PWA Duhl PWA 1480 Heat treated superalloy single crystal
article and process 1978[1980] US4209348A
Publication
Number: US4209348A
Publication
Date: 1980-06-24
Priority
Number: US1976742967A |
US1978970710A
Application
Date: 1978-12-18
Title:
Heat treated superalloy single crystal
article and process
Inventor
- w/address: Duhl David
N.,Newington,CT,US | Olson Walter E.,Vernon,CT,US
Assignee/Applicant:
United Technologies
Corporation,Hartford,CT,US
Abstract:
Nickel base superalloy single crystal articles formed of a
particular compositon and heat treated are described as is the process
employed. The resultant articles are substantially free from the grain boundary
strengtheners such as carbon, boron, and zirconium and contain only a limited
amount of cobalt. As a result of the alloy composition, the alloys have a high
incipient melting temperature. The heat treatment process homogenizes the
micro-structure, and refines the gamma prime morphology.
First Claim:
1. A heat treated
nickel base single crystal superalloy article suited for use at elevated
temperatures having a composition consisting essentially of:
* a. from about 8 to about 12% chromium,
* b. from about 4.5 to about 5.5% aluminum,
* c. from about 1 to about 2% titanium,
* d. from about 3 to about 5% tungsten,
* e. from about 10 to about 14% tantalum,
* f. from about 3 to about 7% cobalt,
* g. balance essentially nickel, said article
being free from intentional additions of carbon, boron and zirconium, and said
article being free from internal grain boundaries and having an average gamma
prime particle size of less than about 0.5 micron and an incipient melting
temperature in excess of about 2350° F.
Description w/Pub Language: BACKGROUND OF THE INVENTION
1. Field of the
Invention
This invention relates
to the field of homogeneous single crystal superalloy articles.
2. Description of the
Prior Art
The nickel base
super-alloy art area has been extensively investigated for many years, and as a
result there are very many issued patents in this area. Some of these disclose
alloys in which no intentional additions of cobalt, carbon, boron, or zirconium
are made, or alloys in which these elements are optional. These include, for
example, U.S. Pat. Nos. 2,621,122; 2,781,264; 2,912,323; 2,994,605; 3,046,108;
3,166,412; 3,188,402; 3,287,110; 3,304,176 and 3,322,534. These patents do not
discuss single crystal applications.
U.S. Pat. No.
3,494,709, assigned to the assignee of the present invention, discloses the use
of single crystal articles in gas turbine engines. This patent discusses the
desirability of limiting certain elements such as boron and zirconium to low
levels.
The limitation of
carbon to low levels in single crystal superalloy articles is discussed in U.S.
Pat. No. 3,567,526 which is also assigned to the present assignee.
U.S. Pat. No.
3,915,761, assigned to the present assignee discloses a nickel base superalloy
article produced by a method which provides a hyperfine dendritic structure. As
a result of the fineness of the structure, the article may be homogenized in
relatively short times.
The conventional
nickel base superalloys which are used to fabricate such parts have evolved
over the last 30 years. Typically these alloys contain chromium in levels of
about 10% primarily for oxidation resistance, aluminum and titanium in combined
levels of about 5% for the formation of the strengthening gamma prime phase and
refractory metals such as tungsten, molybdenum, tantalum and columbium in
levels of about 5% as solid solution strengtheners. Virtually all nickel base
superalloys also contain carbon in levels of about 0.1% which acts as a grain boundary
strengthener and forms carbides which strengthen the alloy. Boron and zirconium
are also often added in small amounts as grain boundary strengtheners.
Most commonly, gas
turbine blades are formed by casting and the casting process most often utilized
produces parts having equiaxed nonoriented grains. It is well known that the
high temperature properties of metals are usually quite dependent upon grain
boundary properties, consequently efforts have been made to strengthen such
boundaries (for example by the additions discussed previously), or to reduce or
eliminate the grain boundaries transverse to the major stress axis of the part.
