CN115044805B - Nickel-based single crystal superalloy with balanced multiple properties and preparation method thereof - Google Patents
Nickel-based single crystal superalloy with balanced multiple properties and preparation method thereof Download PDFInfo
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Abstract
The invention discloses a nickel-based single crystal superalloy with balanced multiple properties and a preparation method thereof, belonging to the technical field of nickel-based single crystal superalloys. The nickel-based single crystal superalloy comprises the following chemical components in atomic percentage: al: 8.5-10.5 at.%, cr:14.0 to 17.0at.%, mo:1.0 to 1.5at.%, nb: 1.0-1.5 at.%, ta: 1.5-2.0 at.%, W: 0.5-1.0 at.%, re:0.5 to 1.0at.%; v: 1.5-2.0 at.%, and the balance of Ni. Through the selection of components and heat treatment, the prepared nickel-based single crystal superalloy has the characteristics of high theoretical creep property, low harmful phase, proper precipitation strengthening phase, negative lattice mismatching degree, low density, excellent casting stability and wide enough gamma single-phase region.
Description
Technical Field
The invention belongs to the technical field of nickel-based single crystal superalloy, and relates to a nickel-based single crystal superalloy with balanced multiple properties and a preparation method thereof.
Background
The nickel-based single crystal superalloy has excellent high-temperature strength, good oxidation resistance, good hot corrosion resistance, good fatigue performance and good fracture toughness. The nickel-based single crystal superalloy can cope with complex stress environment in the environment of more than 900 ℃, can keep surface stability, and is a common material for aerospace engine blades. The excellent mechanical property of the nickel-based superalloy is the guarantee of stable operation of an aircraft engine and is a key link for promoting the development of aviation industry, so that the excellent mechanical property of the nickel-based superalloy has important significance for the development of aerospace industry in China. The novel high-performance nickel-based single crystal superalloy is beneficial to the production and development of the aviation and aerospace industries in China and also provides a required high-temperature material for the development of other industrial departments.
The excellent properties of nickel-based single crystal superalloys result from a combination of high concentrations of alloying elements, such as CMSX-4+. The alloy contains up to 9 alloying elements, the maximum concentration of which can be up to 10wt.%. Varying the alloy content only within the scope of its patent, at an accuracy of 0.1wt%, yields about 10 6 And (3) an alloy. The large range of alloy compositions forces researchers to conduct research based on empirical testing. Therefore, the development of nickel-based single-machine high temperature is often to continue to add new alloy elements or change the content of certain elements on the basis of the previous series. This means that the developed nickel-based single crystal superalloys were developed using experience. The second generation nickel base single crystal high temperature is added on the basis of the first generation nickel base single crystal high temperature<1at.% rhenium (Re) element, increasing its temperature-bearing capacity by 30 ℃; the third generation nickel base single crystal high temperature promotes Re to 1-2at.% on the basis of the second generation nickel base single crystal high temperature; the fourth generation nickel base single crystal is added with new element ruthenium (Ru) at high temperature.
While many commercial nickel-based single crystal superalloys have good properties, the good properties are not compatible, but some are high and others are low, making it difficult to provide a balance of properties needed for a particular engineering application. Such as PWA1480, have excellent creep resistance, but the processing window is very small. Therefore, it is important to balance the properties of the ni-based single crystal superalloy to meet various use targets.
Chinese patent CN106636759A discloses a platinum group element-reinforced high-thermal stability high-strength nickel-based single crystal superalloy, which contains high-cost cobalt element selection, less chromium content, lower corrosion resistance, and added ruthenium element, and obviously belongs to the fourth generation nickel-based single crystal high temperature; the addition of the iridium element and the hafnium element can further improve the preparation cost, and the prepared material has high density which exceeds 9.0g/cm 3 And the cost is also high.
Chinese patent CN111961920A discloses a high temperature-bearing nickel-based single crystal superalloy and a preparation method thereof, which also belongs to the fourth generation nickel-based single crystal superalloy; the selection cost of alloy elements is high, the temperature bearing capacity exceeds the level of typical third generation single crystal high temperature alloy, and the high temperature endurance performance of the alloy elements is superior to that of part of reported fourth generation single crystal high temperature alloy; however, the method does not have multi-property balance, the oxidation resistance and the cost are sacrificed to improve the mechanical property, and the high solution temperature of the precipitated phase reduces the processing window.
