Abstract:
A TiAl composition is prepared to have high strength and to have improved ductility by altering the atomic ratio of the titanium and aluminum to have what has been found to be a highly desirable effective aluminum concentration by addition of tungsten and rapid solidification from the melt according to the approximate formula Ti 50-48  Al 48  W 2-4 .

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     The subject application relates to copending applications as follows: 
     Serial No. 138,476, filed 12/28/87, U.S. Pat. No. 4,857,268; 
     Serial No. 138,486, filed 12/28/87, U.S. Pat. No. 4,842,820; 
     Serial No. 138,481, filed 12/28/87, U.S. Pat. No. 4,842,819; 
     Serial No. 138,407, filed 12/28/87, U.S. Pat. No. 4,836,983; 
     Serial No. 138,408 filed 12/28/87; abandoned; 
     Serial No. 201,984 filed June 3, 1988; 
     Serial No. 07/253,659 filed 10/3/88; and 
     Serial No. 07/293,035 filed 1/3/89. 
     The texts of these related applications are incorporated herein by reference. 
     BACKGROUND OF THE INVENTION 
     The present invention relates generally to alloys of titanium and aluminum. More particularly it relates to alloys of titanium and aluminum which have been modified both with respect to stoichiometric ratio and with respect to tungsten addition. 
     It is known that as aluminum is added to titanium metal in greater and greater proportions the crystal form of the resultant titanium aluminum composition changes. Small percentages of aluminum go into solid solution in titanium and the crystal form remains that of alpha titanium. At higher concentrations of aluminum (including about 25 to 35 atomic %) an intermetallic compound Ti 3  Al is formed. The Ti 3  Al has an ordered hexagonal crystal form called alpha-2. At still higher concentrations of aluminum (including the range of 50 to 60 atomic % aluminum) another intermetallic compound, TiAl, is formed having an ordered tetragonal crystal form called gamma. 
     The alloy of titanium and aluminum having a gamma crystal form and a stoichiometric ratio of approximately one is an intermetallic compound having a high modulus, a low density, a high thermal conductivity, good oxidation resistance, and good creep resistance. The relationship between the modulus and temperature for TiAl compounds to other alloys of titanium and in relation to nickel base superalloys is shown in FIG. 1. As is evident from the figure the TiAl has the best modulus of any of the titanium alloys. Not only is the TiAl modulus higher at temperature but the rate of decrease of the modulus with temperature increase is lower for TiAl than for the other titanium alloys. Moreover, the TiAl retains a useful modulus at temperatures above those at which the other titanium alloys become useless. Alloys which are based on the TiAl intermetallic compound are attractive lightweight materials for use where high modulus is required at high temperatures and where good environmental protection is also required. 
     One of the characteristics of TiAl which limits its actual application to such uses is a brittleness which is found to occur at room temperature. Also the strength of the intermetallic compound at room temperature needs improvement before the TiAl intermetallic compound can be exploited in structural component applications. Improvements of the TiAl intermetallic compound to enhance ductility and/or strength at room temperature are very highly desirable in order to permit use of the compositions at the higher temperatures for which they are suitable. 
     Because these are potential benefits of use of TiAl at high temperatures including the advantage of its lighter weight, what is most desired in the TiAl compositions which are to be used is a combination of strength and ductility at room temperature. A minimum ductility of the order of one percent is acceptable for some applications of the metal composition but higher ductilities are much more desirable. A minimum strength for a composition to be useful is about 50 ksi or about 350 MPa. However, materials having this level of strength are of marginal utility and higher strengths are often preferred for some applications. 
     The stoichiometric ratio of TiAl compounds can vary over a range without altering the crystal structure. The aluminum content can vary from about 50 to about 60 atom percent. The properties of TiAl compositions are subject to very significant changes in the properties displayed as a result of relatively small changes of one percent or more in the stoichiometric ratio of the titanium and aluminum ingredients. Also the properties are similarly affected by the addition of relatively similar small amounts of ternary elements. 
