EP1127948A2 - Hot corrosion resistant single crystal nickel-based superalloys - Google Patents

Hot corrosion resistant single crystal nickel-based superalloys Download PDF

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Publication number
EP1127948A2
EP1127948A2 EP95116194A EP95116194A EP1127948A2 EP 1127948 A2 EP1127948 A2 EP 1127948A2 EP 95116194 A EP95116194 A EP 95116194A EP 95116194 A EP95116194 A EP 95116194A EP 1127948 A2 EP1127948 A2 EP 1127948A2
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percent
superalloy
single crystal
weight
casting
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EP95116194A
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German (de)
French (fr)
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EP1127948B1 (en
EP1127948A3 (en
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Gary L. Erickson
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Cannon Muskegon Corp
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Cannon Muskegon Corp
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Priority to AT95116194T priority Critical patent/ATE221138T1/en
Priority to EP95116194A priority patent/EP1127948B1/en
Priority to DE69527557T priority patent/DE69527557T2/en
Priority to ES95116194T priority patent/ES2184779T3/en
Priority to DK95116194T priority patent/DK1127948T3/en
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Publication of EP1127948A3 publication Critical patent/EP1127948A3/en
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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C19/00Alloys based on nickel or cobalt
    • C22C19/03Alloys based on nickel or cobalt based on nickel
    • C22C19/05Alloys based on nickel or cobalt based on nickel with chromium
    • C22C19/051Alloys based on nickel or cobalt based on nickel with chromium and Mo or W
    • C22C19/056Alloys based on nickel or cobalt based on nickel with chromium and Mo or W with the maximum Cr content being at least 10% but less than 20%

