Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
  • B21J—FORGING; HAMMERING; PRESSING METAL; RIVETING; FORGE FURNACES
  • B21J5/00—Methods for forging, hammering, or pressing; Special equipment or accessories therefor
• • 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
• • 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

Definitions

• the present disclosure relates to methods for processing titanium alloys.
• Methods for producing titanium and titanium alloys having coarse grain (CG), fine grain (FG), very fine grain (VFG), or ultrafine grain (UFG) microstructure involve the use of multiple reheats and forging steps.
• Forging steps may include one or more upset forging steps in addition to draw forging on an open die press.
• the term "coarse grain” refers to alpha grain sizes of 400 ⁇ down to greater than about 14 pm; the term “fine grain” refers to alpha grain sizes in the range of 14 m down to greater than 10 ⁇ ; the term “very fine grain” refers to alpha grain sizes of 10 m down to greater than 4.0 ⁇ ; and the term “ultrafine grain” refers to alpha grain sizes of 4.0 pm or less.
• Known methods intended for the manufacture of fine grain, very fine grain, or ultrafine grain microstructures apply a multi-axis forging (MAF) process at an ultra-slow strain rate of 0.001 s "1 or slower (see, for example, G. Salishchev, et. al., Materials Science Forum, Vol. 584-586, pp. 783-788 (2008)).
• the generic MAF process is described in, for example, C. Desrayaud, et. al, Journal of Materials Processing Technology, 172, pp. 152-156 (2006).
• the key to grain refinement in the ultra-slow strain rate MAF process is the ability to continually operate in a regime of dynamic recrystallization that is a result of the ultra-slow strain rates used, i.e., 0.001 s " or slower.
• the ultra- slow strain rate MAF process uses dynamic recrystallization to continually recrystallize grains during the forging process.
• Relatively uniform cubes of ultrafine grain Ti-6-4 alloy (UNS R56400) can be produced using the ultra-slow strain rate MAF process, but the cumulative time taken to perform the MAF steps can be excessive in a commercial setting.
• conventional large scale, commercially available open die press forging equipment may not have the capability to achieve the ultra-slow strain rates required in such
• a method of refining the grain size of a workpiece comprising a titanium alloy comprises beta annealing the workpiece. After beta annealing, the workpiece is cooled to a
• Multi-axis forging comprises: press forging the workpiece at a workpiece forging temperature in a workpiece forging temperature range in the direction of a first orthogonal axis of the workpiece with a strain rate sufficient to adiabatically heat an internal region of the workpiece; press forging the workpiece at a workpiece forging temperature in the workpiece forging temperature range in the direction of a second orthogonal axis of the workpiece with a strain rate that is sufficient to
• the adiabatically heated internal region of the workpiece is allowed to cool to a temperature at or near the workpiece forging temperature in the workpiece forging temperature range, and an outer surface region of the workpiece is heated to a temperature at or near the workpiece forging temperature in the workpiece forging temperature range. At least one of the press forging steps is repeated until a total strain of at least 1.0 is achieved in at least a region of the workpiece.
• At least one of the press forging steps is repeated until a total strain of at least 1.0 up to less than 3.5 is achieved in at least a region of the workpiece.
• a strain rate used during press forging is in the range of 0.2 s " to 0.8 s 1 .
• a non-limiting embodiment of a method of refining the grain size of a workpiece comprising a titanium alloy includes beta annealing the workpiece. After beta annealing, the workpiece is cooled to a temperature below the beta transus temperature of the titanium alloy. The workpiece is then multi-axis forged using a sequence comprising the following forging steps. [0012] The workpiece is press forged at a workpiece forging temperature in a workpiece forging temperature range in the direction of a first orthogonal A-axis of the workpiece to a major reduction spacer height with a strain rate that is sufficient to adiabatically heat an internal region of the workpiece. As used herein, a major reduction spacer height is a distance equivalent to the final forged dimension desired for each orthogonal axis of the workpiece.
• the workpiece is press forged at the workpiece forging temperature in the workpiece forging temperature range in the direction of a second orthogonal B-axis of the workpiece in a first blocking reduction to a first blocking reduction spacer height.
• the first blocking reduction is applied to bring the workpiece back to substantially the pre-forging shape of the workpiece. While the strain rate of the first blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non- limiting embodiment, adiabatic heating during the first blocking reduction may not occur because the total strain incurred in the first blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the first blocking reduction spacer height is larger than the major reduction spacer height.
• the workpiece is press forged at the workpiece forging temperature in the workpiece forging temperature range in the direction of a third orthogonal C-axis of the workpiece in a second blocking reduction to a second blocking reduction spacer height.
• the second blocking reduction is applied to bring the workpiece back to substantially the pre-forging shape of the workpiece. While the strain rate of the second blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non-limiting embodiment, adiabatic heating during the second blocking reduction may not occur because the total strain incurred in the second blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the second blocking reduction spacer height is greater than the major reduction spacer height.
• the workpiece is press forged at a workpiece forging temperature in the workpiece forging temperature range in the direction of the second orthogonal B-axis of the workpiece to the major reduction spacer height with a strain rate that is sufficient to adiabatically heat an internal region of the workpiece.
• the workpiece is press forged at the workpiece forging temperature in the workpiece forging temperature range in the direction of the third orthogonal C-axis of the workpiece in a first blocking reduction to the first blocking reduction spacer height.
• the first blocking reduction is applied to bring the workpiece back to substantially the pre-forging shape of the workpiece. While the strain rate of the first blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non- limiting embodiment, adiabatic heating during the first blocking reduction may not occur because the total strain incurred in the first blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the first blocking reduction spacer height is larger than the major reduction spacer height.