     PRIOR ART 
     There is extensive literature on the compositions of titanium aluminum including the Ti 3  Al intermetallic compound, the TiAl intermetallic compounds and the TiAl 3  intermetallic compound. A patent, 4,294,615, entitled &#34;Titanium Alloys of the TiAl Type&#34; and naming Blackburn and Smith as inventors, contains an extensive discussion of the titanium aluminide type alloys including the TiAl intermetallic compound. As is pointed out in the patent in column 1 starting at line 50 in discussing TiAl&#39;s advantages and disadvantages relative to Ti 3  Al: 
      &#34;It should be evident that the TiAl gamma alloy system has the potential for being lighter inasmuch as it contains more aluminum. Laboratory work in the 1950&#39;s indicated that titanium aluminide alloys had the potential for high temperature use to about 1000° C. But subsequent engineering experience with such alloys was that, while they had the requisite high temperature strength, they had little or no ductility at room and moderate temperatures, i.e., from 20° to 550° C. Materials which are too brittle cannot be readily fabricated, nor can they withstand infrequent but inevitable minor service damage without cracking and subsequent failure. They are not useful engineering materials to replace other base alloys.&#34; 
     It is known that the alloy system TiAl is substantially different from Ti 3  Al (as well as from solid solution alloys of Ti) although both TiAl and Ti 3  Al are basically ordered titanium aluminum intermetallic compounds. As the &#39;615 patent points out at the bottom of column 1: 
      &#34;Those well skilled recognize that there is a substantial difference between the two ordered phases. Alloying and transformational behavior of Ti 3  Al resemble those of titanium as the hexagonal crystal structures are very similar. However, the compound TiAl has a tetragonal arrangement of atoms and thus rather different alloying characteristics. Such a distinction is often not recognized in the earlier literature.&#34; 
     The &#39;615 patent describes the alloying of TiAl with vanadium and carbon to achieve some property improvements in the resulting alloy. 
     In Table 2 of the &#39;615 patent two TiAl compositions containing tungsten are disclosed. Alloy T 2  A-128 is disclosed to contain Ti-48Al-1.0W and alloy T 2  A-127 is disclosed to contain Ti-48Al-1.0V-1.0W. 
     In the text below Table 2, it is pointed out that &#34;the effects of the alloying additions are summarized in FIG. 3 for Ti-48Al. Referring to FIG. 3, it can be seen that all additions increased creep life but it is seen that tungsten lowers ductility while vanadium raises or preserves it: compare alloy 128 with 125.&#34; 
     The influence of tungsten in lowering ductility is pointed out further in column 5 starting at line 51 in the statement that &#34;most elements such as Mo and W tend to lower ductility somewhat and may reduce creep rupture properties.&#34; 
     The negative influence of tungsten on ductility at room temperature is evident from FIG. 3. From FIG. 3 it is evident that the &#34;RT % Elong.&#34; of alloy 128 containing 1% tungsten in the base alloy is less than half that of the base Ti-Al 48 alloy. The ductility of alloy 127 containing 1% tungsten and 1% vanadium in the base alloy is even lower. 
     A number of technical publications dealing with the titanium aluminum compounds as well as with the characteristics of these compounds are as follows: 
     1. E. S. Bumps, H. D. Kessler, and M. Hansen, &#34;Titanium-Aluminum System&#34;, Journal of Metals, TRANSACTIONS AIME, Vol. 194 (June 1952) pp. 609-614. 
     2. H. R. Ogden, D. J. Maykuth, W. L. Finlay, and R. I. Jaffee, &#34;Mechanical Properties of High Purity Ti-Al Alloys&#34;, Journal of Metals, TRANSACTIONS AIME, Vol. 197 (February 1953) pp. 267-272. 
     3. Joseph B. McAndrew, and H. D. Kessler, &#34;Ti-36 Pct Al as a Base for High Temperature Alloys&#34;, Journal of Metals, TRANSACTIONS AIME, Vol. 206 (October 1956) pp. 1348-1353. 