One method of eliminating such transverse boundaries is termed directional
solidification and is described in U.S. Pat. No. 3,260,505. The effect of
directional solidification is to produce an oriented microstructure of columnar
grains whose major axis is parallel to the stress axis of the part and which
has minimal or no grain boundaries perpendicular to the stress axis of the
part. A further extension of this concept is the utilization of single crystal
parts in gas turbine blades. This concept is described in U.S. Pat. No.
3,494,709. The obvious advantage of the single crystal blade is the complete
absence of grain boundaries. In single crystals, therefore, grain boundaries
are eliminated as potential weaknesses, hence, the mechanical properties of the
single crystal are completely dependent upon the inherent mechanical properties
of the material.
In the prior art alloy
development much effort was devoted to the solution of the problems resulting
from grain boundaries, through the addition of elements such as carbon, boron,
and zirconium. Another problem which prior art alloy development sought to
avoid was the development of deleterious phases after long term exposures at
elevated temperatures (i.e. alloy instability). These phases are of two general
types. One, such as sigma, is undesirable because of its brittle nature while
the other, such as mu, is undesirable because the phase ties up large amounts
of the refractory solid solution strengtheners thus weakening the remaining
alloy phases. These phases are termed TCP phases for topologically closed
packed phases, and one of their common properties is that they all contain
cobalt. There are TCP phases which can form in the absence of cobalt but these
cobalt free TCP phases contain other elements such as silicon which are not
commonly found in nickel base superalloys. While an obvious remedy to control
these deleterious phases is the removal or minimization of cobalt, this has not
proved practical in prior art alloys for polycrystalline applications. The
problem is that if the cobalt is removed or significantly reduced, the carbon
combines preferentially with the refractory metals to form M. sub.6 C carbides
which are deleterious to the properties of the material as their formation
depletes the alloy of the strengthening refractory elements.
U.S. Pat. No.
3,567,526 teaches that carbon can be completely removed from single crystal
superalloy articles and that such removal improves fatigue properties.
In single crystal
articles which are free from carbon there are two important strengthening
mechanisms. The most important strengthening mechanism is the intermetallic
gamma prime phase, Ni.sub.3 (Al, Ti). In modern nickel base superalloys the
gamma prime phase may occur in quantities as great as 60 volume percent. The
second strengthening mechanism is the solid solution strengthening which is
produced by the presence of the refractory metals such as tungsten and
molybdenum in the nickel solid solution matrix. For a constant volume fraction
of gamma prime, considerable variations in the strengthening effect of this
volume fraction of gamma prime may be obtained by varying the size and
morphology of the gamma prime precipitate particles. The gamma prime phase is
characterized by having a solvus temperature above which the phase dissolves
into the matrix. In many cast alloys, however, the gamma prime solvus
temperature is in fact above the incipient melting temperature so that it is
not possible to effectively solutionize the gamma prime phase without incipient
melting. Solutionizing of the gamma prime is the only way in which the
morphology of the as cast gamma prime phase can be modified, hence for many
modern commercial nickel base superalloys the gamma prime morphology is limited
to the morphology which resulted from the original casting process. The other
strengthening mechanism, solid solution strengthening, is most effective when
the solid solution strengthening elements are uniformly distributed throughout
the nickel solid solution matrix. Again this strengthening is reduced in
effectiveness because of the nature of the casting and solidification process.
Practical nickel base superalloys freeze over a wide temperature range. The
freezing or solidification process involves the formation of high melting point
dendrites followed by the subsequent freezing of the lower temperature melting
interdendritic liquid. This solidification process leads to significant
compositional inhomogeneities throughout the microstructure. It is
theoretically possible to homogenize such a microstructure by heating at
elevated temperatures to permit diffusion to occur, however, in practical
nickel base superalloys the maximum homogenization temperature, which is
limited by the incipient melting temperature, is too low to permit significant
homogenization in practical time intervals.