• the workpiece is press forged at the workpiece forging temperature in the workpiece forging temperature range in the direction of the first orthogonal A-axis of the workpiece in a second blocking reduction to the second blocking reduction spacer height.
• the second blocking reduction is applied to bring the workpiece back to substantially the pre-forging shape of the workpiece. While the strain rate of the second blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non-limiting embodiment, adiabatic heating during the second blocking reduction may not occur because the total strain incurred in the second blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the second blocking reduction spacer height is larger than the major reduction spacer height.
• the workpiece is press forged at the workpiece forging temperature in the workpiece forging temperature range in the direction of the third orthogonal C-axis of the workpiece in a major reduction to the major reduction spacer height with a strain rate that is sufficient to adiabatically heat an internal region of the workpiece.
• the workpiece is press forged at the workpiece forging temperature in the workpiece forging temperature range in the direction of the first orthogonal A-axis of the workpiece in a first blocking reduction to the first blocking reduction spacer height.
• the first blocking reduction is applied to bring the workpiece back to substantially the pre-forging shape of the workpiece. While the strain rate of the first blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non- limiting embodiment, adiabatic heating during the first blocking reduction may not occur because the total strain incurred in the first blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the first blocking reduction spacer height is larger than the major reduction spacer height.
• the workpiece is press forged at the workpiece forging temperature in the workpiece forging temperature range in the direction of the second orthogonal B- axis of the workpiece in a second blocking reduction to the second blocking reduction spacer height.
• the second blocking reduction is applied to bring the workpiece back to substantially the pre-forging shape of the workpiece. While the strain rate of the second blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non-limiting embodiment, adiabatic heating during the second blocking reduction may not occur because the total strain incurred in the second blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the second blocking reduction spacer height is larger than the major reduction spacer height.
• the adiabatically heated internal region of the workpiece is allowed to cool to about the workpiece forging temperature in the workpiece forging temperature range, and the outer surface region of the workpiece is heated to about the workpiece forging temperature in the workpiece forging temperature range.
• At least one of the foregoing press forging steps of the method embodiment is repeated until a total strain of at least 1.0 is achieved in at least a region of the workpiece.
• at least one of the press forging steps is repeated until a total strain of at least 1.0 and up to less than 3.5 is achieved in at least a region of the workpiece.
• a strain rate used during press forging is in the range of 0.2 s "1 to 0.8 s "1 .
• FIG. 1 is graph plotting a calculated prediction of the volume fraction of equilibrium alpha phase present in Ti-6-4, Ti-6-2-4-6, and Ti-6-2-4-2 alloys as a function of temperature;
• FIG. 2 is a flow chart listing steps of a non-limiting embodiment of a method for processing titanium alloys according to the present disclosure
• FIG. 3 is a schematic representation of aspects of a non-limiting embodiment of a high strain rate multi-axis forging method using thermal management for processing titanium alloys for the refinement of grain sizes, wherein FIGS. 2(a), 2(c), and 2(e) represent non-limiting press forging steps, and FIGS 2(b), 2(d), and 2(f) represent optional non-limiting cooling and heating steps according to non-limiting aspects of the present disclosure;
• FIG. 4 is a schematic representation of aspects of a prior art slow strain rate multi-axis forging technique known to be used to refine grain size of small scale samples;
• FIG. 5 is a flow chart listing steps of a non-limiting embodiment of a method for processing titanium alloys according to the present disclosure including major orthogonal reductions to the final desired dimension of the workpiece and first and second blocking reductions;
• FIG. 6 is a temperature-time thermomechanical process chart for a non- limiting embodiment of a high strain rate multi-axis forging method according to the present disclosure
• FIG. 7 is a temperature-time thermomechanical process chart for a non- limiting embodiment of a multi-temperature high strain rate multi-axis forging method according to the present disclosure
• FIG. 8 is a temperature-time thermomechanical process chart for a non- limiting embodiment of a through beta transus high strain rate multi-axis forging method according the present disclosure
• FIG. 9 is a schematic representation of aspects of a non-limiting embodiment of a multiple upset and draw method for grain size refinement according to the present disclosure
• FIG. 10 is a flow chart listing steps of a non-limiting embodiment of a method for multiple upset and draw processing titanium alloys to refine grain size according to the present disclosure
• FIG. 1 1 (a) is a micrograph of the microstructure of a commercially forged and processed Ti-6-2-4-2 alloy; [0034] FIG. 1 1 (b) is a micrograph of the microstructure of a Ti-6-2-4-2 alloy processed by the thermally managed high strain MAF embodiment described in
• FIG. 12(a) is a micrograph that depicts the microstructure of a
• FIG. 12(b) is a micrograph of the microstructure of a Ti-6-2-4-6 alloy processed by the thermally managed high strain MAF embodiment described in
• FIG. 13 is a micrograph of the microstructure of a Ti-6-2-4-6 alloy processed by the thermally managed high strain MAF embodiment described in
• FIG. 14 is a micrograph of the microstructure of a Ti-6-2-4-2 alloy processed by the thermally managed high strain MAF embodiment described in
• FIG. 15 is a micrograph of the microstructure of a ⁇ -6-2-4-2 alloy processed by the thermally managed high strain MAF embodiment, described in Example 5 of the present disclosure, wherein blocking reductions are used to minimize bulging of the workpiece that occurs after each major reduction;
• FIG. 16(a) is a micrograph of the microstructure of the center region of a
• FIG. 16(b) is a micrograph of the microstructure of the surface region of a Ti-6-2-4-2 alloy processed by the thermally managed high strain MAF embodiment utilizing through beta transus MAF that is described in Example 6 of the present disclosure.