     4. Patrick L. Martin, Madan G. Mendiratta, and Harry A. Lispitt, &#34;Creep Deformation of TiAl and TiAl+W alloys&#34;, Metallurgical Transactions A, Volume 14A (October 1983) pp. 2171-2174. 
     5. P. L. Martin, H. A. Lispitt, N. T. Nuhfer, and J. C. Williams, &#34;The Effects of Alloying on the Microstructure and Properties of Ti 3  Al and TiAl&#34;, Titanium 80, (Published by American Society for Metals, Warrendale, PA), Vol. 2, pp. 1245-1254. 
     BRIEF DESCRIPTION OF THE INVENTION 
     One object of the present invention is to provide a method of forming a titanium aluminum intermetallic compound having improved ductility and related properties at room temperature. 
     Another object is to improve the properties of titanium aluminum intermetallic compounds at low and intermediate temperatures. 
     Another object is to provide an alloy of titanium and aluminum having improved properties and processability at low and intermediate temperatures. 
     Other objects will be in part, apparent and in part, pointed out in the description which follows. 
     In one of its broader aspects the objects of the present invention are achieved by providing a nonstoichiometric TiAl base alloy, and adding a relatively low concentration of tungsten to the nonstoichiometric composition. The addition may be followed by rapidly solidifying the tungsten-containing nonstoichiometric TiAl intermetallic compound. Addition of tungsten in the order of approximately 1 to 5 parts in 100 is contemplated. 
     The rapidly solidified composition may be consolidated as by isostatic pressing and extrusion to form a solid composition of the present invention. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a graph illustrating the relationship between modulus and temperature for an assortment of alloys. 
     FIG. 2 is a graph illustrating the relationship between load in pounds and crosshead displacement in mils for TiAl compositions of different stoichiometry tested in 4-point bending. 
     FIG. 3 is a graph similar to that of FIG. 2 in which a comparison of the relationship of the properties of TiAl to those of tungsten modified TiAl is provided. 
     FIG. 4 is a bar graph showing the values of fracture strength, yield strength and outer fiber strain for Ti 48  Al 48  W 4  in relation to the base metal. 
     FIG. 5 is a graph in which yield strength in psi is plotted against test temperature for a sample of Ti 50  Al 48  W 2  annealed at 1300° C. as measured by a conventional compression test. The measurement of yield and rupture strength by conventional compression or tension methods tends to be lower than the results obtained by four point bending as is evident by comparing the results plotted in this figure with those plotted in FIG. 4. 
     FIG. 6 is a graph displaying comparative oxidation resistance properties. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     EXAMPLES 1-3 
     Three individual melts were prepared to contain titanium and aluminum in various stoichiometric ratios approximating that of TiAl. The compositions, annealing temperatures and test results of tests made on the compositions are set forth in Table I. 
     For each example the alloy was first made into an ingot by electro arc melting. The ingot was processed into ribbon by melt spinning in a partial pressure of argon. In both stages of the melting, a water-cooled copper hearth was used as the container for the melt in order to avoid undesirable melt-container reactions. Also care was used to avoid exposure of the hot metal to oxygen because of the strong affinity of titanium for oxygen. 
     The rapidly solidified ribbon was packed into a steel can which was evacuated and then sealed. The can was then hot isostatically pressed (HIPped) at 950° C. (1740° F.) for 3 hours under a pressure of 30 ksi. The HIPping can was machined off the consolidated ribbon plug. The HIPped sample was a plug about one inch in diameter and three inches long. 
     The plug was placed axially into a center opening of a billet and sealed therein. The billet was heated to 975° C. (1787° F.) and was extruded through a die to give a reduction ratio of about 7 to 1. The extruded plug was removed from the billet and was heat treated. 