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  • U.K. Patent Application Publication No. 2153848A discloses nickel-base alloys having a composition within the range of 13-15.6% chromium, 5-15% cobalt, 2.5-5% molybdenum, 3-6% tungsten, 4-6% titanium, 2-4% aluminum, and the balance essentially nickel without intentional additions of carbon, boron or zirconium, which are fabricated into single crystals.
  • the alloys taught by this reference claim an improvement in hot corrosion resistance accompanied by an increase in creep rupture properties, the need remains in the art for single crystal superalloys for industrial gas turbine applications having a superior combination of increased hot corrosion resistance, oxidation resistance, mechanical strength, large component castability and adequate heat treatment response.
  • Single crystal articles are generally produced having the low-modulus (001) crystallographic orientation parallel to the component dendritic growth pattern or blade stacking axis.
  • Face-centered cubic (FOC) superalloy single crystals grown in the (001) direction provide extremely good thermal fatigue resistance relative to conventionally cast polycrystalline articles. Since these single crystal articles have no grain boundaries, alloy design without grain boundary strengtheners, such as carbon, boron and zirconium, is possible. As these elements are alloy melting point depressants, their essential elimination from the alloy design provides a greater potential for high temperature mechanical strength achievement since more complete gamma prime solution and microstructural homogenization can be achieved relative to directionally solidified (DS) columnar grain and conventionally cast materials, made possible by a higher incipient melting temperature.
  • DS directionally solidified
  • alloys must be designed to avoid tendency for casting defect formation such as freckles, slivers, spurious grains and recrystallization, particularly when utilized for large cast components. Additionally, the alloys must provide an adequate heat treatment "window" (numeric difference between an alloy's gamma prime solvus and incipient melting point) to allow for nearly complete gamma prime solutioning. At the same time, the alloy compositional balance should be designed to provide an adequate blend of engineering properties necessary for operation in gas turbine engines. Selected properties generally considered important by gas turbine engine designers include: elevated temperature creep-rupture strength, thermo-mechanical fatigue resistance, impact resistanoe, hot corrosion and oxidation resistance, plus coating performance. In particular, industrial turbine designers require unique blends of hot corrosion and oxidation resistance, plus good long-term mechanical properties.
  • An alloy designer can attempt to improve one or two of these design properties by adjusting the compositional balance of known superalloys.
  • the unique superalloy of the present invention provides an excellent blend of the properties necessary for use in producing single crystal articles for operation in industrial and marine gas turbine engine hot sections.
  • This invention relates to a hot corrosion resistant nickel-based superalloy comprising the following elements in percent by weight: from about 14.2 to about 15.5 percent chromium, from about 2.0 to about 4.0 percent cobalt, from about 0.30 to about 0.45 percent molybdenum, from about 4.0 to about 5.0 percent tungsten, from about 4.5 to about 5.8 percent tantalum, from about 0.05 to about 0.25 percent columbium, from about 3.2 to about 3.6 percent aluminum, from about 4.0 to about 4.4 percent titanium, from about 0.01 to about 0.06 percent hafnium, and the balance nickel plus incidental impurities, the superalloy having a phasial stability number N V3B less than about 2.45.
  • the sum of aluminum plus titanium in this superalloy composition is from 7.2 to 8.0 percent by weight. Also, it is advantageous to have a Ti:Al ratio greater than 1 and a Ta:W ratio greater than 1 in the composition of the present invention.
  • the superalloy can also be comprised of from about 0 to about 0.05 percent carbon, from about 0 to about 0.03 percent boron, from about 0 to about 0.03 percent zinconium, from about 0 to about 0.25 percent rhenium, from about 0 to about 0.10 percent silicon, and from about 0 to about 0.10 percent manganese.
  • the base element is nickel. This invention provides a single crystal superalloy having an increased resistance to hot corrosion, an increased resistance to oxidation, and increased creep-rupture strength.
  • the article can be a component for a gas turbine engine and, more particularly, the component can be a gas turbine blade or gas turbine vane.
  • the superalloy compositions of this invention have a critically balanced alloy chemistry which results in a unique blend of desirable properties, including an increased resistance to hot corrosion, which are particularly suitable for industrial and marine gas turbine applications. These properties include: excellent bare hot corrosion resistance and creep-rupture strength; good bare oxidation resistance; good single crystal component castability, particularly for large blade and vane components; good solution heat treatment response; adequate resistance to cast component recrystallization; adequate component coatability and microstructural stability, such as long-term resistance to the formation of undesirable, brittle phases called topologically close-packed (TCP) phases.
  • TCP topologically close-packed
  • FIG. 1 is a chart of hot corrosion test results performed at three exposure temperatures on one embodiment of this invention and on four other alloys.
  • FIG. 2 is a graphical comparison of hot corrosion data from tests performed at 732°C (1350°F) on one embodiment of this invention and on two other alloys.
  • FIG. 3 is a graphical comparison of hot corrosion data from tests performed at 899°C (1650°F) on one embodiment of this invention and on two other alloys.
  • FIG. 4 is a graphical comparison of alloy strength and hot corrosion data from tests performed on one embodiment of this invention and on six other alloys.
  • FIG. 5 is a graphical comparison of oxidation data from tests performed at 1000°C (1832°F) on one embodiment of this invention and on two other alloys.
  • FIG. 6 is a graphical comparison of oxidation data from tests performed at 1010°C (1850°F) on one embodiment of the present invention and on two other alloys.
  • FIG. 7 is a graphical comparison of alloy strength and oxidation data from tests performed on one embodiment of this invention and on six other alloys.
  • the hot corrosion resistant nickel-based superalloy of the present invention comprises the following elements in percent by weight: Chromium about 14.2-15.5 Cobalt about 2.0-4.0 Molybdenum about 0.30-0.45 Tungsten about 4.0-5.0 Tantalum about 4.5-5.8 Columbium about 0.05-0.25 Aluminum about 3.2-3.6 Titanium about 4.0-4.4 Hafnium about 0.01-0.06 Nickel + Incidental impurities balance
  • This superalloy composition also has a phasial stability number N V38 less than about 2.45. Further, this invention has a critically balanced alloy chemistry which results in a unique blend of desirable properties useful for industrial and marine gas turbine engine applications.
  • These properties include a superior blend of bare hot corrosion resistance and creep-rupture strength relative to prior art single crystal superalloys for industrial and marine gas turbine applications, bare oxidation resistance, single crystal component castability, and microstructural stability, including resistance to TCP phase formation under high stress, high temperature conditions.
  • Superalloy chromium content is a primary contributor toward attaining superalloy hot corrosion resistance.
  • the superalloys of the present invention have a relatively high chromium content since alloy hot corrosion resistance was one of the primary design criteria in the development of these alloys.
  • the chromium is about 14.2-15.5% by weight.
  • the chromium content is from 14.3% to 15.0% by weight.
  • chromium provides hot corrosion resistance, it may also assist with the alloys' oxidation capability. Additionally, this superalloys' tantalum and titanium contents, as well as its Ti:Al ratio being greater than 1, are beneficial for hot corrosion resistance attainment.
  • chromium contributes to the formation of Cr and W-rich TCP phase and must be balanced accordingly in these compositions.
  • the cobalt content is about 2.0-4.0% by weight. In another embodiment of the present invention, the cobalt content is from 2.5% to 3.5% by weight.
  • the chromium and cobalt levels in these superalloys assist in making the superalloy solution heat treatable, since both elements tend to decrease an alloy's gamma prime solvus.
  • Proper balancing of these elements in the present invention in tandem with those which tend to increase the alloy's incipient melting temperature, such as tungsten and tantalum result in superalloxy compositions which have desirable solution heat treatment windows (numerical difference between an alloy's incipient melting point and its gamma prime solvus), thereby facilitating full gamma prime solutioning.
  • the cobalt content is also beneficial to the superalloy's solid solubility.
  • the tungsten content is about 4.0-5.0% by weight and, advantageously, the amount of tungsten is from 4.2% to 4.8% by weight.
  • Tungsten is added in these compositions since it is an effective solid solution strengthener and it can contribute to strengthening the gamma prime. Additionally, tungsten is effective in raising the alloy's incipient melting temperature.
  • the molybdenum content is about 0.30-0.45% by weight.
  • molybdemm is present in an amount of from 0.35% to 0.43% by weight.
  • Molybdenum is a good solid solution strengthener, but it is not as effective as tungsten and tantalum, and it tends to be a negative factor toward hot corrosion capability.
  • the addition of molybdenum is a means of assisting control of the overall alloy density in the compositions of this invention. It is believed that the relatively low molybdenum content is unique in this class of bare hot corrosion resistant nickel-based single crystal superalloys.
  • the aluminum content is about 3.2-3.6% by weight. Furthermore, the amount of aluminum present in these compositions is advantageously from 3.3% to 3.5% by weight.
  • Aluminum and titanium are the primary elements comprising the gamma prime phase, and the sum of aluminum plus titanium in the present invention is from 7.2 to 8.0 percent by weight. These elements are added in these compositions in a proportion and ratio consistent with achieving adequate alloy castability, solution heat treatability, phasial stability and the desired blend of high mechanical strength and hot corrosion resistance. Aluminum is also added to these alloys in proportions sufficient to provide oxidation resistance.
  • the titanium content is about 4.0-4.4% by weight.
  • titanium is present in this composition in an amount from 4.1% to 4.3% by weight.
  • These alloys' titanium content is relatively high and, therefore, is beneficial to the alloys' hot corrosion resistance. However, it can also have a negative effect on oxidation resistance, alloy castability and alloy response to solution heat treatment. Accordingly, it is critical that the titanium content is maintained within the stated range of this composition and the proper balancing of the aforementioned elemental constituents is maintained. Furthermore, maintaining the alloys' Ti:Al ratio greater than 1 is critical in achieving the desired bare hot corrosion resistance in these compositions.
  • the columbium content is about 0.05%-0.25% by weight and, advantageously, the columbium content is from 0.05% to 0.12% by weight.
  • Columbium is a gamma prime forming element and it is an effective strengthener in the nickel-based superalloys of this invention. Generally, however, columbium is a detriment to alloy oxidation and hot corrosion properties, so its addition to the compositions of this invention is minimized. Moreover, Columbium is added to this invention's compositions for the purpose of gettering carbon, which can be chemi-sorbed into component surfaces during non-optimized vacuum solution heat treatment procedures.
  • any carbon pick-up will tend to form columbium carbide instead of titanium or tantalum carbide, thereby preserving the greatest proportion of titanium and/or tantalum for gamma prime and/or solid solution strengthening in these alloys. Furthermore, it is critical that the sum of columbium plus hafnium is from 0.06 to 0.31 percent by weight in these compositions in order to enhance the strength of these superalloys.
  • the balance of this invention's superalloy compositions is comprised of nickel and small amounts of incidental impurities.
  • incidental impurities are entrained from the industrial process of production, and they should be kept to the least amount possible in the composition so that they do not affect the advantageous aspects of the superalloy.
  • these incidental impurities may include up to about 0.05 percent carbon, up to about 0.03 percent boron, up to about 0.03 percent zirconium, up to about 0.25 percent rhenium, up to about 0.10 percent silicon, and up to about 0.10 percent manganese. Amounts of these impurities which exceed the stated amounts could have an adverse effect upon the resulting alloy's properties.
  • the superalloys of this invention can be used to suitably make single crystal articles, such as components for industrial and marine gas turbine engines.
  • these superalloys are utilized to make a single crystal casting to be used under high stress, high temperature conditions characterized by an increased resistance to hot corrosion (sulfidation) under such conditions, particularly high temperature conditions involving corrosive atmospheres containing sulfur, sodium and vanadium contaminants, up to about 1922°F (1050°C). While these superalloys can be used for any purpose requiring high strength castings produced as a single crystal, their particular use is in the casting of single crystal blades and vanes for industrial and marine gas turbine engines.
  • the single crystal components made from this invention's compositions can be produced by any of the single crystal casting techniques known in the art.
  • single crystal directional solidification processes can be utilized, such as the seed crystal process and the choke process.
  • the single crystal castings made from the superalloys of the present invention can be aged at a temperature of from about 1800°F (982°C) to about 2125°F (1163°C) for about 1 to about 50 hours.
  • a temperature of from about 1800°F (982°C) to about 2125°F (1163°C) for about 1 to about 50 hours.
  • the optimum aging temperature and time for aging depends on the precise composition of the superalloy.
  • This invention provides superalloy compositions having a unique blend of desirable properties. These properties include: excellent bare hot corrosion resistance and creep-rupture strength; good oxidation resistance; good single crystal component castability, particularly for large blade and vane components; good solution heat treatment response; adequate resistance to cast component recrystallization; adequate component coatability and microstructural stability, such as long-term resistance to the formation of undesirable, brittle phases called topologically close-packed (TCP) phases.
  • TCP topologically close-packed
  • Test materials were prepared to investigate the compositional variations and ranges for the superalloys of the present invention.
  • One of the alloy compositions tested and reported below falls outside the claimed scope of the present invention, but is included for comparative purposes to assist in the understanding of the invention.
  • Representative alloy aim chemistries of materials tested are reported in Table 1 below.
  • AIM CHEMISTRIES ELEMENT CMSX-11C CMSX-11C' CMSX-11C" CMSX-11B C Lap Lap Lap Lap Cr 14.5 14.5 14.4 12.5 Co 3.0 2.5 2.9 6.0 Mo .40 .35 .40 0.55 W 4.4 4.6 4.5 5.0 Ta 4.95 5.1 5.1 5.15 Cb .10 .08 .10 0.20 Al 3.40 3.40 3.4 3.60 Ti 4.20 4.15 4.2 4.20 Hf .04 .03 .04 0.040 Ni BAL BAL BAL BAL N v3B 2.41 2.40 2.42 2.42 NOTE: Chemistries are in wt. %.
  • test specimens were further heat treated by aging initially at 2050°F (1121°C) to encourage a desirable ⁇ ' morphology and distribution, followed by secondary ages at 1600°F (871°C) and 1400°F (760°C), respectively (see Table 3 below).
  • HEAT TREATMENT ALLOY PEAK SOLUTION TEMP All test specimens were further heat treated by aging initially at 2050°F (1121°C) to encourage a desirable ⁇ ' morphology and distribution, followed by secondary ages at 1600°F (871°C) and 1400°F (760°C), respectively (see Table 3 below).
  • test bars were machined and low-stress ground to ASIM standard proportional specimen dimension for subsequent stress - and creep-rupture testing at various conditions of temperature and stress, according to standard ASTM procedure. Specimens removed from solid turbine blades were prepared similarly.
  • Table 5 shows the results of stress - and creep-rupture tests undertaken with the CMSX-11C alloy specimens. The tests were performed at conditions ranging 1400-1900°F (760-1038°C).