Chinese patent CN111647939A discloses a method for making 2-Ru new type nickel-based single crystal superalloy, which also belongs to the fourth generation nickel-based single crystal superalloy, and does not include the selection of Re/Ru alloy, although it can avoid the precipitation of harmful phase under high temperature condition, so that it has better creep property under medium temperature/high stress and high temperature/low stress condition, but its high precipitation phase dissolution temperature reduces the processing window, and has the problems of higher density, higher ruthenium element cost, and so on, thus it can not make the balance of the multi-properties of the nickel-based single crystal superalloy.
Chinese patent CN109371288A discloses a low-rhenium, high-strength, hot corrosion resistant, nickel-based single crystal superalloy and a method for manufacturing the same, which belong to the third generation of nickel-based single crystal superalloy, but include high-cost cobalt element selection, stabilizing treatment is required between solid solution and aging treatment in heat treatment, the temperature of each stage of heat treatment is high, the cost is high, and thus other properties such as processing window and density cannot balance the multi-properties of the nickel-based single crystal superalloy.
Chinese patent CN106011540A discloses a low-rhenium third-generation nickel-based single crystal alloy and a preparation method thereof, the smelting process is complex, the operation difficulty is large, the heat treatment process is divided into 10 sections of heat treatment, each section of heat treatment is air-cooled to room temperature, a large amount of heat is consumed, and the cost is high; the resulting alloy has a high degree of lattice mismatch and density, as well as a high content of deleterious phases.
Disclosure of Invention
The invention aims to solve the technical problems that in the prior art, the addition cost of the alloy elements of cobalt, iridium and hafnium of a plurality of commercial nickel-based single crystal superalloys is high, the alloy has poor hot corrosion resistance effect and high content of harmful phases; the heat treatment consumes much energy, is complex to operate and cannot balance multiple performances; the alloy has high density, small lattice mismatching degree, poor casting stability, narrow gamma single-phase region, poor high-temperature creep resistance and the like.
The invention provides the following technical scheme:
the nickel-based single crystal superalloy with balanced multiple properties comprises the following chemical components in atomic percentage: al: 8.5-10.5 at.%, cr:14.0 to 17.0at.%, mo:1.0 to 1.5at.%, nb:1.0 to 1.5at.%, ta: 1.5-2.0 at.%, W: 0.5-1.0 at.%, re: 0.5-1.0 at.%; v: 1.5-2.0 at.%, and the balance of Ni.
Wherein Al element is used to form gamma' precipitate and Al is formed 2 O 3 The protective layer improves the corrosion resistance, so the content of Al is set to be 8.5-10.5 at%;
cr can improve the solid solution strengthening effect and form Cr 2 O 3 The protective layer improves the corrosion resistance, and the selection range is 14.0 to 17.0at.%;
mo, W and V promote solid solution strengthening, but the excessive high content can generate TCP phase, so that Mo needs to be controlled to be 1.0-1.5 at.%, W needs to be controlled to be 0.5-1.0 at.%, and V needs to be controlled to be 1.5-2.0 at.%; nb and Ta can improve the antiphase domain boundary energy and the gamma' precipitation content of the high-temperature alloy so as to improve the mechanical property of the alloy, but over high can cause eta phase generation and reduce a processing window, so that Nb is controlled to be 1.0 to 1.5at.%, and Ta is controlled to be 1.5 to 2.0at.%; re can improve creep performance, and the range is 0.5 to 1.0at.%.
Preferably, the chemical components of the nickel-based single crystal superalloy are as follows according to atomic percentage: al:9.0-10.0at.%, cr: 15.0-17.0 at.%, mo:1.0 to 1.5at.%, nb: 1.0-1.5 at.%, ta: 1.5-2.0 at.%, W:1.0at.%, re:1.0at.%; v:2.0at.%, the remainder being Ni.