SUMMARY OF THE
INVENTION
This invention
includes three interrelated aspects. The first aspect is the particular alloy
employed. The alloy is a nickel base alloy containing from about 8 to about 12%
chromium, from about 4.5 to about 5. 5% aluminum, from about 1 to 2% titanium,
from 3 to 5% tungsten, and from 10 to 14% tantalum. The cobalt content is
controlled to fall within the range of 3-7%, and the balance is essentially
nickel. The alloy employed in the present invention is free from intentional
additions of carbon, boron and zirconium, although obviously these elements may
be present as unintentional impurities. The alloy is characterized by having an
incipient melting temperature in excess of about 2300° F. Thus, this alloy may
be heat treated under conditions which permit solutionizing of the gamma prime
phase without incipient melting. At the same time the high incipient melting
temperature permits essentially complete homogenization of the alloy in
commercially practicable times. The high incipient melting temperature of the
alloy is a result of the absence of carbon, boron and zirconium. The low cobalt
content inhibits the formation of deleterious TCP phases.
The second important
aspect of the invention is the formation of the previously described alloy into
single crystal articles.
The third aspect of
the invention is the heat treatment sequence by which the gamma prime
morphology may be modified and refined at the same time that significant
homogenization of the as cast microstructure is performed. The resultant single
crystal article will have a microstructure whose typical gamma prime particle
size is about one third of the gamma prime particle size found in the as cast
material. At the same time the heat treated single crystal microstructure will
be essentially free from compositional inhomogeneities and this uniform
microstructure combined with the increased gamma prime solvus temperature will
permit the article of the present invention to exhibit temperature
capabilities, for equal mechanical properties, which are at least 30. degree.
F. greater than the temperature capabilities of comparable prior art single
crystal articles which are formed from conventional alloys containing carbon,
boron and zirconium and conventional levels of cobalt. The alloys have
advantages over conventional alloys even if not heat treated, but the heat
treatment is the preferred embodiment.
The foregoing, and
other objects, features and advantages of the present invention will become
more apparent in light of the following detailed description of the preferred
embodiment thereof.
DESCRIPTION OF THE
PREFERRED EMBODIMENTS
In the description
which follows, all percent figures are in weight percent unless otherwise
specified.
This invention relates
to an article made of a specific alloy by a critical series of process steps.
Although other articles may be produced according to this invention, this
invention has particular utility in the fabrication of airfoils (blades and
vanes) for use in gas turbine engines. In particular, the high strength of
articles made according to this invention make them especially suited for use
as blades in gas turbine engines.
A primary feature in
the alloys employed in the present invention is the substantial elimination of
the grain boundary strengthening agents, carbon, boron and zirconium and the reduction
in cobalt content relative to conventional superalloys. The alloys of the
invention are intended for use as gas turbine components in a single crystal
form. No intentional additions of the elements, carbon, boron and zirconium are
made, however, some will invariably be present as an impurity.
In order to ensure
that TCP phases will not form in the alloy over a wide range of compositions
and operating conditions, the level of cobalt is controlled to fall within the
range of 3 to 7%.
Likewise, with regard
to the grain boundary strengthening agents carbon, boron and zirconium, no
intentional additions are made. If the maximum benefit is to be obtained from
this invention, no single element of the group carbon, boron and zirconium
should be present in an amount greater than 50 ppm and it is preferred that the
total of such impurities be less than 100 ppm. Most preferably carbon is
present in an amount less than 30 ppm and the remaining elements are each
present in quantities less than 20 ppm. In any event, the carbon level must be
restricted to be below that amount of carbon which will form MC type carbides.
It must be emphasized that no intentional addition of these elements is
contemplated and that their presence in the alloy or single crystal article of
the invention is unintentional and undesirable.
Alloys which can be
produced using the concept of the present invention will contain:
(1) from 8 to 12%
chromium,
(2) from 4.5 to 5.5%
aluminum, and from 1-2% titanium,
(3) from 3-5% tungsten
and from 10-14% tantalum,
(4) from 3-7% cobalt,
(5) balance
essentially nickel.