• any numerical range recited herein is intended to include all subranges subsumed therein.
• a range of "1 to 10" is intended to include all sub-ranges between (and including) the recited minimum value of 1 and the recited maximum value of 10, that is, having a minimum value equal to or greater than 1 and a maximum value of equal to or less than 10.
• Any maximum numerical limitation recited herein is intended to include all lower numerical limitations subsumed therein and any minimum numerical limitation recited herein is intended to include all higher numerical limitations subsumed therein. Accordingly, Applicants reserve the right to amend the present disclosure, including the claims, to expressly recite any sub-range subsumed within the ranges expressly recited herein.
• a multi-axis forging process for titanium alloys that includes the application of high strain rates during the forging steps to refine grain size.
• These method embodiments are generally referred to in the present disclosure as “high strain rate multi-axis forging” or “high strain rate MAF”.
• the terms “reduction” and “hit” interchangeably refer to an individual press forging step, wherein a workpiece is forged between die surfaces.
• the phrase “spacer height” refers to the dimension or thickness of a workpiece measured along one orthogonal axis after a reduction along that axis.
• the thickness of the press forged workpiece measured along that axis will be about 4.0 inches.
• spacer heights are well known to those having ordinary skill in the field of press forging and need not be further discussed herein.
• Methods according to the present disclosure involve the application of multi-axis forging and its derivatives, such as the multiple upset and draw (MUD) process disclosed in the '538 Application, to titanium alloys exhibiting slower effective alpha precipitation and growth kinetics than Ti-6-4 alloy.
• MOD multiple upset and draw
• Ti-6AI-2Sn-4Zr-2Mo- 0.08Si alloy (UNS R54620), which also may be referred to as "Ti-6-2-4-2” alloy, has slower effective alpha kinetics than Ti-6-4 alloy as a result of additional grain pinning elements such as Si.
• Ti-6AI-2Sn-4Zr-6Mo alloy (UNS R56260), which also may be referred to as "Ti-6-2-4-6" alloy, has slower effective alpha kinetics than T-6-4 alloy as a result of increased beta stabilizing content. It is recognized that in terms of alloying elements, the growth and precipitation of the alpha phase is a function of the diffusion rate of the alloying element in the titanium-base alloy. Molybdenum is known to have one of the slower diffusion rates of all titanium alloying additions. In addition, beta stabilizers, such as molybdenum, lower the beta transus temperature (Tp) of the alloy, wherein the lower ⁇ results in general slower diffusion of atoms in the alloy at the processing temperature for the alloy.
• Tp beta transus temperature
• a result of the relatively slow effective alpha precipitation and growth kinetics of the Ti-6-2-4-2 and Ti-6-2-4-6 alloys is that the beta heat treatment that is used prior to MAF according to embodiments of the present disclosure produces a fine and stable alpha lath size when compared to the effect of such processing on Ti-6-4 alloy.
• the Ti-6-2-4-2 and Ti-6-2-4-6 alloys possess a fine beta grain structure that limits the kinetics of alpha grain growth.
• alloys such as Ti-6-2-4-6 alloy and Ti-6-2-4-2 alloy, which contain molybdenum, show the desirable, slow alpha kinetics required to achieve ultrafine grain microstructures at comparatively lower strain than Ti-6-4 alloy where the kinetics are controlled by the diffusion of aluminum. Based on periodic table group relationships, one could also reasonably postulate that tantalum and tungsten belong to the group of slow diffusers.
• beta transus temperature in alloys controlled by aluminum diffusion will have a similar effect.
• a beta transus temperature reduction of 100°C will reduce the diffusivity of aluminum in the beta phase by approximately an order of magnitude at the beta transus temperature.
• the alpha kinetics in alloys such as ATI 425 ® alloy (Ti-4AI-2.5V; UNS 54250) and Ti-6-6-2 alloy (Ti-6AI-6V-2SN; UNS 56620) are likely controlled by aluminum diffusion; however, the lower beta transus temperatures of these alloys relative to Ti-6AI-4V alloy also result in the desirable, slower effective alpha kinetics.
• Ti-6AI-7Nb alloy normally a biomedical version of Ti-6AI-4V alloy, may also exhibit slower effective alpha kinetics because of the niobium content.
• alpha+beta alloys other than Ti-6-4 alloy could be processed under conditions similar to those disclosed in the '538 Application at temperatures that would result in similar volume fractions of the alpha phase.
• Ti-6-4 alloy at 1500°F (815.6°C) should have approximately the same volume fraction of the alpha phase as both Ti-6-2-4-2 alloy at 1600°F (871.1 °C) and Ti-6- 2-4-6 alloy at 1200°F (648.9°C) See FIG. 1.
• both Ti-6-2-4-2 and Ti-6-2-4-6 alloys cracked severely when processed in the manner in which Ti-6-4 alloy was processed in the '538 Application using temperatures that it was predicted would produce a similar volume fraction of the alpha phase. Much higher temperatures, resulting in lower equilibrium volume fractions of alpha, and/or significantly reduced strain per pass were required to successfully process the Ti-6-2-4-2 and Ti-6-2-4-6 alloys.
• Variations to the high strain rate MAF process including alpha/beta forging temperature(s), strain rate, strain per hit, hold time between hits, number and duration of reheats, and intermediate heat treatments can each affect the resultant microstructure and the presence and extent of cracking.