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Abstract

This invention relates to a hot corrosion resistant nickel-based superalloy comprising the following elements in percent by weight: from about 14.2 to about 15.5 percent chromium, from about 2.0 to about 4.0 percent cobalt, from about 0.30 to about 0.45 percent molybdenum, from about 4.0 to about 5.0 percent tungsten, from about 4.5 to about 5.8 percent tantalum, from about 0.05 to about 0.25 percent columbium, from about 3.2 to about 3.6 percent aluminum, from about 4.0 to about 4.4 percent titanium, from about 0.01 to about 0.06 percent hafnium, ard the balance nickel plus incidental impurities, the superalloy having a phasial stability number NV3B less than about 2.45. Single crystal articles can be suitably made from the superalloy of this invention. The article can be a component for a gas turbine engine and, more particularly, the component can be a gas turbine blade or gas turbine vane.

Description

    BACKGROUND OF THE INVENTION 1. Field of the Invention
  • This invention relates to single crystal nickel-based superalloys and, more particularly, single crystal nickel-based superalloys and articles made therefrom having increased resistance to bare hot corrosion for use in gas turbine engines.
  • 2. Description of the Prior Art
  • Advances over recent years in the metal temperature and stress capability of single crystal articles have been the result of the continuing development of single crystal superalloys, as well as improvements in casting processes and engine application technology. These single crystal superalloy articles include rotating and stationary turbine blades and vanes found in the hot sections of gas turbine engines. Gas turbine engine design goals have remained the same during the past decades. These goals include the desire to increase engine operating temperature, rotational speed, fuel efficiency, and engine component durability and reliability.
  • Prior art attempts to provide alloys to help achieve these design goals for industrial gas turbine engine applications include U.S. Patent No. 4,677,035, Fiedler et al., which discloses a nickel-base single crystal alloy composition consisting essentially of, in percent by weight, 8.0-14.0% chromium, 1.5-6.0% cobalt, 0.5-2.0% molybdenum, 3.0-10.0% tungsten, 2.5-7.0% titanium, 2.5-7.0% aluminum, 3.0-6.0% tantalum, and the balance nickel. However, the alloy compositions taught by this reference, while possessing relatively high strength at prolonged or repeated exposure to high temperatures, are susceptible to the accelerated corrosive effect of the hot gas environment in which components fabricated from the alloys are exposed to when used in gas turbines.
  • Also, U.K. Patent Application Publication No. 2153848A discloses nickel-base alloys having a composition within the range of 13-15.6% chromium, 5-15% cobalt, 2.5-5% molybdenum, 3-6% tungsten, 4-6% titanium, 2-4% aluminum, and the balance essentially nickel without intentional additions of carbon, boron or zirconium, which are fabricated into single crystals. Although the alloys taught by this reference claim an improvement in hot corrosion resistance accompanied by an increase in creep rupture properties, the need remains in the art for single crystal superalloys for industrial gas turbine applications having a superior combination of increased hot corrosion resistance, oxidation resistance, mechanical strength, large component castability and adequate heat treatment response.
  • Single crystal articles are generally produced having the low-modulus (001) crystallographic orientation parallel to the component dendritic growth pattern or blade stacking axis. Face-centered cubic (FOC) superalloy single crystals grown in the (001) direction provide extremely good thermal fatigue resistance relative to conventionally cast polycrystalline articles. Since these single crystal articles have no grain boundaries, alloy design without grain boundary strengtheners, such as carbon, boron and zirconium, is possible. As these elements are alloy melting point depressants, their essential elimination from the alloy design provides a greater potential for high temperature mechanical strength achievement since more complete gamma prime solution and microstructural homogenization can be achieved relative to directionally solidified (DS) columnar grain and conventionally cast materials, made possible by a higher incipient melting temperature.
  • These process benefits are not necessarily realized unless a multi-faceted alloy design approach is undertaken. Alloys must be designed to avoid tendency for casting defect formation such as freckles, slivers, spurious grains and recrystallization, particularly when utilized for large cast components. Additionally, the alloys must provide an adequate heat treatment "window" (numeric difference between an alloy's gamma prime solvus and incipient melting point) to allow for nearly complete gamma prime solutioning. At the same time, the alloy compositional balance should be designed to provide an adequate blend of engineering properties necessary for operation in gas turbine engines. Selected properties generally considered important by gas turbine engine designers include: elevated temperature creep-rupture strength, thermo-mechanical fatigue resistance, impact resistanoe, hot corrosion and oxidation resistance, plus coating performance. In particular, industrial turbine designers require unique blends of hot corrosion and oxidation resistance, plus good long-term mechanical properties.
  • An alloy designer can attempt to improve one or two of these design properties by adjusting the compositional balance of known superalloys.
  • However, it is extremely difficult to improve more than one or two of the design properties without significantly or even severely compromising some of the remaining properties. The unique superalloy of the present invention provides an excellent blend of the properties necessary for use in producing single crystal articles for operation in industrial and marine gas turbine engine hot sections.
  • SUMMARY OF THE INVENTION
  • This invention relates to a hot corrosion resistant nickel-based superalloy comprising the following elements in percent by weight: from about 14.2 to about 15.5 percent chromium, from about 2.0 to about 4.0 percent cobalt, from about 0.30 to about 0.45 percent molybdenum, from about 4.0 to about 5.0 percent tungsten, from about 4.5 to about 5.8 percent tantalum, from about 0.05 to about 0.25 percent columbium, from about 3.2 to about 3.6 percent aluminum, from about 4.0 to about 4.4 percent titanium, from about 0.01 to about 0.06 percent hafnium, and the balance nickel plus incidental impurities, the superalloy having a phasial stability number NV3B less than about 2.45.
  • Advantageously, the sum of aluminum plus titanium in this superalloy composition is from 7.2 to 8.0 percent by weight. Also, it is advantageous to have a Ti:Al ratio greater than 1 and a Ta:W ratio greater than 1 in the composition of the present invention. Although incidental impurities should be kept to the least amount possible, the superalloy can also be comprised of from about 0 to about 0.05 percent carbon, from about 0 to about 0.03 percent boron, from about 0 to about 0.03 percent zinconium, from about 0 to about 0.25 percent rhenium, from about 0 to about 0.10 percent silicon, and from about 0 to about 0.10 percent manganese. In all cases, the base element is nickel. This invention provides a single crystal superalloy having an increased resistance to hot corrosion, an increased resistance to oxidation, and increased creep-rupture strength.
  • Single crystal articles can be suitably made from the superalloy of this invention. The article can be a component for a gas turbine engine and, more particularly, the component can be a gas turbine blade or gas turbine vane.
  • The superalloy compositions of this invention have a critically balanced alloy chemistry which results in a unique blend of desirable properties, including an increased resistance to hot corrosion, which are particularly suitable for industrial and marine gas turbine applications. These properties include: excellent bare hot corrosion resistance and creep-rupture strength; good bare oxidation resistance; good single crystal component castability, particularly for large blade and vane components; good solution heat treatment response; adequate resistance to cast component recrystallization; adequate component coatability and microstructural stability, such as long-term resistance to the formation of undesirable, brittle phases called topologically close-packed (TCP) phases.
  • Accordingly, it is an object of the present to provide superalloy compositions and single Crystal articles made therefrom having a unique blend of desirable properties, including increased hot corrosion resistance. It is a further object of the present invention to provide superalloys and single crystal articles made therefrom for use in industrial and marine gas turbine engines. These and other objects and advantages of the present invention will be apparent to those skilled in the art upon reference to the following description of the preferred embodiments.
  • BRIEF DESCRIPTION OF THE DRAWINGS
  • FIG. 1 is a chart of hot corrosion test results performed at three exposure temperatures on one embodiment of this invention and on four other alloys.
  • FIG. 2 is a graphical comparison of hot corrosion data from tests performed at 732°C (1350°F) on one embodiment of this invention and on two other alloys.
  • FIG. 3 is a graphical comparison of hot corrosion data from tests performed at 899°C (1650°F) on one embodiment of this invention and on two other alloys.
  • FIG. 4 is a graphical comparison of alloy strength and hot corrosion data from tests performed on one embodiment of this invention and on six other alloys.
  • FIG. 5 is a graphical comparison of oxidation data from tests performed at 1000°C (1832°F) on one embodiment of this invention and on two other alloys.
  • FIG. 6 is a graphical comparison of oxidation data from tests performed at 1010°C (1850°F) on one embodiment of the present invention and on two other alloys.