Preferably, the volume fraction gamma 'of the nickel-based single crystal superalloy is 40.1-49.0 vol%, the dissolution temperature gamma' is 1210-1235 ℃, the existence interval of a gamma single phase zone is 100-125 ℃, the volume fraction of a harmful phase is 0.17-1.02 vol%, the lattice mismatch is-0.0023-0.0002, and the density is 8.65-8.77 g/cm 3 The casting spot resistance index is 0.783-1.101, and the creep resistance index isLabeled 7.504-7.673.
Wherein the gamma prime volume fraction affects the mechanical properties of the superalloy. However, too high a volume fraction of γ 'destroys the γ + γ' system, reducing the mechanical properties. For nickel-base superalloys, the creep life increases and then decreases as the volume fraction of γ' increases. When the volume fraction of gamma' exceeds 40%, the creep life thereof is satisfactory. Thermo-Calc calculations show that the gamma' volume fraction of the alloys of the invention is 40.1 to 49.0vol.%.
The size of the gamma' dissolving temperature directly influences the quenching crackability and the temperature bearing capacity of the alloy. High temperature alloys with high gamma prime dissolution temperatures exhibit a greater tendency to quench cracking; superalloys with too low a gamma prime solution temperature exhibit poor temperature capability. The gamma' dissolution temperature is higher than 1120 ℃ and less than 1250 ℃. The calculated result of Thermo-Calc shows that the gamma' dissolving temperature of the alloy is 1210-1235 ℃.
Superalloys are treated by solution and aging to control the size, volume fraction, and distribution of the gamma prime phase for optimum creep resistance. The solution treatment allows the alloying elements to enter the Ni matrix, and a gamma single-phase region is required to exist. This temperature range is considered to be at least 30 ℃ to meet the requirements. The Thermo-Calc calculation result shows that the gamma single-phase region of the alloy has the existence interval of 100-125 ℃.
When the superalloy is exposed to high temperatures, the deleterious phase phases will be a source of crack propagation, which should be avoided at operating temperatures. The volume of the harmful phase does not exceed 1%. Thermo-Calc calculation results show that the harmful phase volume fraction of the alloy is 0.17-1.02 vol.%.
Lattice mismatch further affects the coherence of the gamma/gamma' interface and thus the creep resistance. The negative lattice mismatch can promote the formation of creep-resistant raft structures and improve creep resistance. The lattice mismatch of the alloy is calculated by adopting a classical theoretical formula and Thermo-Calc, and the result is-0.0022 to-0.0003.
Density is a key issue that limits the application of high temperature alloys. High density superalloys inevitably add weight to the engine at volumes that produce greater stresses in the turbine blades, less dense than9.00g/cm 3 The nickel-based single crystal superalloy meets the requirements. The density of the alloy is 8.65-8.77 g/cm 3 。
The key to improving resistance to casting mottle is to control the distribution of heavier elements between the interdendritic liquid and the dendrite nuclei. Generally, when the casting parameter evaluation index of the nickel-based single crystal superalloy is greater than or equal to 0.7, the alloy has good casting spot resistance. The casting parameter evaluation index of the alloy is 0.783-1.101.
Creep resistance is a key property of nickel-based single crystal superalloys. The time to reach 1% creep strain for practical gas turbine applications is an important indicator for assessing creep resistance of high temperature alloys. Creep resistance index the creep resistance (i.e., creep limit) of a nickel-base superalloy at 1% creep strain may be evaluated, e.g., 5.80 for RR 2000R. The creep resistance index of the alloy is 7.504-7.673.
To satisfy high-temperature oxidation resistance, al and Cr are added to form Al 2 O 3 And Cr 2 O 3 And a protective layer. Document 1 (Metallurgical and Materials transformations a,51 (2020) 4902-4921) proposes a corrosion resistant nickel-base superalloy design region of 8.5-12.0 at.% Al and 13.2-18.0 at.% Cr. The Al content of the alloy is 8.5-10.5 at.%, and the Cr content is 14.0-17.0 at.%.
The preparation method of the nickel-based single crystal superalloy with balanced multiple properties comprises the following steps: the preparation method comprises the following steps of weighing raw materials according to the component ratio, smelting by adopting a vacuum induction arc furnace, casting into a master alloy with chemical components meeting requirements, preparing a single crystal test rod, performing heat treatment on the single crystal test rod, and performing air cooling to obtain the nickel-based single crystal high-temperature alloy with balanced multiple properties.