• Lower total strains were initially attempted in order to inhibit cracking, without any expectation that ultrafine grain structures would result.
• the samples processed using lower total strains showed significant promise for producing ultrafine grain structures. This result was entirely unanticipated.
• a method for producing ultrafine grain sizes includes the following steps: 1 ) selecting a titanium alloy exhibiting effective alpha-phase growth kinetics slower than Ti-6-4 alloy; 2) beta annealing the titanium alloy to produce a fine, stable alpha lath size; and 3) high strain rate MAF (or a similar derivative process, such as the multiple upset and draw (MUD) process disclosed in the '538 Application) to a total strain of at least 1.0, or in another embodiment, to a total strain of at least 1.0 up to less than 3.5.
• MAF multiple upset and draw
• fine for describing the grain and lath sizes, as used herein, refers to the smallest grain and lath size that can be achieved, which in non-limiting embodiments is on the order of 1 ⁇ .
• stable is used herein to mean that the multi-axis forging steps do not significantly coarsen the alpha grain size, and do not increase the alpha grain size by more than about 100%.
• FIG. 2 and the schematic representation in FIG. 3 illustrate aspects of a non-limiting embodiment according to the present disclosure of a method (16) of using a high strain rate multi-axis forging (MAF) to refine grain size of titanium alloys.
• a titanium alloy workpiece 24 Prior to multi-axis forging (26), a titanium alloy workpiece 24 is beta annealed (18) and cooled (20). Air cooling is possible with smaller workpieces, such as, for example, 4 inch cubes; however, water or liquid cooling also can be used. Faster cooling rates result in finer lath and alpha grain sizes.
• Beta annealing (18) comprises heating the workpiece 24 above the beta transus temperature of the titanium alloy of the workpiece 24 and holding for a time sufficient to form all beta phase in the
• Beta annealing (18) is a process well-known to a person of ordinary skill and, therefore, is not described in detail herein.
• a non-limiting embodiment of beta annealing may include heating the workpiece 24 to a beta annealing temperature that is about 50°F (27.8°C) above the beta transus temperature of the titanium alloy and holding the workpiece 24 at the temperature for about 1 hour.
• the workpiece 24 is cooled (20) to a temperature below the beta transus temperature of the titanium alloy of the
• ambient temperature refers to the temperature of the surroundings.
• ambient temperature refers to the temperature of the factory surroundings.
• cooling (20) can include quenching. Quenching includes immersing the workpiece 24 in water, oil, or another suitable liquid and is a process understood by a person skilled in the metallurgical arts. In other non-limiting
• cooling (20) may comprise air cooling. Any method of cooling a titanium alloy workpiece 24 known to a person skilled in the art now or hereafter is within the scope of the present disclosure.
• cooling (20) comprises cooling directly to a workpiece forging temperature in the workpiece forging temperature range for subsequent high strain rate multi-axis forging.
• High strain rate multi-axis forging includes heating (step 22 in FIG. 2) a workpiece 24 comprising a titanium alloy to a workpiece forging temperature in a workpiece forging temperature range that is within the alpha+beta phase field of the titanium alloy, followed by MAF (26) using a high strain rate.
• the cooling step (20) comprises cooling to a temperature in the workpiece forging temperature range
• the heating step (22) is not necessary.
• a high strain rate is used in the high strain rate MAF to adiabatically heat an internal region of the workpiece.
• the temperature of the internal region of the titanium alloy workpiece 24 should not exceed the beta transus temperature ( ⁇ ) of the titanium alloy workpiece. Therefore, in such non-limiting embodiments the workpiece forging temperature for at least the final cycle of A-B-C hits, or at least the last hit of the cycle, of high strain rate MAF should be chosen to ensure that during the high strain rate MAF the temperature of the internal region of the workpiece does not equal or exceed the beta transus temperature of the alloy.
• the temperature of the internal region of the workpiece does not exceed 20°F (1 1.1°C) below the beta transus temperature of the alloy, i.e., ⁇ ⁇ - 20°F ( ⁇ -1 1.1°C), during at least the final high strain rate cycle of A-B-C hits in the MAF or during at least the last press forging hit when a total strain of at least 1 .0, or in a range of at least 1.0 up to less than 3.5, is achieved in at least a region of the workpiece.
• a workpiece forging temperature comprises a temperature within a workpiece forging temperature range.
• the workpiece forging temperature range is 100°F (55.6°C) below the beta transus temperature (T p ) of the titanium alloy of the workpiece to 700°F (388.9°C) below the beta transus
• the workpiece forging temperature range is 300°F (166.7°C) below the beta transus temperature of the titanium alloy to 625°F (347°C) below the beta transus temperature of the titanium alloy.
• the low end of a workpiece forging temperature range is a temperature in the alpha+beta phase field wherein damage, such as, for example, crack formation and gouging, does not occur to the surface of the workpiece during the forging hit.
• the workpiece forging temperature range may be from 1120°F (604.4°C) to 1720°F
• (937.8°C), or in another embodiment may be from 1195°F (646.1 °C) to 1520°F
• the workpiece forging temperature range may be from 1020°F (548.9°C) to 1620°F
• (882.2°C) may be from 1095°F (590.6°C) to 1420°F
• the workpiece forging temperature range may be from 1080°F (582.2°C) to 1680°F (915.6°C), or in another embodiment may be from 1 155°F (623.9°C) to 1480°F (804.4°C).