  • FIG. 7 is a graphical comparison of alloy strength and oxidation data from tests performed on one embodiment of this invention and on six other alloys.
  • DESCRIPTION OF THE PREFERRED EMBODIMENTS
  • The hot corrosion resistant nickel-based superalloy of the present invention comprises the following elements in percent by weight:
    Chromium about 14.2-15.5
    Cobalt about 2.0-4.0
    Molybdenum about 0.30-0.45
    Tungsten about 4.0-5.0
    Tantalum about 4.5-5.8
    Columbium about 0.05-0.25
    Aluminum about 3.2-3.6
    Titanium about 4.0-4.4
    Hafnium about 0.01-0.06
    Nickel + Incidental impurities balance
    This superalloy composition also has a phasial stability number NV38 less than about 2.45. Further, this invention has a critically balanced alloy chemistry which results in a unique blend of desirable properties useful for industrial and marine gas turbine engine applications. These properties include a superior blend of bare hot corrosion resistance and creep-rupture strength relative to prior art single crystal superalloys for industrial and marine gas turbine applications, bare oxidation resistance, single crystal component castability, and microstructural stability, including resistance to TCP phase formation under high stress, high temperature conditions.
  • Superalloy chromium content is a primary contributor toward attaining superalloy hot corrosion resistance. The superalloys of the present invention have a relatively high chromium content since alloy hot corrosion resistance was one of the primary design criteria in the development of these alloys. The chromium is about 14.2-15.5% by weight. Advantageously, the chromium content is from 14.3% to 15.0% by weight. Although chromium provides hot corrosion resistance, it may also assist with the alloys' oxidation capability. Additionally, this superalloys' tantalum and titanium contents, as well as its Ti:Al ratio being greater than 1, are beneficial for hot corrosion resistance attainment. However, besides lowering the alloys' gamma prime solvus, chromium contributes to the formation of Cr and W-rich TCP phase and must be balanced accordingly in these compositions.
  • In one embodiment of the present invention, the cobalt content is about 2.0-4.0% by weight. In another embodiment of the present invention, the cobalt content is from 2.5% to 3.5% by weight. The chromium and cobalt levels in these superalloys assist in making the superalloy solution heat treatable, since both elements tend to decrease an alloy's gamma prime solvus. Proper balancing of these elements in the present invention in tandem with those which tend to increase the alloy's incipient melting temperature, such as tungsten and tantalum, result in superalloxy compositions which have desirable solution heat treatment windows (numerical difference between an alloy's incipient melting point and its gamma prime solvus), thereby facilitating full gamma prime solutioning. The cobalt content is also beneficial to the superalloy's solid solubility.
  • The tungsten content is about 4.0-5.0% by weight and, advantageously, the amount of tungsten is from 4.2% to 4.8% by weight. Tungsten is added in these compositions since it is an effective solid solution strengthener and it can contribute to strengthening the gamma prime. Additionally, tungsten is effective in raising the alloy's incipient melting temperature.
  • Similar to tungsten, tantalum is a significant solid solution strengthener in these compositions, while also contributing to enhanced gamma prime particle strength and volume fraction. The tantalum content is about 4.5-5.8% by weight and, advantageously, the tantalum content is from 4.8% to 5.4% by weight. In these compositions, tantalum is beneficial since it helps to provide bare hot corrosion and oxidation resistance, along with aluminide coating durability. Additionally, tantalum is an attractive single crystal alloy additive in these compositions since it assists in preventing "freckle" defect formation during the single crystal casting process Farticularly when present in greater proportion than tungsten (i.e., the ratio is greater than 1). Furthermore, tantalum is an attractive means of strength attainment in these alloys since it is believed not to directly participate in TCP phase formation.
  • The molybdenum content is about 0.30-0.45% by weight. Advantageously, molybdemm is present in an amount of from 0.35% to 0.43% by weight. Molybdenum is a good solid solution strengthener, but it is not as effective as tungsten and tantalum, and it tends to be a negative factor toward hot corrosion capability. However, since the alloy's density is always a design consideration, and the molybdenum atom is lighter than the other solid solution strengtheners, the addition of molybdenum is a means of assisting control of the overall alloy density in the compositions of this invention. It is believed that the relatively low molybdenum content is unique in this class of bare hot corrosion resistant nickel-based single crystal superalloys.
  • The aluminum content is about 3.2-3.6% by weight. Furthermore, the amount of aluminum present in these compositions is advantageously from 3.3% to 3.5% by weight. Aluminum and titanium are the primary elements comprising the gamma prime phase, and the sum of aluminum plus titanium in the present invention is from 7.2 to 8.0 percent by weight. These elements are added in these compositions in a proportion and ratio consistent with achieving adequate alloy castability, solution heat treatability, phasial stability and the desired blend of high mechanical strength and hot corrosion resistance. Aluminum is also added to these alloys in proportions sufficient to provide oxidation resistance.
  • The titanium content is about 4.0-4.4% by weight. Advantageously, titanium is present in this composition in an amount from 4.1% to 4.3% by weight. These alloys' titanium content is relatively high and, therefore, is beneficial to the alloys' hot corrosion resistance. However, it can also have a negative effect on oxidation resistance, alloy castability and alloy response to solution heat treatment. Accordingly, it is critical that the titanium content is maintained within the stated range of this composition and the proper balancing of the aforementioned elemental constituents is maintained. Furthermore, maintaining the alloys' Ti:Al ratio greater than 1 is critical in achieving the desired bare hot corrosion resistance in these compositions.
  • The columbium content is about 0.05%-0.25% by weight and, advantageously, the columbium content is from 0.05% to 0.12% by weight. Columbium is a gamma prime forming element and it is an effective strengthener in the nickel-based superalloys of this invention. Generally, however, columbium is a detriment to alloy oxidation and hot corrosion properties, so its addition to the compositions of this invention is minimized. Moreover, Columbium is added to this invention's compositions for the purpose of gettering carbon, which can be chemi-sorbed into component surfaces during non-optimized vacuum solution heat treatment procedures. Any carbon pick-up will tend to form columbium carbide instead of titanium or tantalum carbide, thereby preserving the greatest proportion of titanium and/or tantalum for gamma prime and/or solid solution strengthening in these alloys. Furthermore, it is critical that the sum of columbium plus hafnium is from 0.06 to 0.31 percent by weight in these compositions in order to enhance the strength of these superalloys.
  • The hafnium content is about 0.01%-0.06% by weight and, advantageously, hafnium is present in an amount from 0.02% to 0.05% by weight. Hafnium is added in a small proportion to the present compositions in order to assist with coating performance and adherence. Hafnium generally partitions to the gamma prime phase.
  • The balance of this invention's superalloy compositions is comprised of nickel and small amounts of incidental impurities. Generally, these incidental impurities are entrained from the industrial process of production, and they should be kept to the least amount possible in the composition so that they do not affect the advantageous aspects of the superalloy. For example, these incidental impurities may include up to about 0.05 percent carbon, up to about 0.03 percent boron, up to about 0.03 percent zirconium, up to about 0.25 percent rhenium, up to about 0.10 percent silicon, and up to about 0.10 percent manganese. Amounts of these impurities which exceed the stated amounts could have an adverse effect upon the resulting alloy's properties.
  • Not only does the superalloy of this invention have a composition within the above specified ranges, but it also has a phasial stability number NV3B less than about 2.45. As can be appreciated by those skilled in the art, NV3B is defined by the PWA N-35 method of nickel-based alloy electron vacancy TCP phase control factor calculation. This calculation is as follows
  • EQUATION 1
  • Conversion for weight percent to atomic percent: Atomic percent of element i = Pi = Wi/AiΣi (Wi/Ai) X100 where:
  • Wi = weight percent of element i
  • Ai = atomic weight of element i
  • EQUATION 2
  • Calculation for the amount of each element present in the continuous matrix phase:
    Element Atomic amount Rii remaining
    Cr RCr=0.97PCr-0.375PB-1.75PC
    Ni RNi=PNi+0.525PB-3(PAl+0.03PCr+PTi-0.5PC+0.5PV+PTa+PCb+PRf)
    Ti, Al, B, C, Ta, Cb, Hf Ri=O
    V Rv=0.5PV
    W R(W)=PW-0.167PC PW / PMo +PW
    Mo R(Mo)=P(Mo)-0.75PB-0.167PC PMo / (PMo+PW)
  • EQUATION 3
  • Calculation of Nv3B using atomic factors from Equations 1 and 2 above:
    Figure 00130001
    where:
  • i = each individual element in turn.
  • Nii = the atomic factor of each element in matrix.
  • (Nv)i = the electron vacancy No. of each respective element.
  • This calculation is exemplified in detail in a technical paper entitled "PHACOMP Revisited", by H. J. Murphy, C. T. Sims and A. M. Beltran, published in Volume 1 of International Symposium on Structural Stability in Superalloys (1968), the disclosure which is incorporated by reference herein. As can be appreciated by those skilled in the art, the phasial stability number for the superalloys of this invention is critical and must be less than the stated maximum to provide a stable microstructure and capability for the desired properties under high temperature, high stress conditions. The phasial stability number can be determined empirically, once the practitioner skilled in the art is in possession of the present subject matter.
