EP2927336A1 - Nickel base alloy with optimised matrix properties - Google Patents

Abstract

The invention relates to a nickel - based alloy having a structure with a matrix of y - phase and precipitates of y 'phase, wherein the y' phase has a volume fraction of 50 vol.% To 80 vol.% In the temperature range of 1000 ° C to 1100 ° C, and wherein the nickel-base alloy has a chemical composition according to which the nickel-based alloy contains 8 to 13 at.% Aluminum, 3 to 14 at.% Cobalt, 4 to 12 at.% Chromium, 0.6 to 8 at.% Molybdenum, 0 to 6 at.% Rhenium, 0.5 to 4 at.% Tantalum, 0.5 to 4 at.% Titanium, 0.3 to 3.5 at.% Tungsten, 0 to 4 at.% Germanium, 0 to 0.6 at.% Hafnium and 0 to 4 at.% Ruthenium, as well as balance nickel and unavoidable impurities, wherein the chemical composition is selected with respect to the elements molybdenum and tungsten, that according to the relationship X = 0.84 CMo + CW weighted fraction X of molybdenum and tungsten in the y-phase at temperatures in the range of 1000 ° C to 1100 ° C is greater than 5.5 at.%, Where CMo and C W is the concentration of molybdenum and tungsten in at.%.

Description

BACKGROUND OF THE INVENTION FIELD OF THE INVENTION

The present invention relates to a nickel-based alloy as well as to articles such as blades of turbomachinery made of this nickel-based alloy and a process for producing a corresponding nickel-based alloy.

STATE OF THE ART

In turbomachines, such as stationary gas turbines or aircraft engines, nickel-base alloys and in particular nickel-based superalloys, for example as blade materials, are used, since these materials have sufficient mechanical strength for the high mechanical loads even at high operating temperatures. In particular, such materials must also have a high creep resistance when used in turbomachinery under the given environmental conditions with high operating temperatures and high mechanical loads due to centrifugal forces.

Nickel-base alloys are understood to mean alloys whose main alloy constituent, ie the alloy constituent with the highest proportion, is nickel. Nickel-based superalloys, in turn, refer to alloys with a high proportion of alloyed constituents which have intermetallic precipitates for particular hardening of the material. Corresponding nickel base superalloys, such as IN718, CMSX-4, PWA1497 or René N6, have specific microstructures that dictate the favorable high temperature properties of the materials.

For example, such nickel-base superalloys exhibit cube-shaped precipitates of a y 'phase in a γ matrix, such that precipitation hardening occurs through the y' phase. In addition, the alloy constituents in the y-matrix also cause solid-solution hardening.

Although this already provides very suitable materials for high-temperature applications in gas turbines or aircraft engines, there is a further need for optimizing corresponding alloys in order to further increase the operating temperatures and / or load limits and generally to improve the property profile. In addition, it is an objective due to the scarcity of resources to make optimal use of the alloy components used or to be able to substitute them in part by other components.

DISCLOSURE OF THE INVENTION OBJECT OF THE INVENTION

It is therefore an object of the present invention to provide a nickel-based alloy and a process for its production, in which the alloying components used to achieve a balanced property profile and in particular a high strength and creep resistance at high operating temperatures are used efficiently, the alloy allows a high variability of the composition ,

TECHNICAL SOLUTION

This object is achieved by a nickel-based alloy having the features of claims 1 or 2 and an article of such nickel-based alloys having the features of claim 8 and a method of producing a nickel-based alloy having the features of claims 11 or 12. Advantageous embodiments are the subject of the dependent claims.

The invention proposes to optimize the property profile of a nickel-based alloy and for the efficient use and variable use of alloy constituents, a nickel-based alloy having a chemical composition with 8 to 13 at.% Aluminum, 3 to 14 at.% Cobalt, 4 to 12 at.% Chromium, 0.6 to 8 at.% Molybdenum, 0 to 6 at.% Rhenium, 0.5 to 4 at.% Tantalum, 0.5 to 4 at.% Titanium, 0.3 to 3.5 at.% Tungsten, 0 to 4 at.% Germanium, 0 to 0.6 at.% Hafnium, 0 to 4 at.% Ruthenium and the balance nickel and unavoidable impurities.