• the workpiece forging temperature range when applying the embodiment of the present disclosure of FIG. 2 to a Ti-6AI-6V-2Sn alloy (UNS 56620), which also may be referred to as "Ti-6-6-2" alloy, and which has a beta transus temperature (Tp) of about 1735°F (946.1 °C), the workpiece forging temperature range may be from 1035°F (527.2°C) to 1635°F (890.6°C), or in another embodiment may be from 1 1 15°F
• the present disclosure involves the application of high strain rate multi-axis forging and its derivatives, such as the MUD method disclosed in the '538 Application, to titanium alloys that posses slower effective alpha precipitation and growth kinetics than Ti-6-4 alloy.
• MAF (26) comprises press forging (step 28, shown in FIG. 3(a)) the workpiece 24 at the
• High strain rates and fast ram speeds are used to adiabatically heat the internal region of the workpiece in non-limiting embodiments of high strain rate MAF according to the present disclosure.
• the term “high strain rate” refers to a strain rate in the range of about 0.2 s "1 to about 0.8 s ⁇ 1 .
• the term “high strain rate” refers to a strain rate in the range of about 0.2 s "1 to about 0.4 s "1 .
• an internal region of the titanium alloy workpiece may be adiabatically heated to about 200°F (11 1.1 °C) above the workpiece forging temperature.
• an internal region is adiabatically heated to a temperature in the range of about 100°F (55.6°C) to about 300°F (166.7°C) above the workpiece forging temperature.
• an internal region is adiabatically heated to a temperature in the range of about 150°F (83.3°C) to about 250°F (138.9°C) above the workpiece forging temperature.
• no portion of the workpiece should be heated above the beta transus temperature of the titanium alloy during the last cycle of high strain rate A-B-C MAF hits, or during the last hit on an orthogonal axis.
• the workpiece 24 is plastically deformed to a reduction in height or another dimension that is in the range of 20% to 50%, I.e., the dimension is reduced by a percentage within that range.
• the workpiece 24 is plastically deformed to a reduction in height or another dimension in the range of 30% to 40%.
• a known ultra-slow strain rate (0.001 s " or slower) multi-axis forging process is depicted schematically in FIG. 4.
• an aspect of multi-axis forging is that after every three-stroke, ⁇ i.e., "three-hit") cycle by the forging apparatus (which may be, for example, an open die forge), the shape and size of the workpiece approaches that of the workpiece just prior to the first hit of that three-hit cycle.
• a 5-inch sided cube-shaped workpiece is initially forged with a first "hit” in the direction of the "a" axis, rotated 90° and forged with a second hit in the direction of the orthogonal "b” axis, and then rotated 90° and forged with a third hit in the direction of the orthogonal "c" axis, the workpiece will resemble the starting cube and include approximately 5-inch sides.
• a first press forging step (28), shown in FIG. 2(a), also referred to herein as the "first hit”, may include press forging the workpiece on a top face down to a predetermined spacer height while the workpiece is at a temperature in the workpiece forging temperature range.
• spacer height refers to the dimension of the workpiece on the completion of a particular press forging reduction. For example, for a spacer height of 5 inches, the workpiece is forged to a dimension of about 5 inches. In a specific non-limiting embodiment of the method of the present disclosure, a spacer height is, for example, 5 inches. In another non-limiting embodiment, a spacer height is 3.25 inches. Other spacer heights, such as, for example, less than 5 inches, about 4 inches, about 3 inches, greater than 5 inches, or 5 inches up to 30 inches are within the scope of embodiments herein, but should not be considered as limiting the scope of the present disclosure.
• Spacer heights are only limited by the capabilities of the forge and optionally, as will be seen herein, the capabilities of the thermal management system according to non-limiting embodiments of the present disclosure to maintain the workpiece at the workpiece forging temperature. Spacer heights of less than 3 inches are also within the scope of embodiments disclosed herein, and such relatively small spacer heights are only limited by the desired characteristics of a finished product. The use of spacer heights of about 30 inches, for example, in methods according to the present disclosure allows for the production of billet-sized (e.g., 30-inch sided) cube-shaped titanium alloy forms having fine grain size, very fine grain size, or ultrafine grain size.
• billet-sized e.g., 30-inch sided
• Billet-sized cube-shaped forms of conventional alloys have been employed as workpieces that are forged into disk, ring, and case parts for aeronautical or land-based turbines, for example.
• the predetermined spacer heights that should be employed in various non-limiting embodiments of methods according to the present disclosure may be determined by a person having ordinary skill in the art without undue experimentation on considering the present disclosure.
• Specific spacer heights may be determined by a person having ordinary skill without undue experimentation.
• Specific spacer heights are dependent upon a specific alloy's susceptibility to cracking during forging. Alloys that have a higher susceptibility to cracking will require larger spacer heights, i.e., less deformation per hit to prevent cracking.
• the adiabatic heating limit must also be considered when choosing a spacer height because, at least in the last cycle of hits, the workpiece temperature should not surpass the ⁇ of the alloy.
• the forging press capability limit needs to be considered when selecting a spacer height. For example, during the pressing of a 4-inch sided cubic workpiece the cross-sectional area increases during the pressing step. As such, the total load that is required to keep the workpiece deforming at the required strain rate increases. The load cannot increase beyond the capabilities of the forging press.
• the workpiece geometry needs to be considered when selecting spacer heights. Large deformations may result in bulging of the workpiece. Too great a reduction could result in a relative flattening of the workpiece, so that the next forging hit in the direction of a different orthogonal axis could result in bending of the workpiece.
• the spacer heights used for each orthogonal axis hit are equivalent. In certain other non-limiting embodiments, the spacer heights used for each orthogonal axis hits are not equivalent.