  • The superalloys of this invention can be used to suitably make single crystal articles, such as components for industrial and marine gas turbine engines. Preferably, these superalloys are utilized to make a single crystal casting to be used under high stress, high temperature conditions characterized by an increased resistance to hot corrosion (sulfidation) under such conditions, particularly high temperature conditions involving corrosive atmospheres containing sulfur, sodium and vanadium contaminants, up to about 1922°F (1050°C). While these superalloys can be used for any purpose requiring high strength castings produced as a single crystal, their particular use is in the casting of single crystal blades and vanes for industrial and marine gas turbine engines.
  • The single crystal components made from this invention's compositions can be produced by any of the single crystal casting techniques known in the art. For example, single crystal directional solidification processes can be utilized, such as the seed crystal process and the choke process.
  • The single crystal castings made from the superalloys of the present invention can be aged at a temperature of from about 1800°F (982°C) to about 2125°F (1163°C) for about 1 to about 50 hours. However, as can be appreciated by those skilled in the art, the optimum aging temperature and time for aging depends on the precise composition of the superalloy.
  • This invention provides superalloy compositions having a unique blend of desirable properties. These properties include: excellent bare hot corrosion resistance and creep-rupture strength; good oxidation resistance; good single crystal component castability, particularly for large blade and vane components; good solution heat treatment response; adequate resistance to cast component recrystallization; adequate component coatability and microstructural stability, such as long-term resistance to the formation of undesirable, brittle phases called topologically close-packed (TCP) phases.
    As noted above, this superalloy has a precise composition with only small permissible variations in any one element if the unique blend of properties is to be maintained.
  • In order to more clearly illustrate this invention and provide a comparison with representative superalloys outside the claimed scope of the invention, the examples set forth below are presented. The following examples are included as being illustrations of the invention and its relation to other superalloys and articles, and should not be construed as limiting the scope thereof.
  • EXAMPLES
  • Test materials were prepared to investigate the compositional variations and ranges for the superalloys of the present invention. One of the alloy compositions tested and reported below falls outside the claimed scope of the present invention, but is included for comparative purposes to assist in the understanding of the invention. Representative alloy aim chemistries of materials tested are reported in Table 1 below.
    AIM CHEMISTRIES
    ELEMENT CMSX-11C CMSX-11C' CMSX-11C" CMSX-11B
    C Lap Lap Lap Lap
    Cr 14.5 14.5 14.4 12.5
    Co 3.0 2.5 2.9 6.0
    Mo .40 .35 .40 0.55
    W 4.4 4.6 4.5 5.0
    Ta 4.95 5.1 5.1 5.15
    Cb .10 .08 .10 0.20
    Al 3.40 3.40 3.4 3.60
    Ti 4.20 4.15 4.2 4.20
    Hf .04 .03 .04 0.040
    Ni BAL BAL BAL BAL
    Nv3B 2.41 2.40 2.42 2.42
    NOTE: Chemistries are in wt. %.
  • Test materials defined by the CMSX® -11C aim chemistry shown in Table 1 were initially produced by mixing 15 lbs. of the heat R2D2 alloy (see Table 2 below) with 8 lbs. of virgin materials, melting and subsequently pouring the melt into a ceramic shell mold. (CMSX is a registered trademark of Cannon-Muskegon Corporation, assignee of the present application).
  • Nineteen (19) each ⅜" diameter x 6" long test bars plus three (3) each solid turbine blades were investment cast with the resulting blended product. Specimen inspection revealed satisfactory grain yield with only one test bar rejectable for mis-orientation. No freckles were apparent. Furthermore, a test-bar chemistry check indicated that the CMSX-11C aim composition was attained.
  • Further test materials were obtained with alloy product which was VIM produced in 250 -270 1b. (113-122 kg.) quantities. The VIM heats that were produced and their respective chemistries are reported in Table 2 below.
    Figure 00190001
  • Small quantities of these materials were re-melted and precision investment cast into both bar and blade configurations.
  • Grain and orientation inspections for product that was investment cast yielded satisfactory results. Generally, the aim compositions reported in Table 1 above, resulting in product reported in Table 2, yielded SX cast parts which were single crystal, void of spurious grain and/or sliver indications, free of apparent freckles, possessed orientations generally within 10° of the desired primary (001) crystallographic orientation, and met the compositional requirements.
  • Some of the test specimens produced were used to develop appropriate solution heat treatment procedures, with the results reported in Table 3 below. Complete coarse γ' and eutectic γ-γ' solutioning was achieved with a peak solution temperature of 2309°F (1265°C) applied. But variable levels of test specimen recrystallization, occurring during solution heat treatment, was observed. This problem was alleviated by reducing the CMSX-11C alloy peak solution temperature to 2289°F (1254°C), where full γ' solutioning still prevailed.
  • Similarly, the other two compositional variants listed in Table 1 (CMSX-11C' and CMSX-11C") were solution treated to a peak temperature of 2289°F (1254°C) with similar results.
  • All test specimens were further heat treated by aging initially at 2050°F (1121°C) to encourage a desirable γ' morphology and distribution, followed by secondary ages at 1600°F (871°C) and 1400°F (760°C), respectively (see Table 3 below).
    HEAT TREATMENT
    ALLOY PEAK SOLUTION TEMP. °F (°C) % SOLUTIONING AGING TREATMENT
    CMSX-11C 2309 (1265) 100 2050°F/5 Hrs/AC
    1600°F/24 Hrs/AC
    1400°F/30 Hrs/AC
    and
    2289(1254) 100 2050°F/5 Hrs/AC
    1600°F/24 Hrs/AC
    1400°F/30 Hrs/AC
    CMSX-11C' 2289 (1254) 100 2050°F/5 Hrs/AC
    and CMSX-11C" 1600°F/24 Hrs/AC
    1400°F/30 Hrs/AC
  • Differential Thermal Analysis (DTA) of the VIM heats (reported in Table 2 above) produced respective alloy solidus and liquidus data. The DTA detail is reported in Table 4 below.
    DTA DATA
    HEAT SOLIDUS °F (°C) LIQUIDS °F(°C)
    VF 998 2296 (1258) 2404 (1318)
    VG 33 2298 (1259) 2403 (1317)
    VG 110 2305 (1263) 2408 (1320)
    VG 113 2300 (1260) 2402 (1317)
    VG 148 2302 (1261) 2414 (1323)
    VG 175 2306 (1263) 2412 (1322)
  • Following heat treatment, test bars were machined and low-stress ground to ASIM standard proportional specimen dimension for subsequent stress - and creep-rupture testing at various conditions of temperature and stress, according to standard ASTM procedure. Specimens removed from solid turbine blades were prepared similarly.
  • Table 5 below shows the results of stress - and creep-rupture tests undertaken with the CMSX-11C alloy specimens. The tests were performed at conditions ranging 1400-1900°F (760-1038°C).
  • Most of the tests reported in Table 5 were undertaken with alloy originating from the previously detailed heat R2D2/virgin material blending along with product from heat VF 998. Test results for materials produced with heat VG 33 product are highlighted in Table 5. No rupture tests were performed with product originating from the remaining VIM heats listed in Table 2 above.
    STRESS - AND CREEP-RUPTURE DATA
    CMSX-11C Alloy
    TEST CONDITION RUPTURE TIME HRS EL % RA % FINAL CREEP READING FINAL CREEP READING TIME IN HRS TO REACH
    T, HRS % DEFORMATION 1.0% 2.0%
    1400°F/95.0 ksi 681.8 10.8 15.7 681.1 10.331 56.6 215.8
    (760°C/655 MPa) 627.6 14.3 17.8 - - - -
    677.4 14.4 17.8 - - - -
    220.9 5.5 8.0 - - - -
    321.6 5.5 7.8 - - - -
    418.4 8.9 10.7 417.1 7.842 100.8 232.6
    317.7 11.3 17.0 316.5 10.405 97.8 182.2
    1600°F/50.0 ksi 977.1 9.2 13.1 975.8 8.550 264.6 553.8
    (871°C/345 MPa)
    1600°F/55.0 ksi 294.7 10.6 12.5 - - - -
    (871°C/379 MPa) 621.3 15.9 16.2 - - - -
    314.3 8.4 9.2 - - - -
    366.4 5.5 9.2 - - - -
    251.6 7.4 10.8 251.3 6.278 116.6 198.7
    228.6 9.2 18.0 227.3 5.902 123.7 190.9
    461.8 9.0 13.4 461.1 7.858 154.9 330.1
    1650°F/45.0 ksi 702.8 11.5 18.9 701.1 9.421 162.7 337.8
    (899°C/310 MPa) 564.1 12.4 17.6 - - - -
    645.9 12.7 11.6 - - - -
    481.9 11.2 12.6 - - - -
    442.2 9.5 11.4 - - - -
    295.2 5.9 10.6 295.1 4.918 186.9 262.7
    336.4 9.6 16.4 334.8 7.288 176.5 275.2
    281.2 8.5 11.8 279.9 6.100 92.9 213.8
    524.5 9.1 13.8 523.9 6.779 203.2 405.5
    1652°F/21.76 ksi 9921.2 7.5 14.8 9912.5 6.107 6329.2 8374.9
    (900°C/150 MPa) 12373.1 8.3 14.7 12366.0 6.474 8976.2 10885.1
    1700°F/36.0 ksi 871.4 11.2 16.1 869.2 9.409 179.6 451.4
    (927°C/248 MPa) + 696.6 16.7 32.3 - - - -
    +745.1 15.6 23.1 - - - -
    592.3 12.6 13.8 - - - -
    513.9 12.9 16.4 - - - -
    302.3 11.4 22.1 301.3 7.376 203.5 260.4
    290.8 9.8 21.9 290.6 8.061 197.7 255.8
    487.6 8.4 15.2 487.5 7.203 263.6 417.4
    1750°F/30.0 ksi 473.6 11.8 23.4 - - - -
    (954°C/207 MPa) +770.6 18.1 30.8 - - - -
    419.3 - 13.8 - - - -
    ++526.7 14.1 13.8 - - - -
    1124.8 10.4 11.0 1124.5 7.049 529.5 924.3
    279.5 10.6 23.6 278.1 7.173 190.0 246.5
    615.8 5.8 8.9 615.3 5.000 301.1 539.9
    458.4 - - - - - -
    1750°/20.0/30.0 ksi*
    (954°C/138/207 MPa) 2057.9 13.1 26.7 2057.1 11.892. 1748.1 1905.7
    1800°F/25.0 ksi 1082.1 12.1 32.2 1081.5 9.769 268.4 870.9
    (982°C/172 MPa) 599.7 15.3 29.6 - - - -
    447.8 16.3 30.4 - - - -
    367.3 10.7 13.1 - - - -
    366.6 10.3 14.5 - - - -
    1511.6 4.3 11.6 1511.4 3.403 908.5 1449.1
    577.0 7.8 18.3 575.6 6.239 331.8 524.9
    479.2 6.4 14.5 477.7 5.057 266.2 438.1
    571.2 - - - - - -
    1060.8 7.0 19.7 1059.4 5.354 333.9 979.1
    891.4 - - - - - -
