of great importance for gas turbine engine nozzles.
However, greater creep resistance results in an alloy that is more difficult to weld,
which is necessary to allow for repairs by welding. A desirable combination of creep
strength and weldability exhibited by GTD-222 is believed to be the result of the use
of judicious levels of aluminum, titanium, tantalum and columbium in the alloy. Each
of these elements participates in the gamma prime precipitation-strengthening
phase (Ni3(Ti,Al)). Aluminum and titanium are the key elements in the formation of
the gamma-prime phase, while the primary role of tantalum and columbium is to
participate in the MC carbide phase. Tantalum and columbium remaining after MC
carbide formation plays a lesser but not insignificant role in the formation of the
gamma-prime phase.
While GTD-222 has been proven to perform well as the alloy for latter stage nozzles
of gas turbine engines, alternatives would be desirable. Of current interest is the
reduction in tantalum used in view of its high cost. However, the properties of an
alloy with a reduced tantalum content would preferably be closely match those of
GTD-222. particularly for use as the alloy for second and third stage nozzles.
BRIEF SUMMARY OF THE INVENTION
The present invention provides a nickel-base alloy that exhibits a desirable balance of
strength (including creep resistance) and resistance to corrosion and oxidation suitable
for nozzles of the latter stages of a gas turbine engine, particularly the second and
third stage nozzles. The alloy is also castable, relatively easier to weld than GTD-
222, and has acceptable heat treatment requirements. These desirable properties are
achieved with an alloy in which tantalum is eliminated or at a relatively low level and
a relatively high level of columbium is maintained to achieve properties similar to that
of the GTD-222 alloy.
According to the invention, the nickel-base alloy consists essentially of by weight,
10% to 25% cobalt. 20% to 28% chromium 1% to 3% tungsten. 0.5% to 1.5%
aluminum, 1.5% to 2.8% titanium, 0.8% to 1.45% columbium, tantalum in an amount
less than columbium and Cb + 0.508Ta is 1.15% to 1.45%. 0.001 % to 0.025% boron,
up to 0.05% zirconium. 0.02% to 0.15% carbon, with the balance essentially nickel
and incidental impurities. The columbium content of the alloy is preferably at least
0.9%, more preferably at least 1.25%, while the tantalum content of the alloy is
preferably less than 0.5%, more preferably entirely omitted from the alloy.
The alloy of this invention has properties comparable to those of the GTD-222 alloy,
with potentially improved ductility and weldability and with no degradation in
castability. Notably, improved weldability of the alloy is achieved without sacrificing
creep resistance. These properties and advantages are achieved even though the
relative amounts of tantalum and columbium are opposite those of GTD-222. namely,
more columbium is present in the alloy than tantalum, with a preferred maximum
level of tantalum being below the minimum amount of tantalum required for GTD-
222. The desired properties are believed to be achieved by maintaining a substantially
constant combined atomic percent of columbium and tantalum in the alloy, in which
columbium contributes greater to the combined amount than does tantalum as a result
of specifying the combined amount according to the formula Cb + 0.508Ta. Contrary
to GTD-222 (U. S. Patent No. 4,810,467) second and third stage nozzles exhibit
excellent properties when cast from the alloy in which tantalum is essentially absent
i.e., only impurity levels are present. Consequently, the alloy of this invention
provides an excellent and potentially lower-cost alternative to GTD-222 as a result of
reducing or eliminating the requirement for tantalum.
Other objects and advantages of this invention will be better appreciated from the
following detailed description.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
Figures 1 through 3 are graphs plotting tensile strength yield strength and percent
elongation versus temperature for the GTD-222 nickel-base alloy and nickel-base
alloys within the scope of the present invention.
Figures 4 and 5 are graphs plotting low cycle fatigue life at 1400°F and 1600°F
respectively for the GTD-222 alloy and alloys within the scope of the present
invention.
Figure 6 is a graph plotting creep life at 1450°F and 1600°F for the GTD-222 alloy
and alloys within the scope of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
The present invention was the result of an effort to develop a nickel-base alloy having
properties comparable to the nickel-base alloy commercially known as GTD-222 and
disclosed in U.S. Patent No. 4.810.467, incorporated herein by reference, but whose
chemistry is carefully balanced to allow for the reduction or complete elimination of
tantalum. The investigation resulted in the development of a nickel-base alloy whose
properties are particularly desirable for nozzles used in the second or third turbine
stages of a gas turbine engine. Therefore, particular properties of interest include
creep strength, weldability. fatigue life, capability, metallurgical stability and
oxidation resistance. The approach of the investigation resulted in the increase in
columbium to substitute for the absence of tantalum, and as a result radically altered
two of the minor alloying elements of GTD-222 that are known to effect the gamma-
prime precipitation hardening phase.
The high-temperature strength of a nickel-base superalloy is directly related to the
volume fraction of the gamma-prime phase, which in turn is directly related to the
total amount of the gamma prime-forming elements (aluminum, titanium, tantalum
and columbium) present. Based on these relationships, the amounts of these elements
required to achieve a given strength level can be estimated. The compositions of the
gamma-prime phase and other secondary phases such as carbides and borides as well
as the volume fraction of the gamma-prime phase can also be estimated based on the
starting chemistry of the alloy and some basic assumptions about The phases which
form. By such a procedure, it was concluded that an alloy having the desired level of
creep strength for second and third stage nozzles should contain about 18 volume
percent or more of the gamma-prime phase. However, other properties important to
gas turbine engine nozzles, such as weldability, fatigue life, capability, metallurgical
stability and oxidation resistance, cannot be predicted from amounts of these and
other elements.
Two alloys having the approximate chemistries set forth in Table I below were
formulated and cast during the investigation. Castings of the GTD-222 alloy were
also prepared having the following approximate chemistry by weight: 19% cobalt,
about 22.5% chromium, about 2% tungsten, about 1.2% aluminum, about 2.3%