• Non-limiting embodiments of high strain rate MAF using non-equivalent spacer heights for each orthogonal axis are presented below.
• a non-limiting embodiment of a method according to the present disclosure optionally further comprises a step of allowing (step 32) the temperature of the adiabatically heated internal region (not shown) of the workpiece to cool to a temperature at or near the workpiece forging temperature in the workpiece forging temperature range, which is shown in FIG. 3(b).
• internal region cooling times, or "waiting" times may range, for example, from 5 seconds to 120 seconds, from 10 seconds to 60 seconds, or from 5 seconds to 5 minutes.
• an "adiabatically heated internal region" of a workpiece refers to a region extending outwardly from a center of the workpiece and having a volume of at least about 50%, or at least about 60%, or at least about 70%, or at least about 80% of the workpiece. It will be recognized by a person skilled in the art that the time required to cool the internal region of a workpiece to a temperature at or near the workpiece forging temperature will depend on the size, shape, and composition of the workpiece 24, as well as on conditions of the atmosphere surrounding the workpiece 24.
• an aspect of a thermal management system 33 optionally comprises heating (step 34) an outer surface region 36 of the workpiece 24 to a temperature at or near the workpiece forging temperature.
• the temperature of the workpiece 24 is in a uniform or near uniform and substantially isothermal condition at or near the workpiece forging temperature prior to each high strain rate MAF hit. It is recognized that it is within the scope of the present disclosure to optionally heat (34) the outer surface region 36 of the workpiece 24 after each A-axis heat, after each B-axis hit, and/or after each C-axis hit.
• the outer surface of the workpiece optionally is heated (34) after each cycle of A-B-C hits.
• the outer surface region optionally is be heated after any hit or cycle of hits, as long as the overall temperature of the workpiece is maintained within the workpiece forging temperature range during the forging process.
• the times that a workpiece should be heated to maintain a temperature of the workpiece 24 in a uniform or near uniform and substantially isothermal condition at or near the workpiece forging temperature prior to each high strain rate MAF hit may depend on the size of the workpiece, and this may be determined by a person having ordinary skill without undue experimentation.
• an "outer surface region" of a workpiece refers to a region extending inwardly from an outer surface of the workpiece and having a volume of at least about 50%, or at least about 60%, or at least about 70%, or at least about 80% of the workpiece. It is recognized that at any time intermediate
• heating (34) an outer surface region 36 of the workpiece 24 may be accomplished using one or more surface heating mechanisms 38 of the thermal management system 33. Examples of possible surface heating mechanisms successive press forging steps, the entire workpiece may be placed in a furnace or otherwise heated to a temperature with the workpiece forging temperature range.
• the thermal management system 33 is used to heat the outer surface region 36 of the workpiece, and the adiabatically heated internal region is allowed to cool for an internal region cooling time so as to return the temperature of the workpiece to a substantially uniform temperature at or near the selected workpiece forging temperature.
• the thermal management system 33 is used to heat the outer surface region 36 of the workpiece, and the adiabatically heated internal region is allowed to cool for an internal region cooling time so that the temperature of the workpiece returns to a substantially uniform temperature within the workpiece forging temperature range.
• Non-limiting embodiments of a method according to the present disclosure utilizing both (1 ) a thermal management system 33 to heat the outer surface region of the workpiece to a temperature within the workpiece forging temperature range and (2) a period during which the adiabatically heated internal region cools to a temperature within the workpiece forging temperature range may be referred to herein as "thermally managed, high strain rate multi-axis forging”.38 include, but are not limited to, flame heaters adapted for flame heating; induction heaters adapted for induction heating; and radiant heaters adapted for radiant heating of the outer surface of the workpiece 24.
• Other mechanisms and techniques for heating an outer surface region of the workpiece will be apparent to those having ordinary skill upon considering the present disclosure, and such mechanisms and techniques are within the scope of the present disclosure.
• a non-limiting embodiment of an outer surface region heating mechanism 38 may comprise a box furnace (not shown).
• a box furnace may be configured with various heating mechanisms to heat the outer surface region of the workpiece using one or more of flame heating mechanisms, radiant heating mechanisms, induction heating mechanisms, and any other suitable heating mechanism known now or hereafter to a person having ordinary skill in the art.
• the temperature of the outer surface region 36 of the workpiece 24 optionally is heated (34) and maintained at or near the workpiece forging temperature and within the workpiece forging temperature range using one or more die heaters 40 of a thermal management system 33.
• Die heaters 40 may be used to maintain the dies 42 or the die press forging surfaces 44 of the dies at or near the workpiece forging temperature or at temperatures within the workpiece forging temperature range.
• the dies 42 of the thermal management system are heated to a temperature within a range that includes the workpiece forging temperature down to 100°F (55.6°C) below the workpiece forging temperature.
• Die heaters 40 may heat the dies 42 or the die press forging surface 44 by any suitable heating mechanism known now or hereafter by a person skilled in the art, including, but not limited to, flame heating mechanisms, radiant heating
• a die heater 40 may be a component of a box furnace (not shown). While the thermal management system 33 is shown in place and being used during the cooling steps (32),(52),(60) of the multi-axis forging process (26) shown in FIGS. 2(b), (d), and (f), it will be recognized that the thermal management system 33 may or may not be in place during the press forging steps (28),(46),(56) depicted in FIGS. 2(a), (c), and (e). [0076] As shown in FIG.
