Classifications

• • C—CHEMISTRY; METALLURGY
  • C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
  • C22F—CHANGING THE PHYSICAL STRUCTURE OF NON-FERROUS METALS AND NON-FERROUS ALLOYS
  • C22F1/00—Changing the physical structure of non-ferrous metals or alloys by heat treatment or by hot or cold working
  • C22F1/16—Changing the physical structure of non-ferrous metals or alloys by heat treatment or by hot or cold working of other metals or alloys based thereon
  • C22F1/18—High-melting or refractory metals or alloys based thereon
  • C22F1/183—High-melting or refractory metals or alloys based thereon of titanium or alloys based thereon
• • C—CHEMISTRY; METALLURGY
  • C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
  • C22C—ALLOYS
  • C22C14/00—Alloys based on titanium

Definitions

• the present invention relates to a near-beta titanium alloy and, more particularly, to a heat treatment and heat treated near-beta titanium alloy casting.
• Background of the Invention Near-beta titanium alloys are known in the art and are described in published European application 2003/0164212 Al and published Japanese abstract JP 7011406 A2.
• the present invention provides in an illustrative embodiment a heat treatment for a near-beta titanium alloy as well as a heat treated near-beta titanium alloy casting having a Widmanstatten microstructure comprising primary alpha phase precipitates and secondary alpha phase precipitates in a beta phase matrix.
• the heat treatment produces a hardness that correlates to a desirable combination of tensile strength and ductility of the heat treated near beta-titanium alloy casting for load-bearing structural applications.
• Figure 1 is a graph of Vickers hardness at different cooling rates versus aging temperature for a near-beta Ti-5A15Mo-5V-3Cr (Ti-5553) alloy. Ultimate tensile strength, yield strength, and % elongation are also set forth for certain data points.
• Figure 2 is a graph correlating Vickers hardness versus ultimate tensile strength (UTS), yield strength (YS), and ductility (El) for the heat treated near-beta Ti-5553 alloy.
• Figure 3a, 3b; 4a, 4b; and 5a,5b are photomicrographs at 1000X of the heat treated near-beta Ti-5553 alloy showing a Widmanstatten microstructure having primary and secondary alpha phase needle-shaped precipitates in cross-sections of the photomicrographs (i.e. cross-sections through primary and secondary alpha phase platelet-shaped precipitates in . the actual alloy body).
• Figures 6a, 6b are photomicrographs at 2500X and 10000X, respectively, of the heat treated near-beta Ti-5553 alloy having a Vickers hardness of about 380 showing a Widmanstatten microstructure having primary and secondary alpha phase needle-shaped precipitates in cross-sections of the photomicrographs (i.e. cross-sections through primary and secondary alpha phase platelet-shaped precipitates in the actual alloy body).
• Figure 7 is a graph of room and elevated temperature strength and ductility of the Ti-5553 alloy casting.
• Figure 8 is a table comparing room temperature mechanical properties of the heat treated Ti-5553 casting versus those of a Ti-6A1-4V (designated Ti-64) casting.
• the present invention provides a heat treatment for near-beta titanium alloys and especially for a cast and optionally hot isostatically pressed near-beta titanium alloy as well as a near-beta titanium alloy casting having a heat treated, refined Widmanstatten microstructure.
• a near-beta titanium alloy is one wliich is quenchable from a solution temperature at or above the alpha/beta transformation temperature and which retains some or all of the beta phase upon quenching to room temperature.
• a near- beta titanium alloy (designated Ti-5553) that can be heat treated pursuant to the invention comprises, in weight percent, about 4.4 to about 5.7% Al, about 4.0 to about 5.5% Mo, about 4.0 to about 5.5% V, about 2.5 to about 3.5% Cr, about 0.3 to about 0.5% Fe, and balance essentially titanium (designated Ti-5553 alloy).
• Table 1 sets forth an illustrative alloy composition (Specification) as well as actual (Target) tested alloy composition. TABLE 1
• the Ti-5553 alloy has potential use as a cast load-bearing structural component including but not limited to an airframe structural component, such as a bulkhead casting, landing gear component, and other components.
• an airframe structural component such as a bulkhead casting, landing gear component, and other components.
• the alloy typically is investment cast to the desired airframe shape using the well known "lost wax" technique followed by hot isostatic pressing (HIP'ing) of the casting (e.g. HIP'ing at 1650 degrees F at 15 ksi for 2 hours).
• HIP'ing hot isostatic pressing
• the HJJP'ed airframe structural casting then is heat treated pursuant to the invention to develop a desirable combination of mechanical properties, such as tensile strength and ductility.
• the invention of course envisions heat treating components cast using other casting methods.
• An illustrative vacuum heat treatment of the invention comprises a solution heat treatment for a time above the alpha beta transformation temperature (1580 degrees F for Ti5553) of the alloy followed by cooling to a low aging temperature relative to the alpha/beta transformation temperature (e.g. at least 400 degrees F below the transformation temperature) to provide a relatively large amount of undercooling and then aging at an aging temperature to form a duplex refined Widmanstatten microstructure comprising primary alpha phase needles when viewed in sectioned metallographic samples and secondary alpha phase needles precipitated when viewed in sectioned metallographic samples in a beta phase matrix.