     The extruded samples were then annealed at temperatures as indicated in Table I for two hours. The annealing was followed by aging at 1000° C. for two hours. Specimens were machined to the dimension of 1.5×3×25.4 mm (0.060×0.120×1.0 in) for four point bending tests at room temperature. The bending tests were carried out in a 4-point bending fixture having an inner span of 10 mm (0.4 in) and an outer span of 20 mm (0.8 in). The load-crosshead displacement curves were recorded. Based on the curves developed the following properties are defined: 
     1. Yield strength is the flow stress at a cross head offset displacement of one thousandth of an inch. This amount of cross head displacement is taken as the first evidence of plastic deformation and the transition from elastic deformation to plastic deformation. The measurement of yield and/or fracture strength by conventional compression or tension methods tends to give results which are lower than the results obtained by four point bending as carried out in making the measurements reported herein. The higher levels of the results from four point bending measurements should be kept in mind when comparing these values to values obtained by the conventional compression or tension methods. However, the comparison of measurement results in the examples herein is between four point bending tests for all samples measured and such comparisons are quite valid in establishing the differences in strength properties resulting from differences in composition or in processing of the compositions. 
     2. Fracture strength is the stress to fracture. 
     3. Outer fiber strain is the quantity of 9.71hd where h is the specimen thickness in inches and d is the cross head displacement of fracture in inches. Metallurgically, the value calculated represents the amount of plastic deformation experienced at the outer surface of the bending specimen at the time of fracture. 
     The results are listed in the following Table I. Table I contains data on the properties of samples annealed at 1300° C. and further data on these samples in particular is given in FIG. 2. 
     
                       TABLE I______________________________________                  An-                 OuterGamma    Com-     neal  Yield  Fracture                                      FiberEx.  Alloy    posit.   Temp. Strength                               Strength                                      StrainNo.  No.      (at. %)  (°C.)                        (ksi)  (ksi)  (%)______________________________________1    83       Ti.sub.54 Al.sub.46                  1250  131    132    0.1                  1300  111    120    0.1                  1350  --*    58     02    12       Ti.sub.52 Al.sub.48                  1250  130    180    1.1                  1300  98     128    0.9                  1350  88     122    0.9                  1400  70     85     0.23    85       Ti.sub.50 Al.sub.50                  1250  83     92     0.3                  1300  93     97     0.3                  1350  78     88     0.4______________________________________ *No measurable value was found because the sample lacked sufficient ductility to obtain a measurement. 
    
     It is evident from the data of this table that alloy 12 for Example 2 exhibited the best combination of properties. This confirms that the properties of Ti-Al compositions are very sensitive to the Ti/Al atomic ratios and to the heat treatment applied. Alloy 12 was selected as the base alloy for further property improvements based on further experiments which were performed as described below. 
     It is also evident that the anneal at temperatures between 1250° C. and 1350° C. results in the test specimens having desirable levels of yield strength, fracture strength and outer fiber strain. However, the anneal at 1400° C. results in a test specimen having a significantly lower yield strength (about 20% lower); lower fracture strength (about 30% lower) and lower ductility (about 78% lower) than a test specimen annealed at 1350° C. The sharp decline in properties is due to a dramatic change in microstructure due in turn to an extensive beta transformation at temperatures appreciably above 1350° C. 
     EXAMPLES 4-13 
     Ten additional individual melts were prepared to contain titanium and aluminum in designated atomic ratios as well as additives in relatively small atomic percents. 
     Each of the samples was prepared as described above with reference to Examples 1-3. 
     The compositions, annealing temperatures, and test results of tests made on the compositions are set forth in Table II in comparison to alloy 12 as the base alloy for this comparison. 