Preferably, the raw material selection in the preparation method adopts pure Al and nickel-based intermediate alloy.
Preferably, the heat treatment in the preparation method is solution treatment and aging treatment.
Preferably, the temperature of the solution treatment in the preparation method is 1150-1200 ℃, and the time is 3-6 h; the aging treatment is divided into two stages, the temperature of the aging treatment in the first stage is 1170-1230 ℃, the time is 6-8h, and the air cooling is carried out; the temperature of the aging treatment of the second stage is 880-920 ℃, the time is 12-18 h, and air cooling is carried out.
Preferably, the temperature of the solution treatment in the preparation method is 1170 ℃ and the time is 4h; the aging treatment is divided into two stages, the temperature of the aging treatment in the first stage is 1195 ℃, the time is 8 hours, and air cooling is carried out; and the temperature of the aging treatment of the second stage is 900 ℃, the time is 16h, and the air cooling is carried out.
Preferably, the temperature bearing capacity of the nickel-based single crystal superalloy prepared by the preparation method is not less than 1180 ℃.
Compared with the prior art, the invention has the following beneficial effects:
in the scheme, compared with various commercial nickel-based single crystal superalloys in the prior art, the nickel-based single crystal superalloy with balanced multiple properties provided by the invention can realize the balance of the multiple properties of the nickel-based single crystal superalloy.
The nickel-based single crystal superalloy with balanced multiple properties provided by the invention plays a role in selecting the content of components of Al element to form gamma' -precipitation and Al at the same time 2 O 3 The protective layer improves the corrosion resistance; cr enhances the solid solution strengthening effect and forms Cr 2 O 3 The protective layer improves the corrosion resistance; improving solid solution strengthening of Mo, W and V; nb and Ta improve the antiphase domain boundary energy and the gamma' precipitation content of the high-temperature alloy so as to improve the mechanical property of the alloy; re improves creep performance. The method does not contain cobalt element and ruthenium element selection in the fourth-generation nickel-based single crystal superalloy, has simple and easy operation of heat treatment mode and less energy consumption, and is beneficial to industrial large-scale production.
The choice of Cr content in the nickel-based single crystal superalloy with balanced multiple properties, which is provided by the invention, is up to 14at.% which is not available in the prior art, and the hot corrosion resistance is superior to that of the prior art.
In the nickel-based single crystal superalloy with balanced multiple properties, the gamma 'volume fraction and the gamma' dissolution temperature are moderate, the width of a gamma single phase region is obviously superior to that of other commercial nickel-based single crystal superalloys, the density is obviously lower than that of other commercial nickel-based single crystal superalloys, the degree of mismatch of harmful phases and lattices is lower, and the casting spot resistance and the creep resistance are excellent.
In conclusion, the nickel-based single crystal superalloy with balanced multiple properties provided by the invention has the advantages of low component selection cost, simple and convenient heat treatment, low energy consumption, high resource utilization rate, good thermal corrosion resistance and other property balances, and is beneficial to industrial large-scale production.
Drawings
In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.
FIG. 1 is an XRD pattern of a multi-property balanced nickel-base single crystal superalloy of the present invention;
FIG. 2 is a comparison of the gamma prime volume fraction at 900 ℃ of a multi-property balanced nickel-based single crystal superalloy of the present invention with a commercial nickel-based single crystal superalloy;
FIG. 3 is a comparison of the gamma prime solution temperature of a multi-property balanced nickel-based single crystal superalloy of the present invention with a commercial nickel-based single crystal superalloy;
FIG. 4 is a comparison of the width of the gamma-single phase region temperature interval of the multi-property balanced nickel-based single crystal superalloy of the present invention with that of a commercial nickel-based single crystal superalloy;
FIG. 5 is a comparison of the harmful phase content at 900 ℃ of the multi-property balanced nickel-based single crystal superalloy of the present invention with a commercial nickel-based single crystal superalloy;
FIG. 6 is a comparison of lattice mismatch at 900 ℃ for a multi-property balanced nickel-based single crystal superalloy of the present invention and a commercial nickel-based single crystal superalloy;
FIG. 7 is a comparison of density of a multi-property balanced nickel-based single crystal superalloy of the present invention and a commercial nickel-based single crystal superalloy;
FIG. 8 is a comparison of the cast spot resistance of the multi-property balanced nickel-based single crystal superalloys of the present invention with commercial nickel-based single crystal superalloys;
FIG. 9 is a comparison of creep resistance of the multi-property balanced nickel-based single crystal superalloys of the present invention with commercial nickel-based single crystal superalloys;
FIG. 10 is a comparison of Al/Cr addition concentrations for a multi-property balanced nickel-based single crystal superalloy of the present invention with commercial nickel-based single crystal superalloys.