titanium, about 0.8% columbium, about 1% tantalum, about 0.008% boron, about
0.022% zirconium, about 0.1% carbon, with the balance essentially nickel and
incidental impurities. Castings of each alloy underwent a heat treatment cycle that
entailed a solution treatment at about 2100°F (about 1150°C) for about two hours,
followed by aging at about 1475°F (about 800°C) for about eight hours. The
specimens were then machined from the castings in a conventional manner.
The above alloying levels were selected to evaluate the effect of substituting
columbium for tantalum, but otherwise were intended to retain the GTD-222
composition. Tensile properties of the alloys were determined with standard smooth
bar specimens. The normalized data are summarized in Figures 1. 2 and 3, in which
"222 baseline. Average" plots the historical average of GTD-222 for the particular
property, "222Cb-Supplier 1" designates data for the B1 specimens, and "222Cb-
Supplier 2" designates data for the B2 specimens. Also evaluated was a gas turbine
engine nozzle cast from the same alloy as the B1 specimens. The data indicate that
the tensile strength of the B1 and B2 specimens was about three to about five percent
lower than the GTD-222 baseline, but ductility was much higher in the B1 and B2
specimens - on the order of about 30% to 40% higher. The high ductility and similar
tensile strength of the B1 and B2 alloys compared with GTD-222 indicated that the
experimental alloys might be suitable alternatives to GTD-222.
Figures 4 and 5 are graphs plotting low cycle fatigue (LCF) life at 1400°F (about
760°C) and 1600°F (about 870°C), respectively, for the B1 and B2 alloys and GTD-
222. In both tests, 0.25 inch (about 8.2 mm) bars were cycled to crack initiation. In
Figure 4. 3s ("3S") is also plotted for the evaluated alloys (averaged) as well as GTD-
222. The 3s plot indicates that the LCF life of the B1 and B2 alloys at 1400°F was
essentially the same as the GTD-222 baseline at strain levels above about 0.5%, but
was lower by about 15% to 25% at strains less than 0.5%. In Figure 5, the data for the
1600°F LCF test evidence that the B1 and B2 alloys exhibited essentially the same
LCF life as GTD-222.
Figure 6 is a graph plotting creep life for the B1 and B2 alloys and GTD-222 at a
strain level of about 0.5% and temperatures of about 1450°F (about 790°C) and
1600°F (about 870°C). At the 1450°F test temperature, the B1 and B2 alloys
exhibited a creep life that was essentially the same as GTD-222. At the 1600°F test
temperature, the short-term life of the B1 and B2 alloys was lower than GTD-222 as
predicted by the tensile data. However, Figure 6 evidences that the long-term creep
life of the B1 and B2 alloys is essentially the same as GTD-222.
Additional tests were performed on the B1 and B2 alloys to compare various other
properties to GTD-222. Such tests included high cycle fatigue (HCF) and low cycle
fatigue (LCF) testing, oxidation resistance, weldability. castability, diffusion coating
characteristics, and physical properties. In all of these investigations, the properties of
the B1 and B2 alloys were essentially identical to that of the GTD-222 baseline, with
the exception of weldability in which the B1 and B2 alloys were surprisingly found to
exhibit slightly better weldability than GTD-222 in terms of resistance to cracking.
Furthermore, the LCF life of TIG welded joints in the B1 and B2 alloys was
determined to be about two times longer than that of TIG welded joints formed in
GTD-222, which was consistent with the results of the weldability study.
On the basis of the above, an alloy having the broad, preferred and nominal
compositions (by weight) and gamma prime content (by volume) summarized in
Table II is believed to have properties comparable to GTD-222 and therefore suitable
for use as the alloy for the latter stage nozzles of a gas turbine engine, as well as other
applications in which similar properties are required.
The formula Cb+0.508Ta was derived to maintain a constant atomic percent of
combined tantalum and columbium in the alloy, though with a clear preference for
columbium. Tantalum is preferably kept below levels allowed in GTD-222. and more
preferably is entirely omitted from the alloy in view of the investigation reported
above. The ranges established for columbium are believed to be necessary to
compensate for the absence or reduced level of tantalum in order to maintain the
properties desired for the alloy and exhibited by alloys B1 and B2 during the
investigation. It is believed that the alloy identified above in Table II can be
satisfactorily heat treated using the treatment described above, though conventional
heat treatments adapted for nickel-base alloys could also be used.
While the invention has been described in terms of a preferred embodiment, it is
apparent that other forms could be adopted by one skilled in the art. Therefore, the
scope of the invention is to be limited only by the following claims.
WE CLAIM
1. A castable weldable nickel-base alloy consisting of, by weight, 10% to
25% cobalt, 20% to 28% chromium, 1% to 3% tungsten, 0.5% to 1.5%
aluminum, 1.5% to 2.8% titanium, 0.5% to 1.45% columbium, tantalum
in an amount of from 0% to less than Columbian, and Cb + 0.508Ta is
1.15% to 1.45%, 0.001% to 0.025% boron, up to 0.4% zirconium 0.02%
to 0.15% carbon, with the balance essentially nickel and incidental
impurities.
2. The alloy as claimed in claim 1, wherein the columbium content is at least
1.25%.
3. The alloy as claimed in claim 1, wherein the tantalum content 0.01% to
0.09%.
4. The alloy as claimed in claim 1, wherein the cobalt content is 18.5% to
19.5%, the chromium content is 22.2% to 22.8%, the tungsten content is
1.8% to 2.25, the aluminum content is 1.1% to 1.3%, the titanium
content is 2.2% to 2.4%, the boron content is 0.002% to 0.015%, the
zirconium content is 0.005% to 0.4%, and the carbon content is 0.08% to
0.12%.
5. The alloy as claimed in claim 1, wherein the alloy contains at least 18
volume percent of a gamma-prime precipitate phase.
6. The alloy as claimed in claim 1, wherein the alloy is in the form of a cast
nozzle of a gas turbine engine.
7. The alloy as claimed in claim 6, wherein the nozzle is installed in a second
or third turbine stage of the gas turbine engine.
8. The alloy as claimed in claim 7, wherein the alloy is free of tantalum.
9. The alloy as claimed in claim 7, wherein the alloy contains about 25 to
about 38 volume percent of a gamma-prime precipitate phase
The invention relates to a castable weldable nickel-base alloy consisting of, by
weight, 10% to 25% cobalt, 20% to 28% chromium, 1% to 3% tungsten, 0.5%
to 1.5% aluminum, 1.5% to 2.8% titanium, 0.5% to 1.45% columbium,
tantalum in an amount of from 0% to less than Columbian, and Cb + 0.508Ta is
1.15% to 1.45%, 0.001% to 0.025% boron, up to 0.4% zirconium 0.02% to
0.15% carbon, with the balance essentially nickel and incidental impurities.