For a nickel base alloy having such a composition, the chemical composition is further selected to be a microstructure having a matrix of y phase and precipitates can be formed from the y 'phase, wherein the y' phase component in the temperature range from 1000 ° C. to 1100 ° C. is 50% by volume to 80% by volume, preferably 60% by volume to 80% by volume and in particular 70 ° Vol.% To 80 vol.%. The y 'volume fraction can be adjusted in particular by the appropriate choice of the proportions of germanium, aluminum, titanium and tantalum. In this case, it is advantageous if the aluminum content is minimized, while the proportion of germanium, titanium and / or tantalum is maximized for each element alone or in total for several or all of these elements, wherein the boundary condition that the y '- Phases - proportion should amount to 50 vol.% To 80 vol.% In the structure of the nickel-based alloy.

Accordingly, the aluminum content may be in particular in a range of plus 30%, in particular plus 20%, preferably plus 10% of the minimum aluminum content to the minimum of aluminum content at given or maximum proportions of germanium, titanium and tantalum for the maintenance of y '- Phases - fraction can be chosen within the chemical composition given above. Accordingly, the proportion of germanium, tantalum and / or titanium in each case alone or for several or all of these elements can be selected in ranges corresponding to the respective maxima of the fraction minus 30%, in particular minus 20%, preferably minus 10% to the maximum correspond. Both in the determination of the aluminum content and in the determination of the proportions of germanium, tantalum and / or titanium, the boundary condition of a y 'phase fraction of 50% by volume to 80% by volume should be adhered to, so that in each case the corresponding minima or Maxima for the respective fractions can be determined for a minimum or maximum or middle or intermediate proportion of the y 'phase, ie for example for 50% by volume, 65% by volume and 80% by volume y' phase in the microstructure at a temperature range of 1000 ° C to 1100 ° C.

In particular, the aluminum content may be selected in the range of 9 to 12 at.%, Preferably 10 to 12 at.%.

In addition to the abovementioned chemical composition of the nickel-based alloy according to the invention and the adjustment of the nickel-based alloy having a y 'phase content of 50% by volume to 80% by volume, preferably 60% by volume to 80% by volume and in particular 70% by volume 80% by volume is proposed according to the invention that the proportions of molybdenum and / or tungsten can be chosen in a particular way to both optimize the y - phase solid solution hardening of the matrix by incorporating appropriate alloying constituents in the y phase, as well as to improve the resistance of the y 'precipitates. Since the mechanical properties of the nickel - base superalloys are strongly influenced by the y 'precipitates, it has been found to be of particular importance that the alloying constituents be chosen so that the y' precipitates are as much as possible in their original shape and size remain. For this purpose, it is advantageous to prevent, or at least to complicate, a coarsening of the y 'precipitates and the necessary diffusion through suitable alloy composition. For the solid solution hardening of the y phase, the alloy composition is important in that the alloying composition can also be used to optimize the incorporation of foreign atoms into the y phase.

Accordingly, it is proposed according to the invention to select the chemical composition of the nickel-based alloy such that, with respect to the elements molybdenum and tungsten, the weighted fraction X corresponding to the relationship X = 0.84C _Mo + _CW , in the y-phase at one temperature in the range of 1000 ° C to 1100 ° C is greater than 5.5 at.%, where C _{Mo is} the concentration of molybdenum and C _{W is} the concentration of tungsten in each case in at.% in the y-phase of the matrix. With such a choice of the components of molybdenum and tungsten, optimum solid solution hardening of the y phase is given.