• the vacuum heat treatment produces a hardness that corresponds with a desirable combination of tensile strength and ductility of the heat treated near beta- titanium alloy casting.
• the invention is not limited to a vacuum heat treatment since the heat treatment can be conducted in an inert gas or other gas atmosphere that is not adversely reactive to the alloy.
• conducted at lxlO "4 to lxl 0 "5 ton) includes a solution treatment of the optionally HIP'ed casting at 1620 degrees F for 2 hours followed by cooling in vacuum at a rate of 300 degrees F/hour to a lower temperature of about 1000-1200 degrees F and aging at an aging temperature, such as for example 1000-1200 degrees F, for 8 hours in vacuum to produce a Vickers hardness of about 380, more generally 375 to 385, as measured using a 300 gram load, and the above-described microstructure. Cooling at 300 degrees F/hour can be achieved by computer controlled power-down of the vacuum heat treatment furnace. After the heat treatment, the heat treated casting can be gas fan cooled (GFC) in the heat treatment furnace to room temperature.
• GFC gas fan cooled
• the casting can be cooled to the lower temperature and then gas fan cooled (GFC) in the heat treatment furnace to room temperature.
• GFC gas fan cooled
• the casting then can be reheated to and aged at an aging temperature such as 1000-1200 degrees F for a period of time such as 8 hours.
• a Vickers hardness measured using a 300 gram load
• 380 provides a desirable combination of tensile strength and ductility of the heat treated near beta-titanium alloy casting.
• a Ti-5553 casting having such a Vickers hardness provides a desirable combination of tensile strength and ductility; namely, room temperature ultimate tensile strength (UTS) of 164 Ksi, room temperature tensile yield strength (YS) of 150 Ksi, and elongation (El) expressed as ductility of 7-9%.
• the Ti5553 titanium alloy is heat treatable pursuant to the invention to produce uniform, high strength micro structures over a broad thickness range up to, for example, 1.5 to 2 inches thickness of a casting.
• Figures 3 a, 3b; 4a, 4b; 5 a, 5b; and 6a, 6b illustrate Widmanstatten microstructures produced using different cooling rates from the 1620 degrees F solution temperature and different aging temperatures as well as the corresponding Vickers hardness achieved.
• Figures 6a, 6b more clearly show that the heat treated microstructure pursuant to the invention comprises a combination of primary (coarse) alpha phase appearing in the photomicrographs as coarse needles and secondary (fine) alpha phase appearing as secondary needles in the photomicrographs precipitated during cooling and aging in a beta phase matrix.
• Figure 1 shows the measured Vickers hardness at different aging temperatures and at different cooling rates from the solution temperature.
• Figure 2 correlates the Vickers hardness to room temperature strength and ductility.
• a faster cooling rate e.g. 500 degrees F/hour
• a slower cooling rate e.g. 100 degrees/hour
• aging temperatures 1050 degrees F and 1100 degrees F also were evaluated.
• the invention envisions using alternative cooling rates and aging temperatures to achieve the optimum combination of mechanical properties produced by the preferred vacuum heat treatment described above. For example, a cooling rate of 500 degrees F/hour from the solution temperature and an aging temperature of 1060 degrees F for 8 hours may produce such an optimum combination of properties.
• obtainment of the optimum combination of mechanical properties for a given service application involves controlling the heat treated microstructural refinement and concomitant Vickers hardness through a combination of controlled undercooling (and thus nucleation density of the alpha phase) and aging.
• Figure 7 shows the room temperature and elevated temperature (up to 800 degrees F) mechanical properties of the heat treated Ti-5553 alloy (Vickers hardness of about 380).
• Figure 8 is a table comparing certain room temperature mechanical properties of the heat treated Ti-5553 casting pursuant to the invention versus those of a Ti-6A1-4V casting (designated Ti-64).
• the heat treated Ti-5553 alloy exhibits a substantial improvement in ultimate tensile strength (UTS) and tensile yield strength (TYS) compared to the Ti-6A1-4V casting with the same elongation. Also the compressive strength and bearing ultimate tensile (UTS) and bearing yield strength (YS) of the heat treated Ti-5553 alloy were improved over the Ti-6A1-4V casting.
• Figure 9 is a graph showing room temperature high cycle fatigue (HCF) strength for the heat treated Ti-5553 casting and a Ti-6A1-4V casting (designated Ti-64).
• HCF room temperature high cycle fatigue
• the room temperature high cycle fatigue (HCF) strength of the heat treated Ti-5553 casting is much better than that of the Ti-6A1-4V casting.
• the room temperature high cycle fatigue (HCF) strength of the heat treated Ti-5553 casting is generally equal to that of wrought titanium alloys, which for example exhibit HCF strengths of 110 ksi at 10 7 cycles.
• the heat treated Ti-5553 casting exhibited good fracture toughness.

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• 2005
  • 2005-06-09 EP EP05770257A patent/EP1786943A4/de not_active Withdrawn
  • 2005-06-09 JP JP2007527743A patent/JP2008502808A/ja active Pending
  • 2005-06-09 WO PCT/US2005/020374 patent/WO2005123976A2/en active Application Filing
  • 2005-06-09 RU RU2007100129/02A patent/RU2007100129A/ru not_active Application Discontinuation

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