Within the preceding
ranges, certain relationships are preferred. The sum of tungsten and tantalum
levels is preferably at least 15.5% to insure adequate solid solution strengthening
and improved elevated temperature creep strength. A tantalum level of at least
11% is preferred for oxidation resistance. The elements aluminum, titanium and
tantalum participate in the formation of the gamma prime phase (Ni.sub.3 Al,
Ti, Ta) and for maximum strengthening by the gamma prime phase the total
content of aluminum plus titanium plus tantalum is preferably at least 17. 5%.
Aluminum and titanium are the principal elements which form the gamma prime
phase and the ratio of aluminum to titanium must be controlled to be greater
than 2.5 and preferably greater than 3.0 to insure adequate oxidation
resistance. At least 9% chromium should be present if the article is to be used
in environments where sulfidation is a problem. The minor addition of cobalt
also aids in improving sulfidation resistance.
Alloys made according
to the preceding limitations will comprise a nickel chromium solid solution
containing at least 30% by volume of the ordered phase of the composition
Ni.sub.3 M where M is aluminum, titanium, tantalum, and tungsten to a lesser
degree.
The alloys within the
ranges set forth above are thermally stable and deleterious microstructural
instabilities such as the cobalt containing TCP phases will not form, even
after extended exposure at elevated temperature as for example 500 hours at
either 1600°, 1800° or 2000° F. Further, the alloys have good fatigue
properties since the formation of deleterious carbide particles is prevented.
The refractory metals which would normally combine with carbon or precipitate
in TCP phase formation remain in solid solution and result in an alloy having
exceptional mechanical properties.
An important benefit
which arises from the elimination of boron, carbon and zirconium is an increase
in the incipient melting temperature. Typically the incipient melting temperature
of the present alloys, that temperature at which the alloy first begins
localized melting, will be increased by at least 50° F. over the incipient
melting temperature of a similar (prior art) alloy which contains normal
amounts of carbon, boron and zirconium. The incipient melting temperature of
the alloy of this invention will typically exceed 2300° F. while conventional
high strength, high volume fraction gamma-gamma prime alloys typically have
incipient melting temperatures below 2300° F. This increased temperature
permits solutionizing heat treatments to be performed at temperatures where
complete solutionizing of the precipitated gamma prime is possible while
simultaneously permitting a significant amount of homogenization within
reasonable times.
The alloys of the
present invention will not form the carbides which have been found necessary
for grain boundary strengthening in polycrystalline nickel base superalloys.
For this reason the alloys of the present invention must be used as single
crystal articles. The formation of the alloy into single crystal form is a
critical aspect of the present invention, but the method of single crystal
formation is unimportant. Typical articles and solidification techniques are
described in U.S. Pat. No. 3,494,709 to Piearcey, which is assigned to the
assignee of the present application, and the contents of this patent are
incorporated herein by reference.
The final aspect of
the invention involves the specific heat treatment applied to the single
crystal article. The as cast single crystal article will contain the gamma
prime phase in dispersed form with a typical particle size on the order of 1.5
microns. The gamma prime solvus of the alloy will typically fall in the range
of 2350. degree.-2400° F. and the incipient melting temperature will be in
excess of about 2350. degree. F. Thus, heat treatment in the range of
2350°-2400° F. (but below the incipient melting temperature) will place the
precipitated gamma prime phase into solution without deleterious localized
melting. Times on the order of 1/2 to 8 hours will normally be satisfactory
although longer times may be employed. Such heat treatment temperatures are
about 100° F. higher than those which can be employed with polycrystalline
articles of conventional superalloys. This elevated temperature permits a
substantial amount of homogenization to occur during the solutionizing steps.
Following the
solutionizing treatment, an aging treatment at 1600. degree.-2000° F. may be
utilized to reprecipitate the gamma prime in refined form. Typical gamma prime
particle sizes after reprecipitation will be less than about 0.5 micron.