wobei c_W die Konzentration des Wolframs in der Matrix in at.%, c'_W die Konzentration des Wolframs in der y'- Phase in at.% und D_W der Diffusionskoeffizient des Wolframs sowie D_Ni der Diffusionskoeffizient von Nickel unter Berücksichtigung der Löslichkeitsdifferenz der Elemente zwischen Matrix und y'- Phase ist.Alternatively or in combination, the concentration of the alloying constituent tungsten may be selected such that a material parameter φ, which describes the diffusion influence in the coarsening of the y 'precipitates, is less than or equal to 0.05, where φ is defined by the formula $$\phi =\frac{1}{D_{\mathit{Ni}}}{\left[\frac{c_W^{\text{'}}-c_W}{c_W{D}_W}\right]}^{-1}$$

where c _{W is} the concentration of tungsten in the matrix in at.%, c ' _{W is} the concentration of tungsten in the y' phase in at.% and D _{W is} the diffusion coefficient of tungsten and D _{Ni is} the diffusion coefficient of nickel taking into account the solubility difference of the elements between matrix and y'-phase.

The nickel-based alloy may be further selected such that the distribution ratio of tungsten and / or molybdenum from the y-matrix to the y 'precipitates is adjusted so that the concentration of tungsten and / or molybdenum in the matrix relative to the respective concentration of Tungsten and / or molybdenum in the y 'phase is greater than 1, in particular greater than or equal to 1.5. This distribution ratio of the concentration of tungsten and / or molybdenum from the y-phase to the y '-phase can also be influenced by the adjustment of the chemical composition of the alloy with regard to the constituents tantalum, titanium and / or germanium.

In addition, the nickel base alloy can be optimized so that the alloy has a solidus temperature of more than 1300 ° C and / or that the γ / γ 'mismatch in the temperature range of 1000 ° C to 1100 ° C in the range of - 0.15 % to - 0.25%, with the y - / γ 'mismatch being the difference in lattice constants of the two phases γ and γ' normalized to the averaged value of the lattice constant.

In addition, impurities or trace elements such as bismuth, selenium, thallium, lead, tellurium or sulfur can be minimized to technically possible purity ranges.

Embodiment

An alloy containing about 10 at.% Al, 14 at.% Co, 7 at.% Cr, 2 at.% Mo, 2.5 at.% Ta, 3 at.% Ti and 2.5 at.% W and balance nickel designed according to the present invention has optimized properties in terms of the volume fraction of the y 'phase, the liquidus temperature, the solid solution hardening, the coarsening of the y' precipitates and the γ / γ 'mismatch. Thus, the γ / γ 'mismatch is -0.25% and the solidus temperature is 1301 ° C. The proportion of y 'phase is 46 mol .-% and the concentration of W and Mo in the y - phase, each with about 3.5 at.% Is so high that they contribute significantly to solid solution hardening. In addition, the proportion of W and Mo in combination with the selected concentrations of the other alloying constituents causes the coarsening of the y 'phase to be hindered at high use temperatures. In particular, by the combination of the properties achieved, taking into account the alloying constituents used, the alloy is outstandingly suitable for applications at high temperatures, such as in turbomachines and in particular in aircraft turbines.

Claims (15)