Detailed Description
The following describes technical solutions and technical problems to be solved in the embodiments of the present invention with reference to the embodiments of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the patent of the invention, not all embodiments.
A multi-property balanced Ni-based single crystal superalloy, examples 1-12, has a chemical composition in atomic percent as shown in Table 1.
Weighing raw materials according to the component proportion of examples 1-12 in Table 1, smelting by adopting a vacuum induction arc furnace, casting into a master alloy with chemical components meeting requirements, preparing a single crystal test rod, and finally performing heat treatment on the single crystal test rod, wherein the heat treatment comprises solid solution treatment and aging treatment, the temperature of the solid solution treatment is 1170 ℃, and the time is 4 hours; the aging treatment is divided into two stages, the temperature of the aging treatment in the first stage is 1195 ℃, the time is 8 hours, and air cooling is carried out; the temperature of the aging treatment of the second stage is 900 ℃, the time is 16h, and air cooling is carried out; the nickel-based single crystal superalloy with multiple balanced properties is obtained.
Table 1 chemical composition (at.%) of examples 1-12
The results of the invention using Thermo-Calc for the gamma 'volume fraction at 900 ℃, the gamma' dissolution temperature, the width of the temperature interval of the gamma single phase zone, the content of the harmful phase at 900 ℃ and the lattice mismatch at 900 ℃ for examples 1-12 are shown in table 2.
TABLE 2 Gamma volume fraction at 900 deg.C, gamma' dissolution temperature, width of temperature interval of Gamma monophasic region, content of detrimental phases at 900 deg.C, lattice mismatch at 900 deg.C for examples 1-12
The amount of detrimental phases in the nickel base single crystal superalloy of example 1 is 0.621vol.% at 900 c, as shown by XRD results, which indicate the absence of detrimental phases in the alloy.
The density of the nickel-based single crystal superalloy is measured by a drainage method; carrying out creep life test on the sample after heat treatment and machining; and simultaneously calculating the casting resistance spot and the creep resistance index. Specific results are shown in table 3.
Table 3 density, cast-stain resistance, creep resistance indices for examples 1-12.
FIGS. 2-9 show the results of comparing SA, according to example 5 of the present invention, with 18 commercial single-crystal NI-base superalloys, including AF-56, AM1, AM3, CMSX-6, DD402, DD403, DD404, DD407, DD408, DD426, DD499, MC-NG, PWA1480, ren N4, RR2000, SC-16, SRR99 and CK 7.
In fig. 2, the gamma prime volume fraction of the nickel based single crystal superalloy is shown, and the gamma prime volume fraction of the nickel based single crystal superalloy SA of example 5 is lower than other superalloys but still meets the requirements, and the creep life is 118h.
FIG. 3 shows the gamma prime dissolution temperature of the Ni-based single crystal superalloy, while the gamma prime dissolution temperature of the Ni-based single crystal superalloy SA of example 5 is lower than that of the superalloys (AM 1, AM3, CMSX-6, DD402, DD407, DD499, MC-NG, PWA1480, SC 16), where MC-NG and PWA1480 are shown to have a higher gamma prime dissolution temperature, but is higher than the other 9 superalloys, with a temperature capability of 1200 ℃.