The preceding
discussion of the preferred embodiment will be clarified through reference to
the following illustrative examples:
EXAMPLE 1
Alloys having
compositions set forth in Table I were prepared. ##TBL1## (See PDF)
Alloy 444 is disclosed
in U.S. Ser. No. 742,967, the parent case of the present application. Alloy 454
is the alloy of the present invention. Both of these alloys were solidified in
single crystal form. Alloy PWA 1422 is a commercial alloy used as a blade
material in gas turbine engines and noted for its high temperature mechanical
properties. Alloy PWA 1422 was produced in a directionally solidified form
having elongated columnar grains. Alloy 1455 is a commercial alloy which has
been used as a gas turbine blade material. It is noted for its high temperature
oxidation resistance. This alloy was produced by conventional casting methods
with equiaxed nonoriented grains. Alloy PWA 1481 is a previously developed
single crystal alloy developed to have good oxidation/corrosion behavior in
combination with reasonable mechanical properties.
It can be seen that SM
200, SM 200 (No B, Zr), PWA 1409 and PWA 1422 have similar compositions. SM 200
represents the original alloy composition and is used in either equiaxed or
directionally solidified columnar grained form. SM 200 (No B, Zr) represents a
modification in which B and Zr are deleted. These elements primarily affect
grain boundaries and this modified composition is intended for single crystal
applications where grain boundary strength is not a consideration. Alloy PWA
1422 is alloy SM 200 with additions of Hf for improved transverse ductility.
PWA 1422 is used in directionally solidified columnar grained form. Alloy PWA
1409 is another composition which is used in single crystal form. Except for
its intended form, it is quite similar to SM 200.
The experimental
alloys (alloys 444 and 454) were heat treated according to the invention, the
treatment used was a 4 hour solution heat treatment at 2350° F. with subsequent
aging treatments at 1975. degree. F. for 4 hours and 1600° F. for 32 hours.
Alloys PWA 1409 and 1422 were treated at 2200° F. for 2 hours followed by aging
treatments at 1975° F. for 4 hours and 1600° F. for 32 hours and the alloy PWA
1455 was tested as cast. The prior art alloys were heat treated according to
the usual commercial practice. The SM 200 samples were heat treated at 2250° F.
for 1 hour and then at 1600. degree. F. for 32 hours.
EXAMPLE 2
Some of the alloy
samples produced in Example 1 were tested to evaluate their creep rupture
properties. The test conditions and results are set forth below in Table II.
##TBL2## (See PDF)
Referring to Table II,
it is apparent that under the test conditions employed, the invention alloy
(454) was superior to the other alloys tested including SM 200, SM 200 (No B,
Zr), 444 and PWA 1422. The proportionate degree of superiority of the invention
alloy, in time to 1% creep, to alloy 444 can be seen to diminish somewhat with
increasing temperature. However, in creep, the superiority of the invention
alloy to the commercial alloy, 1422, can be seen to increase significantly with
increasing test temperature.
In terms of rupture
life, the superiority of the invention alloy to the 1422 alloy is seen to
increase with increasing temperature. The invention alloy displays properties
superior to those of the other alloys under all conditions tested. Since the
trend in gas turbine engines is toward increased efficiency through higher
temperature, the improved elevated temperature properties of the present
invention are significant.
EXAMPLE 3
Samples of some of the
materials described in Example 1 were tested for resistance to sulfidation and
oxidation at elevated temperatures. The sulfidation test involved the
application of Na.sub.2 SO.sub.4 at the rate of 1 mg/cm.sup.2 every twenty
hours. The failure criteria was a weight loss of 250 mg/cm.sup.2 or more. The
oxidation tests were performed both on the unprotected alloys at 2100° F. under
cyclic conditions and on the alloys protected with a NiCoCrAlY type of coating
under cyclic conditions at 2150° F. NiCoCrAlY is a commercial coating material
having a nominal composition of 18% Cr, 23% Co, 12.5% Al, 0.3% Y, balance
nickel. The tests on coated samples were normalized to minimize the effect of
different coating thicknesses. This coating is described in U.S. Pat. No.