Nickel - based alloy having a microstructure with a matrix of y - phase and precipitates of y 'phase, wherein the y' phase has a volume fraction of 50 vol.% To 80 vol.% In the temperature range of 1000 ° C to 1100 ° C, and wherein the nickel-base alloy has a chemical composition according to which the nickel-based alloy 8 to 13 at.% Aluminum 3 to 14 at.% Cobalt 4 to 12 at.% Chromium 0.6 to 8 at.% Molybdenum 0 to 6 at.% Rhenium 0.5 to 4 at.% Tantalum 0.5 to 4 at.% Titanium 0.3 to 3.5 at.% Tungsten 0 to 4 at.% Germanium 0 to 0.6 at.% Hafnium 0 to 4 at.% Ruthenium and the remainder comprises nickel and unavoidable impurities, the chemical composition with respect to the elements molybdenum and tungsten being chosen such that the proportion X of molybdenum and tungsten in the y-phase weighted according to the relationship X = 0.84 C _Mo + C _W Temperatures in the range of 1000 ° C to 1100 ° C is greater than 5.5 at.%, Where C _Mo and C _{W are} the concentrations of molybdenum and tungsten in at.%. Nickel - based alloy having a microstructure with a matrix of y - phase and precipitates of y 'phase, wherein the y' phase has a volume fraction of 50 vol.% To 80 vol.% In the temperature range of 1000 ° C to 1100 ° C, and wherein the nickel-base alloy has a chemical composition according to which the nickel-based alloy 8 to 13 at.% Aluminum 3 to 14 at.% Cobalt 4 to 12 at.% Chromium 0.6 to 8 at.% Molybdenum 0 to 6 at.% Rhenium 0.5 to 4 at.% Tantalum 0.5 to 4 at.% Titanium 0.3 to 3.5 at.% Tungsten 0 to 4 at.% Germanium 0 to 0.6 at.% Hafnium 0 to 4 at.% Ruthenium and the remainder comprises nickel and unavoidable impurities, wherein the chemical composition with respect to the element tungsten is chosen such that the material parameter φ is less than or equal to 0.05, wherein φ is determined by $$\phi =\frac{1}{D_{\mathit{Ni}}}{\left[\frac{c_W^{\text{'}}-c_W}{c_W{D}_W}\right]}^{-1}$$