    Running at 620 Hrs
    1850°F/15.0 ksi 5381.8 7.2 24.8 5381.2 4.066 4671.9 5293.3
    (1010°C/172 MPa) Running at 3798.8 Hrs., 1.250% Deformation 2134.0
    1850°F/25.0 ksi 510.5 6.1 31.3 509.1 4.770 88.3 442.4
    (1010°C/172 MPa) 446.2 7.4 32.0 445.1 5.031 57.8 367.2
    518.1 8.1 36.1 579.6 6.184 109.0 457.5
    734.4 6.7 27.6 733.7 4.302 80.5 662.4
    1900°F/18.0 ksi 1904.9 4.9 20.8 1904.6 2.877 1160.2 1888.0
    (1038°C/124 MPa) 1981.0 5.9 18.1 1974.9 2.493 104.7 1946.4
    1714.0 4.0 9.4 1711.4 2.875 377.4 1633.7
    2097.7 5.0 16.4 2094.2 2.412 727.7 2087.0
  • Selected rupture test specimens were reviewed metallographically following testing. None of the ruptured specimens which were reviewed exhibited any observable signs of undesirable microstructural instability, ie., formation of Topologically-Close-Packed (TCP) phases such as sigma, mu or others.
  • Additionally, two test bars were exposed to 1600°F/39.2 ksi (870°C/270 MPa) condition for 200 hours. The respective bar gage sections were then reviewed and no sign of deleterious phase formation was observed.
  • Initial Low Cycle Fatigue (LCF) test results are reported in Table 6 below. The results of the strain-controlled tests undertaken at 1112°F (600°C) are compared to the typical capabilities of selected other alloys, such as single crystal CMSX-2 alloy, DS and equiaxed CM 247 LC® alloy and DS René 80 H alloy.
    PLAIN LOW CYCLE FATIGUE
    1112° F (600°C) ; Strain-controlled (∈TOTAL = 1.106);
    R = O; 0.25 Hz
    Alloy Cycles to Failure
    CMSX-11C 12,130; 7,980
    CMSX-2 10,000
    DS CM 247 LC d 5,000
    DS RENÉ 80 H 1,500
    CC CM 247 LC 90
  • Concurrent to the previously detailed evaluations, fully heat treated CMSX-11C test specimens were subjected to bare oxidation and hot corrosion testing.
  • The results of hot corrosion tests performed are reported in Table 7 below. The tests were undertaken at 1292°F (700°C) and 1472°F (800°C) in a laboratory furnace utilizing an artificial ash plus SO2. Metal loss data are reported as mean and maximum values, as well as a percentage loss of the test pin employed. Data are reported for intervals of 100, 576 and 1056 hours for the 1292°F (700°C) test, and 100, 576, 1056 and 5000 hours for the 1472°F (800°C) test.
    CMSX-11C HOT CORROSION (crucible test with synthetic slag)
    TEST TEMPERATURE: 700°C (1292°F)
    EXPOSURE TIME (HRS.) METAL LOSS (microns) PERCENTAGE METAL LOSS
    MEAN MAXIMUM
    100 34.5 39 2.70
    576 90.5 102 7.05
    1056 120.5 143.5 9.27
    TEST TEMPERATURE: 800°C (1472°F)
    100 56.5 112.5 4.41
    576 366.5 394.5 26.97
    1056 2520 2520 100.00
    5000 2520 2520 100.00
  • Similarly, Figure 1 illustrates the results of additional hot corrosion tests undertaken with CMSX-11C alloy and other alloys to 500 hours exposure in synthetic slag (GTV Type) plus .03 volume percent SOx in air. The 500 hour tests were undertaken at 1382, 1562, 1652°F, (750, 850 and 900°C). The results indicate that the CMSX-11C alloy provides extremely good corrosion resistance at all three test temperatures.
  • Subsequent testing utilizing an alternative slag, type FW, with test temperatures of 1472*F and 1652°F (800, 900°C), was also undertaken. The 500 hour test results are reported in Table 8 below and illustrate a performance benefit derived from the CMSX-11C alloys having a higher chromium content compared to the 12.5% - containing CMSX-11B alloy.
    CMSX-11C Alloy vs. IN 738 LC Alloy vs. CMSX-11B Alloy Hot Corrosion
    Results presented represent depth of penetration after 500 hours exposure in synthetic slag (type FVV) plus 0.03% SOx in air.
    •   Test Temperature - 800*C (1472°F)
    Alloy Maximum Penetration Average Penetration
    CMSX-11C 160 µm 140 µm
    CMSX-11B 350 µm 170 µm
    •   Test Temperature ― 900°C (1652°F)
    Alloy Maximum Penetration Average Penetration
    CMSX-11C 150 µm 130 µm
    IN 738 LC - 190 µm
    CMSX-11B 220 µm 150 µm
  • Additional laboratory furnace, crucible type, artificial ash hot corrosion tests were performed. The results of these tests, undertaken at 1350°F (732*C) and 1650°F (899°C), are illustrated in Figures 2 and 3, respectively. In these tests, the specimens were coated with 1 mg./cm2 Na2SO4 every 100 cycles and were cycled 3 times per day. Both tests were run to about 2400 hours. These results further demonstrate an improved level of hot corrosion resistance obtained with the CMSX-11C alloy vs. the CMSX-11B material.
  • Further hot corrosion tests were performed with the CMSX-11C alloy, along with other materials for comparative purposes. In contrast to the aforementioned tests, these hot corrosion evaluations were performed in burner rigs, which is usually a preferred method of testing since the results achieved in burner rig tests generally give more representative indications of the way materials will perform in a gas turbine engine.
  • The burner rig tests were performed at 1652°F (900°C) and 1922°F (1050°C), and the test results are reported below in Tables 9 and 10, respectively. The .35 in. (9 mm) diameter x 3.9 in. (100 mm) long test pins utilized were mounted in a rotating cylindrical jig and exposed to a high speed gas stream. Other test conditions were as specified in the respective Tables.
    900°C (1652°F) HOT CORROSION (BURNER RIG.)
    Weight Loss In Grams As a Function of Time
    ALLOY Hrs. 100 200 300 400 500
    CMSX-11B .005 .015 .01 -.01 .03
    CMSX-11C -.04 .005 -.015 -.045 .013
    FSX 414 .015 .045 .04 .04 .085
    RENÉ 80 H .075 .275 .365 .46 .495
    IN 738 LC .015 .08 .10 .15 .195
    IN 939 -.07 -.09 -.14 -.15 -.06
    CM 186 LC .08 .195 .30 .395 .44
    CONDITIONS
    1 temperature, time 900°C - 500 hrs (max)
    2 burning gas flow rate 6 Nm3/min.
    3 petroleum flow rate 9 ℓ/hr.
    4 salt water 6 cc/min.
    5 sulfuric oil 6 cc/min.
    1050°C (1922°F) HOT CORROSION (BURNER RIG.)
    Weight Loss In Grams As a Function of Time
    ALLOY Hrs. 100 200 300 400 500
    CMSX-11B 0.1 0.7 1.15 2.5 -
    CMSX-11C 0.04 0.05 1.22 1.55 1.65
    FSX 414 0.2 0.39 0.5 0.65 0.9
    RENÉ 80 H 0.18 0.38 0.47 1.45 1.68
    IN 738 LC 0.1 0.43 1.35 2.09 2.33
    IN 939 0.1 0.22 0.26 0.45 0.65
    CM 186 LC 0.6 2.9 - - 13.7
    CONDITIONS
    1 temperature, time 1050° C - 500 hrs (max)
    2 burning gas flow rate 6 Nm3/min SOx :257 - 287 ppm
    3 petroleum flow rate 18 ℓ/min NaCl :17.8 - 18.2 mg/m3
    4 NaCl solution 6 cc/min Na2SO4 :<0.5 mg/m 3
    5 sulphuric oil 7 cc/min
  • The results of the tests indicate that the CMSX-11C alloy provided much better hot corrosion resistance than the IN 738 LC alloy at both test temperatures, and also performed superior to the CMSX-11B alloy.
    Furthermore, Figure 4 illustrates that CMSX-11C alloy provides an attractive blend of strength and hot corrosion resistance at 1922°F (1050°C), and most notably, outperforms the commercially, widely used DS René 80 H alloy. It is believed that a similar analysis at 900°C would illustrate an even greater blend of capability.
  • CMSX-11C alloy oxidation tests were performed concurrent to the hot corrosion tests. Table 11 below reports the results of a crucible oxidation test performed at 1742°F (950°C) for 1000 hour duration within a laboratory furnace. Mean and maximum oxidation depth plus weight gain measurements recorded at 100 and 500 hour intervals are reported, as well as at test completion.
    CMSX-11C HOT OXIDATION
    TEST TEMPERATURE: 950°C (1742°F)
    EXPOSURE TIME (HRS.) OXIDATION DEPTH (microns) WEIGHT GAIN (GRAMS)
    MEAN MAXIMUM
    100 3.6 14.7 1.30E-03
    500 5.6 11.9 2.40E-03
    1000 8.7 19.6 3.10E-03
    5000
  • Slightly higher temperature oxidation test results are presented in Figure 5. The data illustrated are the result of oxidation tests run at 1832°F (1000°C) and to as long as 3000 hour duration. The tests were performed in an air atmosphere, and measured test specimen weight change as a function of time. The test temperature was cycled to room temperature on a once-per-hour basis. The test results indicate that the CMSX-11C alloy provides much better oxidation resistance than IN 738 LC, an alloy which is widely used throughout the industrial turbine industry.
  • Further oxidation test results are illustrated in Figure 6. In this particular test, the pins were cycled to room temperature 3 times per day from the 1850°F (1010°C) test temperature, and weight change measured as a function of time. The test was run to about 2400 hours and the results indicate that the CMSX-11C material provides much better oxidation resistance than the alloy IN 738 LC.
  • Burner rig oxidation testing was undertaken at 2192°F (1200°C), with the results presented in Table 12 below. Various alloys were tested within the same rotating carousel. Specimen weight loss was measured at intervals of 100, 200, 300, 400 and 500 hours. Additional test conditions are provided in the Table.
    1200°C (2192°F) OXIDATION (BURNER RIG.)
    Weight Loss In Grams As a Function of Time
    ALLOY
    100 200 300 400 500 Hrs.
    CMSX-11R .002 .005 .011 .012 .026
    CMSX-11C .002 .005 .009 .01 .022
    FSX 414 .02 .077 .085 .12 .125
    RENÉ 80 H .002 .005 .014 .20 .35
    IN 738 LC .005 .034 .049 .064 .095
    IN 939 .016 .038 .064 .077 .113
    CM 186 LC .002 .01 .01 .015 .013
    CONDITIONS
    1 temperature, time 1200°C - 500 hrs (max)
    2 burning gas flow rate 6 Nm3/min
    3 petroleum flow rate 18 - 20 ℓ/min
    4 burning pressure 11 kgf/cm2
  • The burner rig oxidation test results illustrate that the CMSX-11C material provides extremely good 2192°F (1200°C) oxidation resistance in comparison to widely used industrial turbine blade and vane materials.
  • An alloy strength and 2192°F (1200°C) oxidation comparrison is illustrated in Figure 7. This Figure illustrates that the CMSX-11C alloy blended capability is superior to directional solidified alloys such as René 80 H, FSX 414, IN 939 and IN 738 LC alloys.
  • While this invention has been described with respect to particular embodiments thereof, it is apparent that numerous other forms and modifications of this invention will be obvious to those skilled in the art. the appended claims and this invention generally should be construed to cover all such obvious forms and modifications which are within the true spirit and scope of the present invention.