• an aspect of a non-limiting embodiment of a multi-axis forging method (26) comprises press forging (step 46) the workpiece 24 at a workpiece forging temperature in the workpiece forging temperature range in the direction (B) of a second orthogonal axis 48 of the workpiece 24 using a strain rate that is sufficient to adiabatically heat the workpiece 24, or at least an internal region of the workpiece 24, and plastically deform the workpiece 24.
• the workpiece 24 is deformed to a plastic deformation of a 20% to 50% reduction in height or another dimension.
• the workpiece 24 is plastically deformed to a plastic deformation of a 30% to 40% reduction in height or another dimension.
• the workpiece 24 may be press forged (46) in the direction of the second orthogonal axis 48 to the same spacer height used in the first press forging step (28).
• the workpiece 24 may be press forged in the direction of the second orthogonal axis 48 to a different spacer height than is used in the first press forging step (28).
• the internal region (not shown) of the workpiece 24 is adiabatically heated during the press forging step (46) to the same temperature as in the first press forging step (28).
• the high strain rates used for press forging (46) are in the same strain rate ranges as disclosed for the first press forging step (28).
• the workpiece 24 may be rotated (50) between successive press forging steps (e.g., (28),(46),(56)) to present a different orthogonal axis to the forging surfaces.
• This rotation may be referred to as "A-B-C" rotation. It is understood that by using different forge configurations, it may be possible to rotate the ram on the forge instead of rotating the workpiece 24, or a forge may be equipped with multi-axis rams so that rotation of neither the workpiece nor the forge is required.
• the important aspect is the relative change in position of the workpiece and the ram being used, and rotating (50) the workpiece 24 may be unnecessary or optional. In most current industrial equipment set-ups, however, rotating (50) the workpiece to a different orthogonal axis in between press forging steps will be required to complete the multi-axis forging process (26).
• A-B-C rotation (50) is required, the workpiece 24 may be rotated manually by a forge operator or by an automatic rotation system (not shown) to provide A-B-C rotation (50).
• An automatic A-B-C rotation system may include, but is not limited to including, free-swinging clamp-style manipulator tooling or the like to enable a non-limiting thermally managed high strain rate multi-axis forging embodiment disclosed herein.
• process (20) optionally further comprises allowing (step 52) an adiabatically heated internal region (not shown) of the workpiece to cool to a temperature at or near the workpiece forging temperature, which is shown in FIG. 3(d).
• internal region cooling times, or waiting times may range, for example, from 5 seconds to 120 seconds, or from 10 seconds to 60 seconds, or from 5 seconds up to 5 minutes. It will be recognized by an ordinarily skilled person that the minimum cooling times are dependent upon the size, shape, and composition of the workpiece 24, as well as the characteristics of the environment surrounding the workpiece.
• an optional aspect of a thermal management system 33 comprises heating (step 54) an outer surface region 36 of the workpiece 24 to a temperature in the workpiece forging temperature range at or near the workpiece forging temperature. In this manner, the temperature of the workpiece 24 is maintained in a uniform or near uniform and substantially isothermal condition at or near the workpiece forging temperature prior to each high strain rate MAF hit.
• the thermal management system 33 when using the thermal management system 33 to heat the outer surface region 36, together with allowing the adiabatically heated internal region to cool for a specified internal region cooling time, the temperature of the workpiece returns to a substantially uniform temperature at or near the workpiece forging temperature between each A-B-C forging hit.
• the thermal management system 33 when using the thermal management system 33 to heat the outer surface region 36, together with allowing the adiabatically heated internal region to cool for a specified internal region cooling time, the temperature of the workpiece returns to a substantially uniform temperature within the workpiece forging temperature range prior to each high strain rate MAF hit.
• heating (54) an outer surface region 36 of the workpiece 24 may be accomplished using one or more outer surface heating mechanisms 38 of the thermal management system 33.
• Examples of possible heating mechanisms 38 may include, but are not limited to, flame heaters adapted for flame heating; induction heaters adapted for induction heating; and/or radiant heaters adapted for radiant heating of the workpiece 24.
• a non-limiting embodiment of a surface heating mechanism 38 may comprise a box furnace (not shown).
• Other mechanisms and techniques for heating an outer surface of the workpiece will be apparent to those having ordinary skill upon considering the present disclosure, and such mechanisms and techniques are within the scope of the present disclosure.
• a box furnace may be configured with various heating mechanisms to heat the outer surface of the workpiece, and such heating mechanisms may comprise one or more of flame heating
• the temperature of the outer surface region 36 of the workpiece 24 may be heated (54) and maintained at or near the workpiece forging temperature and within the workpiece forging temperature range using one or more die heaters 40 of a thermal management system 33.
• Die heaters 40 may be used to maintain the dies 42 or the die press forging surfaces 44 of the dies at or near the workpiece forging temperature or at temperatures within the workpiece forging temperature range.
• Die heaters 40 may heat the dies 42 or the die press forging surfaces 44 by any suitable heating mechanism known now or hereafter by a person skilled in the art, including, but not limited to, flame heating mechanisms, radiant heating mechanisms, conduction heating mechanisms, and/or induction heating mechanisms.
• a die heater 40 may be a component of a box furnace (not shown). While the thermal management system 33 is shown in place and being used during the equilibration and cooling steps (32),(52),(60) of the multi-axis forging process (26) shown in FIGS, 2(b), (d), and (f), it is recognized that the thermal management system 33 may or may not be in place during the press forging steps (28),(46),(56) depicted in FIGS. 2(a), (c), and (e) .