where c _{W is} the concentration of tungsten in the matrix in at.%, c ' _{W is} the concentration of tungsten in the y' phase in at.% and D _{W is} the diffusion coefficient of tungsten and D _{Ni is} the diffusion coefficient of nickel taking into account the solubility difference of the elements between matrix and y'-phase. Nickel-based alloy according to claim 2,
characterized in that
the chemical composition with respect to the elements molybdenum and tungsten is chosen such that the proportion X of molybdenum and tungsten in the y-phase weighted according to the relationship X = 0.84C _Mo + _CW at temperatures in the range of 1000 ° C to 1100 ° C is greater than 5.5 at.%, Where C _Mo and C _{W are} the concentrations of molybdenum and tungsten in at.% Nickel-based alloy according to one of the preceding claims,
characterized in that
the proportion of aluminum is minimized as a function of the proportions of germanium, titanium and tantalum, the aluminum content being in particular in the region of the minimum plus 30%, in particular plus 20%, preferably plus 10% is selected when a minimum, average or maximum proportion of the y 'phase is set. Nickel-based alloy according to claim 4,
characterized in that
the proportion of germanium, tantalum or titanium is in each case maximized alone or in total, the respective proportion being chosen in particular in the region of the maximum minus 30%, in particular minus 20%, preferably minus 10%, if a minimum, average or maximum Proportion of the y 'phase is set. Nickel-based alloy according to one of the preceding claims,
characterized in that
the aluminum content is 9 to 12 at.%, in particular 10 to 12 at.%. Nickel-based alloy according to one of the preceding claims,
characterized in that
the distribution ratio of the concentration of tungsten and / or molybdenum in the matrix to the respective concentration of tungsten and / or molybdenum in the y 'phase is greater than 1, in particular greater than or equal to 1.5. Nickel-based alloy article according to any one of the preceding claims. An article according to claim 8,
characterized in that
the nickel-based alloy is monocrystalline or directionally solidified. Article according to one of claims 8 or 9,
characterized in that
the object is a component, in particular a blade of a turbomachine, in particular a gas turbine or an aircraft engine. Process for producing a nickel-based alloy, in particular according to one of the preceding claims, in which a chemical composition is selected in a first step for determining the chemical composition, according to which the nickel-based alloy 8 to 13 at.% Aluminum 3 to 14 at.% Cobalt 4 to 12 at.% Chromium 0.6 to 8 at.% Molybdenum 0 to 6 at.% Rhenium 0.5 to 4 at.% Tantalum 0.5 to 4 at.% Titanium 0.3 to 3.5 at.% Tungsten 0 to 4 at.% Germanium 0 to 0.6 at.% Hafnium 0 to 4 at.% Ruthenium and the balance includes nickel and unavoidable impurities,
wherein, in a second step, the chemical composition is selected so that in the nickel-based alloy a microstructure with a matrix of y-phase and precipitates of γ'-phase is formed,
wherein in a third step, the chemical composition is selected so that in the temperature range of 1000 ° C to 1100 ° C, the γ'-phase has a volume fraction of 50 vol.% To 80 vol.%, And
wherein, in a fourth step, the chemical composition with respect to the elements molybdenum and tungsten is chosen such that the proportion X of molybdenum and tungsten in the y-phase weighted according to the relationship X = 0.84C _Mo + _CW at temperatures in the range of 1000 ° C to 1100 ° C is greater than 5.5 at.%, Where C _Mo and Cw are the concentrations of molybdenum and tungsten in at.%. Process for producing a nickel-based alloy, in particular according to one of the preceding claims, in which a chemical composition is selected in a first step for determining the chemical composition, according to which the nickel-based alloy 8 to 13 at.% Aluminum 3 to 14 at.% Cobalt 4 to 12 at.% Chromium 0 6 to 8 at.% Molybdenum 0 to 6 at.% Rhenium 0.5 to 4 at.% Tantalum 0.5 to 4 at.% Titanium 0.3 to 3.5 at.% Tungsten 0 to 4 at.% Germanium 0 to 0.6 at.% Hafnium 0 to 4 at.% Ruthenium and the balance includes nickel and unavoidable impurities,
wherein, in a second step, the chemical composition is selected so that in the nickel-based alloy a microstructure with a matrix of y-phase and precipitates of γ'-phase is formed,
wherein in a third step, the chemical composition is selected so that in the temperature range of 1000 ° C to 1100 ° C, the γ'-phase has a volume fraction of 50 vol.% To 80 vol.%, And
wherein in a fourth step, the chemical composition is selected with respect to the element tungsten so that the material parameter φ is less than or equal to 0.05, wherein φ is determined by $$\phi =\frac{1}{D_{\mathit{Ni}}}{\left[\frac{c_W^{\text{'}}-c_W}{c_W{D}_W}\right]}^{-1}$$

where c _{W is} the concentration of tungsten in the matrix in at.%, c ' _{W is} the concentration of tungsten in the y' phase in at.% and D _{W is} the diffusion coefficient of tungsten and D _{Ni is} the diffusion coefficient of nickel taking into account the solubility difference of the elements between matrix and γ'-phase. Method according to claim 12,
characterized in that
in a further step, the chemical composition is selected with respect to the element tungsten so that the material parameter φ is less than or equal to 0.05, where φ is determined by $$\phi =\frac{1}{D_{\mathit{Ni}}}{\left[\frac{c_W^{\text{'}}-c_W}{c_W{D}_W}\right]}^{-1}$$

where c _{W is} the concentration of tungsten in the matrix in at.%, c ' _{W is} the concentration of tungsten in the y' phase in at.% and D _{W is} the diffusion coefficient of tungsten and D _{Ni is} the diffusion coefficient of nickel taking into account the solubility difference of the elements between matrix and γ'-phase. Method according to one of claims 11 to 13,
characterized in that
in the third step, the proportion of aluminum is minimized and the proportion of germanium, titanium and / or tantalum is maximized individually or together. Method according to one of claims 11 to 14,
characterized in that
the proportion of germanium, titanium and / or tantalum is set individually or together so that the proportion of tungsten and / or molybdenum in the matrix in each case alone or together higher, in particular 1.5 times as high as the respective proportion of tungsten and / or molybdenum in the y'-phase.