Claims (20)

  1. A hot corrosion resistant nickel-based superalloy comprising the following elements in percent by weight: Chromium about 14.2-15.5 Cobalt about 2.0-4.0 Molybdenum about 0.30-0.45 Tungsten about 4.0-5.0 Tantalum about 4.5-5.8 Columbium about 0.05-0.25 Aluminum about 3.2-3.6 Titanium about 4.0-4.4 Hafnium about 0.01-0.06 Nickel + Incidental Impurities balance
    said superalloy having a phasial stability number NV3B less than about 2.45.
  2. The superalloy of Claim 1 further comprising the following elements in percent by weight: Carbon about 0-0.05 Boron about 0-0.03 Zirconium about 0-0.03 Rhenium about 0-0.25 Silicon about 0-0.10 Manganese about 0-0.10
  3. The superalloy of Claim 1 wherein the sum of columbium plus hafnium is from 0.06 to 0.31 percent by weight.
  4. The superalloy of Claim 1 wherein the Ti:Al ratio is greater than 1.
  5. The superalloy of Claim 1 wherein the sum of aluminum plus titanium is from 7.2 to 8.0 percent by weight.
  6. The superalloy of Claim 1 wherein Ta:W ratio is greater than 1.
  7. The superalloy of Claim 1 wherein said superalloy has an increased resistance to oxidation.
  8. A single crystal article made from the superalloy of Claim 1.
  9. The single crystal article of Claim 7, wherein the article is a component for a turbine engine.
  10. The article of Claim 11, wherein the component is a gas turbine blade or gas turbine vane.
  11. A single crystal casting characterized by an increased resistance to hot corrosion, said casting being made from a nickel-based superalloy comprising the following elements in percent by weight: Chromium 14.3-15.0 Cobalt 2.5-3.5 Molybdenum 0.35-0.43 Tungsten 4.2-4.8 Tantalum 4.8-5.4 Columbium 0.05-0.12 Aluminum 3.3-3.5 Titanium 4.1-4.3 Hafnium 0.02-0.05 Nickel + Incidental Impurities balance
    said superalloy having a phasial stability number NV3B less than about 2.45.
  12. The single crystal casting of Claim 10 further comprising the following elements in percent by weight: Carbon 0-0.05 Boron 0-0.03 Zirconium 0-0.03 Rhenium 0-0.25 Silicon 0-0.10 Manganese 0-0.10.
  13. The single crystal casting of Claim 10 wherein the sum of columbium plus hafnium is from 0.06 to 0.31 percent by weight.
  14. The single crystal casting of Claim 10 wherein the sum of aluminum plus titanium is from 7.2 to 8.0 percent by weight.
  15. The single crystal casting of Claim 10 wherein both the Ti:Al ratio and the Ta:W ratio are greater than 1.
  16. The single crystal casting of Claim 10 wherein said casting has an increased resistance to oxidation.
  17. The single crystal casting of Claim 10 wherein said casting has an increased creep-rupture strength.
  18. The single crystal casting of Claim 10 wherein said casting is a gas turbine blade or gas turbine vane.
  19. A single crystal casting characterized by an increased resistance to hot corrosion, said casting being made from a nickel-based superalloy comprising the following elements in percent by weight: Chromium about 14.5 Cobalt about 3.0 Molybdenum about 0.40 Tungsten about 4.4 Tantalum about 4.95 Columbium about 0.10 Aluminum about 3.40 Titanium about 4.2 Hafnium about 0.04 Carbon about 0-0.05 Boron about 0-0.03 Zirconium about 0-0.03 Rhenium about 0-0.25 Silicon about 0-0.10 Manganese about 0-0.10 Nickel balance
    said superalloy having a phasial stability number NV3B less than about 2.45, wherein the sum of columbium plus hafnium is from 0.06 to 0.31 percent by weight, the sum of aluminum plus titanium is from 7.2 to 8.0 percent by weight, the Ti:Al ratio is greater than 1, and the Ta:W ratio is greater than 1.
  20. The single crystal casting of Claim 18 wherein said casting is a gas turbine blade or gas turbine vane.
EP95116194A 1995-10-13 1995-10-13 Hot corrosion resistant single crystal nickel-based superalloys Expired - Lifetime EP1127948B1 (en)