Fig. 4 shows that the width of the γ single-phase region temperature interval of the nickel-based single-crystal superalloy is negative in MC-NG and PWA1480, whereas in DD403, DD426 and c k 7, although the width of the γ single-phase region temperature interval is larger than that of the nickel-based single-crystal superalloy SA of example 5, the dissolution temperature is lower than that of the present application, and the balance among the γ 'volume fraction, the γ' dissolution temperature and the γ single-phase region temperature interval width is lower than that of the nickel-based single-crystal superalloy SA of example 5.
FIG. 5 shows the harmful phase contents of the Ni-based single crystal superalloy, wherein MC-NG, PWA1480, DD426 and C K7 are all very high, which indicates that the balance among the γ 'volume fraction, the γ' dissolution temperature, the γ single phase region temperature interval width and the harmful phase content is lower than that of the Ni-based single crystal superalloy SA of example 5.
Fig. 6 shows that the lattice mismatch of the nickel-based single crystal superalloy, MC-NG, DD426 and c k 7 are negative, and PWA1480 is positive, indicating that the balance of the properties in γ 'volume fraction, γ' dissolution temperature, γ single-phase zone temperature interval width, harmful phase content and lattice mismatch is lower than that of the nickel-based single crystal superalloy SA of example 5.
FIG. 7 shows that the densities of MC-NG and DD426 are higher than those of the Ni-based single crystal superalloy SA in example 5, and the densities of PWA1480 and C K7 are lower than those of the Ni-based single crystal superalloy SA in example 5, indicating that the balance among γ 'volume fraction, γ' dissolution temperature, γ single phase region temperature interval width, harmful phase content, lattice mismatch and density is lower than that of the Ni-based single crystal superalloy SA in example 5.
Fig. 8 shows that MC-NG and PWA1480 have higher resistance to casting spots than the ni-based single crystal superalloy SA of example 5, and DD426 and c k 7 have lower resistance to casting spots than the ni-based single crystal superalloy SA of example 5, indicating that the balance of the properties in γ 'volume fraction, γ' dissolution temperature, γ single phase region temperature interval width, harmful phase content, lattice mismatch, density, and resistance to casting spots is lower than the ni-based single crystal superalloy SA of example 5.
Fig. 9 shows that the creep resistance of the nickel-based single crystal superalloy, MC-NG, is higher than that of the nickel-based single crystal superalloy SA of example 5, whereas the creep resistance index of the nickel-based single crystal superalloy SA of example 5 is higher than that of the other 17 superalloys, indicating that the balance of the properties of gamma prime volume fraction, gamma prime solution temperature, gamma prime temperature interval width, detrimental phase content, lattice mismatch, density, casting mottle resistance, and creep resistance is lower than that of the nickel-based single crystal superalloy SA of example 5.
Fig. 10 shows the Cr concentration and Al concentration of the ni-based single crystal superalloy, and only the ni-based single crystal superalloy SA and c k 7 of example 5, which meet the conditions of the Cr concentration and Al concentration of the present invention, show that the balance of the properties in γ 'volume fraction, γ' dissolution temperature, γ single phase zone temperature interval width, harmful phase content, lattice mismatch, density, casting spot resistance, creep resistance, and Cr concentration and Al concentration is lower than the ni-based single crystal superalloy SA of example 5.
Therefore, the nickel-based single crystal superalloy in the prior art has lower balance performance on gamma 'volume fraction, gamma' dissolution temperature, gamma single phase zone temperature interval width, harmful phase content, lattice mismatch degree, density, casting spot resistance, creep resistance and Cr concentration and Al concentration than that of the nickel-based single crystal superalloy in the prior art.
In the scheme, compared with various commercial nickel-based single crystal superalloys in the prior art, the nickel-based single crystal superalloy with balanced multiple properties provided by the invention can realize the balance of the multiple properties of the nickel-based single crystal superalloy.
The nickel-based single crystal superalloy with balanced multiple properties provided by the invention plays a role in selecting the content of components of Al element to form gamma' -precipitation and Al at the same time 2 O 3 The corrosion resistance of the protective layer is improved; cr enhances the solid solution strengthening effect and forms Cr 2 O 3 The protective layer improves the corrosion resistance; improving solid solution strengthening of Mo, W and V; nb and Ta improve the antiphase domain boundary energy and gamma' precipitation content of the high-temperature alloy so as to improve the mechanical property of the alloy; re improves creep performance. The method does not contain cobalt element and ruthenium element selection in the fourth-generation nickel-based single crystal superalloy, has simple and easy operation of heat treatment mode and less energy consumption, and is beneficial to industrial large-scale production.