     
                                           TABLE II__________________________________________________________________________                             Outer   Gamma          Anneal                 Yield  Fracture                             FiberEx.   Alloy Composit.             Temp.                 Strength                        Strength                             StrainNo.   No.   (at. %)  (°C.)                 (ksi)  (ksi)                             (%)__________________________________________________________________________2  12    Ti.sub.52 Al.sub.48             1250                 130    180  1.1             1300                  98    128  0.9             1350                  88    122  0.94  22    Ti.sub.50 Al.sub.47 Ni.sub.3             1200                 --*    131  05  24    Ti.sub.52 Al.sub.46 Ag.sub.2             1200                 --*    114  0             1300                  92    117  0.56  25    Ti.sub.50 Al.sub.48 Cu.sub.2             1250                 --*     83  0             1300                  80    107  0.8             1350                  70    102  0.97  32    Ti.sub.54 Al.sub.45 Hf.sub.1             1250                 130    136  0.1             1300                  72     77  0.18  41    Ti.sub.52 Al.sub.44 Pt.sub.4             1250                 132    150  0.39  45    Ti.sub.51 Al.sub.47 C.sub.2             1300                 136    149  0.110 57    Ti.sub.50 Al.sub.48 Fe.sub.2             1250                 --*     89  0             1300                 --*     81  0             1350                  86    111  0.511 82    Ti.sub.50 Al.sub.48 Mo.sub.2             1250                 128    140  0.2             1300                 110    136  0.5             1350                  80     95  0.112 39    Ti.sub.50 Al.sub.46 Mo.sub.4             1200                 --*    143  0             1250                 135    154  0.3             1300                 131    149  0.213 20    Ti.sub.49.5 Al.sub.49.5 Er.sub.1             +   +      +    +__________________________________________________________________________ *See asterisk note to Table I. + Material fractured during machining to prepare test specimens. 
    
     For Examples 4 and 5 heat treated at 1200° C., the yield strength was unmeasurable as the ductility was found to be essentially nil. For the specimen of Example 5 which was annealed at 1300° C., the ductility increased, but it was still undesirably low. 
     For Example 6 the same was true for the test specimen annealed at 1250° C. For the specimens of Example 6 which were annealed at 1300° and 1350° C. the ductility was significant but the yield strength was low. 
     None of the test specimens of the other Examples were found to have any significant level of ductility. 
     It is evident from the results listed in Table II that the sets of parameters involved in preparing compositions for testing are quite complex and interrelated. One parameter is the atomic ratio of the titanium relative to that of aluminum. From the data plotted in FIG. 2 it is evident that the stoichiometric ratio or non-stoichiometric ratio has a strong influence on the test properties which formed for different compositions. 
     Another set of parameters is the additive chosen to be included into the basic TiAl composition. A first parameter of this set concerns whether a particular additive acts as a substituent for titanium or for aluminum. A specific metal may act in either fashion and there is no simple rule by which it can be determined which role an additive will play. The significance of this parameter is evident if we consider addition of some atomic percentage of additive X. 
     If X acts as a titanium substituent then a composition Ti 48  Al 48  X 4  will give an effective aluminum concentration of 48 atomic percent and an effective titanium concentration of 52 atomic percent. 
     If by contrast the X additive acts as an aluminum substituent then the resultant composition will have an effective aluminum concentration of 52 percent and an effective titanium concentration of 48 atomic percent. 
     Accordingly the nature of the substitution which takes place is very important but is also highly unpredictable. 
     Another parameter of this set is the concentration of the additive. 
     Still another parameter evident from Table II is the annealing temperature. The annealing temperature which produces the best strength properties for one additive can be seen to be different for a different additive. This can be seen by comparing the results set forth in Example 6 with those set forth in Example 7. 
     In addition there may be a combined concentration and annealing effect for the additive so that optimum property enhancement, if any enhancement is found, can occur at a certain combination of additive concentration and annealing temperature so that higher and lower concentrations and/or annealing temperatures are less effective in providing a desired property improvement. 
     The content of Table II makes clear that the results obtainable from addition of a ternary element to a non-stoichiometric TiAl composition are highly unpredictable and that most test results are unsuccessful with respect to ductility or strength or to both. 