Priority Applications (5)

Application Number Priority Date Filing Date Title
AT95116194T ATE221138T1 (en) 1995-10-13 1995-10-13 SINGLE CRYSTALLINE SUPER ALLOYS WITH GOOD CORROSION RESISTANCE AT HIGH TEMPERATURES
EP95116194A EP1127948B1 (en) 1995-10-13 1995-10-13 Hot corrosion resistant single crystal nickel-based superalloys
DE69527557T DE69527557T2 (en) 1995-10-13 1995-10-13 Single-crystalline superalloys with good corrosion resistance at high temperatures
ES95116194T ES2184779T3 (en) 1995-10-13 1995-10-13 NICKEL-BASED MONOCRISTALINE SUPERALEATIONS RESISTANT TO ELEVATED TEMPERATURE CORROOSION.
DK95116194T DK1127948T3 (en) 1995-10-13 1995-10-13 High-temperature corrosion-resistant monocrystalline nickel-based superalloys

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
EP95116194A EP1127948B1 (en) 1995-10-13 1995-10-13 Hot corrosion resistant single crystal nickel-based superalloys

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EP1127948A2 true EP1127948A2 (en) 2001-08-29
EP1127948A3 EP1127948A3 (en) 2001-09-05
EP1127948B1 EP1127948B1 (en) 2002-07-24

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AT (1) ATE221138T1 (en)
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115044805A (en) * 2022-05-30 2022-09-13 北京科技大学 Nickel-based single crystal superalloy with balanced multiple properties and preparation method thereof

Citations (5)

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Publication number Priority date Publication date Assignee Title
GB2153848A (en) * 1984-02-10 1985-08-29 United Technologies Corp High strength hot corrosion resistant single crystals
EP0207874A2 (en) * 1985-05-09 1987-01-07 United Technologies Corporation Substrate tailored coatings for superalloys
US4677035A (en) * 1984-12-06 1987-06-30 Avco Corp. High strength nickel base single crystal alloys
EP0240451A2 (en) * 1986-04-03 1987-10-07 United Technologies Corporation Single crystal articles having reduced anisotropy
EP0577316A2 (en) * 1992-06-29 1994-01-05 Cannon-Muskegon Corporation Single crystal nickel-based superalloy

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2153848A (en) * 1984-02-10 1985-08-29 United Technologies Corp High strength hot corrosion resistant single crystals
US4677035A (en) * 1984-12-06 1987-06-30 Avco Corp. High strength nickel base single crystal alloys
EP0207874A2 (en) * 1985-05-09 1987-01-07 United Technologies Corporation Substrate tailored coatings for superalloys
EP0240451A2 (en) * 1986-04-03 1987-10-07 United Technologies Corporation Single crystal articles having reduced anisotropy
EP0577316A2 (en) * 1992-06-29 1994-01-05 Cannon-Muskegon Corporation Single crystal nickel-based superalloy

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115044805A (en) * 2022-05-30 2022-09-13 北京科技大学 Nickel-based single crystal superalloy with balanced multiple properties and preparation method thereof

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EP1127948B1 (en) 2002-07-24
DE69527557T2 (en) 2002-11-07
DK1127948T3 (en) 2002-11-11
EP1127948A3 (en) 2001-09-05
DE69527557D1 (en) 2002-08-29
ES2184779T3 (en) 2003-04-16
ATE221138T1 (en) 2002-08-15

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