The choice of Cr content in the nickel-based single crystal superalloy with balanced multiple properties, which is provided by the invention, is up to 14at.% which is not available in the prior art, and the hot corrosion resistance is superior to that of the prior art.
In the nickel-based single crystal superalloy with balanced multiple properties, the gamma 'volume fraction and the gamma' dissolution temperature are moderate, the width of a gamma single phase region is obviously superior to that of other commercial nickel-based single crystal superalloys, the density is obviously lower than that of other commercial nickel-based single crystal superalloys, the degree of mismatch of harmful phases and lattices is lower, and the casting spot resistance and the creep resistance are excellent.
In a word, the nickel-based single crystal superalloy with balanced multiple properties has the advantages of low component selection cost, simple and convenient heat treatment, low energy consumption, high resource utilization rate, good thermal corrosion resistance and good balance of other properties, and is beneficial to industrial large-scale production.
While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims.
Claims (5)
1. The nickel-based single crystal superalloy with balanced multiple properties is characterized by comprising the following chemical components in atomic percentage: al:8.5 to 10.5at.%, cr:14.0 to 17.0at.%, mo:1.0 to 1.5at.%, nb:1.0 to 1.5at.%, ta:1.5 to 2.0at.%, W:0.5 to 1.0at.%, re:0.5 to 1.0at.%; v:1.5 to 2.0at.%, and the balance of Ni;
the volume fraction of gamma 'of the nickel-based single crystal superalloy is 40.1 to 49.0vol%, the dissolution temperature of gamma' is 1210 to 1235 ℃, the size of an existing interval of a gamma single phase region is 100 to 125 ℃, the volume fraction of a harmful phase is 0.17 to 1.02 vol%, the lattice mismatch is-0.0023 to-0.0002, and the density is 8.65 to 8.77g/cm 3 The casting speckle resistance index is 0.783 to 1.101, and the creep resistance index is 7.504 to 7.673.
2. The multi-property-balanced nickel-based single crystal superalloy as in claim 1, wherein the nickel-based single crystal superalloy comprises the following chemical components in atomic percent: al:9.0-10.0at.%, cr:15.0 to 17.0at.%, mo:1.0 to 1.5at.%, nb:1.0 to 1.5at.%, ta:1.5 to 2.0at.%, W:1.0at.%, re:1.0at.%; v:2.0at.%, the remainder being Ni.
3. A method for preparing the nickel-based single crystal superalloy based on the multi-property balance of any of claims 1-2, wherein the method comprises the following steps: weighing raw materials according to the component ratio, smelting by adopting a vacuum induction arc furnace, casting into a master alloy with chemical components meeting requirements, preparing to obtain a single crystal test rod, finally carrying out heat treatment on the single crystal test rod, and carrying out air cooling to obtain the nickel-based single crystal high-temperature alloy with balanced multiple properties;
the heat treatment in the preparation method is solid solution treatment and aging treatment;
the temperature of the solution treatment in the preparation method is 1150-1200 ℃, and the time is 3-6 h; the aging treatment is divided into two stages, the temperature of the aging treatment in the first stage ranges from 1170 to 1230 ℃, the time is 6-8 hours, and air cooling is carried out; and the temperature of the aging treatment of the second stage is 880 to 920 ℃, the time is 12 to 18h, and the air cooling is carried out.
4. The method for preparing the nickel-based single crystal superalloy with the balanced properties according to claim 3, wherein the temperature of solution treatment in the preparation method is 1170 ℃ and the time is 4 hours; the aging treatment is divided into two stages, the temperature of the aging treatment in the first stage is 1195 ℃, the time is 8 hours, and air cooling is carried out; and the temperature of the aging treatment of the second stage is 900 ℃, the time is 16h, and the air cooling is carried out.
5. The method for preparing the nickel-based single crystal superalloy with the balanced multiple properties as claimed in claim 3, wherein the raw material selection in the method is pure Al and nickel-based intermediate alloy.
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