     EXAMPLES 14-17 
     Four additional samples were prepared as described above with reference to Examples 1-3 to contain titanium aluminide having compositions respectively as listed in Table III. 
     The Table III summarizes the bend test results on all of the alloys both standard and modified under the various heat treatment conditions deemed relevant. 
     
                                           TABLE III__________________________________________________________________________Four-Point Bend Properties of W-Modified TiAl Alloys                              Weight                          Outer                              Loss After   Gamma   Compo-         Annealing                Yield                     Fracture                          Fiber                              48 hours   Alloy   sition         Temperature                Strength                     Strength                          Strain                              at 980° C.Ex.   Number   (at. %)         (°C.)                (ksi)                     (ksi)                          (%) (mg/cm2)__________________________________________________________________________ 2 12   Ti.sub.52 Al.sub.48         1250   130  180  1.1 +         1300    98  128  0.9 +         1350    88  122  0.9 31         1400    70   85  0.2 +14 120  Ti.sub.52 Al.sub.46 W.sub.2         1250   *     74  0   +         1300   114  147  0.51                              +         1350    69   79  0.27                              +         1400   *     43  0   215 15   Ti.sub.50 Al.sub.48 W.sub.2         1250   105  136  0.5 +         1300   114  147  1.0 1         1350   101  139  1.0 +16 93   Ti.sub.48 Al.sub. 50 W.sub.2         1250   *     97  0   +         1300   111  124  0.3 +         1350   118  125  0.2 +         1400   *     76  0   +17 16   Ti.sub.48 Al.sub.48 W.sub.4         1300   122  161  0.9 0__________________________________________________________________________ *see Table I + not measured 
    
     From the results tabulated in Table III, it is evident that alloys 15 and 16 are the alloys displaying a remarkably good combination of properties including yield strength, fracture strength, ductility, and resistance to high temperature (980° C.) oxidation. 
     The test of oxidation, and the complementary test of oxidation resistance, involves heating a sample to be tested at a temperature of 982° C. for a period of 48 hours. After the sample has cooled, it is scraped to remove any oxide scale. By weighing the sample both before and after the heating and scraping, a weight difference can be determined. Weight loss is determined in mg/cm 2  by dividing the total weight loss in grams by the surface area of the specimen in square centimeters. This oxidation test is the one used for all measurements of oxidation or oxidation resistance as set forth in this application. 
     In this regard, please note that the alloy 12 of Example 2 contained no tungsten and the weight loss after 48 hours at 980° C. was quite high and specifically 31 mg/cm 2 . 
     By contrast, alloys 120 and 15 which each contained 2 atomic percent tungsten had weight loss after heating for 48 hours at 980° C. of only 2 mg/cm 2  and 1 mg/cm 2  respectively. This represents a fifteen fold reduction for alloy 120 and an even more remarkable thirty fold reduction for alloy 15. 
     Probably most remarkable of all is the reduction to zero to alloy 16 containing 4 atomic percent tungsten. 
     At the same time that these very good reductions in weight loss are achieved, the alloys display a unique and unusual high strength coupled with a valuable ductility. It is the strength of these alloys though when coupled with oxidation resistance which is their most unique and valuable property set. 
     Please note, for example, the Ti 50  Al 48  W 2  alloy annealed at 1300° C. The yield strength is increased over the base alloy by 16%. The fracture strength is increased by 20%. The ductilities are about equal. But the oxidation resistance at 980° C. is improved over thirty fold. The combined improvement is thus truly remarkable. 
     The properties of the tungsten-containing alloy relative to the base Ti 52  Al 48  alloy are plotted in the figures. 
     FIG. 3 illustrates the relationship between load in pounds and cross heat displacement in mils. 
     FIG. 4 illustrates the comparative strength and ductility as measured by the four point bending test for alloys 12 and 16 after annealing at 1300° C. 
     FIG. 5 illustrates yield strength versus temperature. 
     FIG. 6 illustrates comparative oxidation resistance.