3,928,026 which is incorporated herein by reference. The tests of coated
samples are significant since these alloys are always used in a coated
condition and since coating substrate interactions occur in-service. The test
results are shown below in Table III. ##TBL3## (See PDF)
The sulfidation
resistance of the invention alloy is clearly superior to that of the other
alloys tested. Likewise, in cyclic oxidation evaluation of uncoated samples,
the invention alloy outperforms even alloy 1455, an alloy noted for inherent
oxidation resistance. Even when a protective coating is employed, the invention
alloy displays superior resistance to elevated temperature cyclic oxidation.
EXAMPLE 4
Tensile tests were
conducted on alloys 454, SM 200, and PWA 1481 at room temperature and 1100° F.
The results are shown below. ##TBL4## (See PDF)
Again the marked
superiority of the invention alloy, 454 is evident. The yield strength
improvements are believed to be related in general to the Ta level. Alloys SM
200/1409, 1481, and 454 contain 0, 8, and 12% Ta respectively and the high Ta
content of the invention alloy is believed largely responsible for its superior
tensile properties.
Although the invention
has been shown and described with respect to a preferred embodiment thereof, it
should be understood by those skilled in the art that various changes and
omissions in the form and detail thereof may be made therein without departing
from the spirit and scope of the invention.
Claims: Having thus
described a typical embodiment of our invention, that which we claim as new and
desire to secure by Letters Patent of the United States is:
1. A heat treated
nickel base single crystal superalloy article suited for use at elevated
temperatures having a composition consisting essentially of:
* a. from about 8 to about 12% chromium,
* b. from about 4.5 to about 5.5% aluminum,
* c. from about 1 to about 2% titanium,
* d. from about 3 to about 5% tungsten,
* e. from about 10 to about 14% tantalum,
* f. from about 3 to about 7% cobalt,
* g. balance essentially nickel, said article
being free from intentional additions of carbon, boron and zirconium, and said
article being free from internal grain boundaries and having an average gamma
prime particle size of less than about 0.5 micron and an incipient melting
temperature in excess of about 2350° F.
2. An article as in
claim 1 wherein the sum of the tungsten and tantalum contents are at least
about 15.5%.
3. An article as in
claim 1 wherein the tantalum content is at least about 11%.
4. An article as in
claim 1 wherein the sum of the aluminum, titanium, and tantalum contents are at
least 17.5%.
5. An article as in
claim 1 wherein the ratio of aluminum to titanium is greater than about 2.5.
6. An article as in
claim 1 wherein the ratio of aluminum to titanium is greater than about 3.0.
7. An article as in
claim 1 wherein the chromium content exceeds about 9%.
8. A method for
producing a single crystal nickel base superalloy article suited for use at
elevated temperatures including the steps of:
* a. providing an alloy consisting essentially
of from about 8 to about 12% chromium, from about 4.5 to about 5.5% aluminum,
from about 1 to about 2% titanium, from about 3 to about 5% tungsten, from
about 10 to about 14% tantalum, from about 3 to about 7% cobalt, balance
essentially nickel, said alloy being free from intential additions of carbon,
boron and zirconium,
* b. forming the alloy into a single crystal
article, and
* c. solution heat treating the article at a
temperature of from about 2350° to about 2400° F., but below the incipient
melting temperature so as to place the gamma prime phase into solid solution,
and
* d. aging the article at a temperature of from
about 1600° to about 2000° F. to reprecipitate the gamma phase in a refined
form.
9. An intermediate
single crystal article useful in the production of articles for use at elevated
temperatures, said intermediate article having a composition consisting
essentially of:
* a. from about 8 to about 12% chromium,
* b. from about 4.5 to about 5.5% aluminum,
* c. from about 1 to about 2% titanium,
* d. from about 3 to about 5% tungsten,
* e. from about 10 to about 14% tantalum,
* f. from about 3 to about 7% cobalt,
* g. balance essentially nickel, said article
being free from intentional additions of carbon, boron and zirconium, said
article being free from internal grain boundaries and having an as cast
microstructure and having an incipient melting temperature in excess of 2350°
F.