Documents:

406-KOL-2003-FORM-27.pdf

406-kol-2003-granted-abstract.pdf

406-kol-2003-granted-assignment.pdf

406-kol-2003-granted-claims.pdf

406-kol-2003-granted-correspondence.pdf

406-kol-2003-granted-description (complete).pdf

406-kol-2003-granted-drawings.pdf

406-kol-2003-granted-examination report.pdf

406-kol-2003-granted-form 1.pdf

406-kol-2003-granted-form 18.pdf

406-kol-2003-granted-form 2.pdf

406-kol-2003-granted-form 3.pdf

406-kol-2003-granted-form 5.pdf

406-kol-2003-granted-gpa.pdf

406-kol-2003-granted-reply to examination report.pdf

406-kol-2003-granted-specification.pdf

406-kol-2003-granted-translated copy of priority document.pdf

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Patent Number

223867

Indian Patent Application Number

406/KOL/2003

PG Journal Number

39/2008

Publication Date

26-Sep-2008

Grant Date

23-Sep-2008

Date of Filing

25-Jul-2003

Name of Patentee

GENERAL ELECTRIC COMPANY

Applicant Address

1 RIVER ROAD, SCHENECTADY, NEW YORK

Inventors:

#	Inventor's Name	Inventor's Address
1	WOOD, JOHN HERBERT	170 SMOLIK ROAD, ST JOHNSONVILLE
2	FENG, GANGJIANG	19 BRECKENRIDGE COURT GREENVILLE
3	BECK, CYRIL GERARD	200 BELMONT STAKES WAY, GREENVILLE

PCT International Classification Number

C22C 13/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	10/064, 607	2002-07-30	U.S.A.