• an aspect of an embodiment of multi-axis forging (26) according to the present disclosure comprises press forging (step 56) the
• the workpiece 24 at a workpiece forging temperature in the workpiece forging temperature range in the direction (C) of a third orthogonal axis 58 of the workpiece 24 using a ram speed and strain rate that are sufficient to adiabatically heat the workpiece 24, or at least adiabatically heat an internal region of the workpiece, and plastically deform the workpiece 24.
• the workpiece 24 is deformed during press forging (56) to a plastic deformation of a 20% to 50% reduction in height or another dimension.
• the workpiece is plastically deformed to a plastic deformation of a 30% to 40% reduction in height or another dimension.
• the workpiece 24 may be press forged (56) in the direction of the third orthogonal axis 58 to the same spacer height used in the first press forging step (28) and/or the second forging step (46). In another non-limiting embodiment, the workpiece 24 may be press forged in the direction of the third orthogonal axis 58 to a different spacer height than used in the first press forging step (28). In another non-limiting embodiment according to the disclosure, the internal region (not shown) of the workpiece 24 is adiabatically heated during the press forging step (56) to the same temperature as in the first press forging step (28). In other non- limiting embodiments, the high strain rates used for press forging (56) are in the same strain rate ranges as disclosed for the first press forging step (28).
• the workpiece 24 may be rotated (50) to a different orthogonal axis between successive press forging steps (e.g., 46,56). As discussed above, this rotation may be referred to as A-B-C rotation. It is understood that by using different forge
• process 20 optionally further comprises allowing (step 60) an adiabatically heated internal region (not shown) of the workpiece to cool to a temperature at or near the workpiece forging temperature, which is indicated in FIG. 3(f).
• Internal region cooling times may range, for example, from 5 seconds to 120 seconds, from 10 seconds to 60 seconds, or from 5 seconds up to 5 minutes, and it is recognized by a person skilled in the art that the cooling times are dependent upon the size, shape, and composition of the workpiece 24, as well as on the characteristics of the environment surrounding the workpiece.
• an optional aspect of a thermal management system 33 comprises heating (step 62) an outer surface region 36 of the workpiece 24 to a temperature at or near the workpiece forging temperature. In this manner, the temperature of the workpiece 24 is maintained in a uniform or near uniform and substantially isothermal condition at or near the workpiece forging temperature prior to each high strain rate MAF hit.
• the thermal management system 33 by using the thermal management system 33 to heat the outer surface region 36, together with allowing the adiabatically heated internal region to cool for a specified internal region cooling time, the temperature of the workpiece returns to a substantially uniform temperature at or near the workpiece forging temperature between each A-B-C forging hit.
• the thermal management system 33 by using the thermal management system 33 to heat the outer surface region 36, together with allowing the adiabatically heated internal region to cool for a specified internal region cooling time, the temperature of the workpiece returns to a substantially isothermal condition within the workpiece forging temperature range between successive A-B-C forging hits.
• heating (62) an outer surface region 36 of the workpiece 24 may be accomplished using one or more outer surface heating mechanisms 38 of the thermal management system 33.
• Examples of possible heating mechanisms 38 may include, but are not limited to, flame heaters for flame heating; induction heaters for induction heating; and/or radiant heaters for radiant heating of the workpiece 24.
• Other mechanisms and techniques for heating an outer surface of the workpiece will be apparent to those having ordinary skill upon considering the present disclosure, and such mechanisms and techniques are within the scope of the present disclosure.
• a non-limiting embodiment of a surface heating mechanism 38 may comprise a box furnace (not shown).
• a box furnace may be configured with various heating mechanisms to heat the outer surface of the workpiece using one or more of flame heating mechanisms, radiant heating mechanisms, induction heating
• the temperature of the outer surface region 36 of the workpiece 24 may be heated (62) and maintained at or near the workpiece forging temperature and within the workpiece forging temperature range using one or more die heaters 40 of a thermal management system 33.
• Die heaters 40 may be used to maintain the dies 42 or the die press forging surfaces 44 of the dies at or near the workpiece forging temperature or at temperatures within the temperature forging range.
• the dies 42 of the thermal management system are heated to a temperature within a range that includes the workpiece forging temperature to 100°F (55.6°C) below the workpiece forging temperature.
• Die heaters 40 may heat the dies 42 or the die press forging surface 44 by any suitable heating mechanism known now or hereafter by a person skilled in the art, including, but not limited to, flame heating mechanisms, radiant heating mechanisms, conduction heating mechanisms, and/or induction heating mechanisms.
• a die heater 40 may be a component of a box furnace (not shown). While the thermal management system 33 is shown in place and being used during the equilibration steps (32),(52),(60) of the multi-axis forging process show in FIGS. 2(b), (d), and (f), it will be recognized that the thermal management system 33 may or may not be in place during the press forging steps 28,46,56 depicted in FIGS. 2(a), (c), and (e).
• An aspect of the present disclosure includes a non-limiting embodiment wherein one or more of the press forging steps along the three orthogonal axes of a workpiece are repeated until a total strain of at least .0 is achieved in the workpiece.
• the total strain is the total true strain.
• the phrase "true strain” is also known to a person skilled in the art as “logarithmic strain” or "effective strain”. Referring to FIG. 2, this is exemplified by step (g), i.e., repeating (step 64) one or more of press forging steps (28),(46),(56) until a total strain of at least 1.0, or in the range of at least 1.0 up to less than 3.5 is achieved in the workpiece.
• the workpiece can simply be cooled to ambient temperature, in a non-limiting embodiment, by quenching in a liquid, or in another non-limiting embodiment, by air cooling or any faster rate of cooling.
• the total strain is the total strain in the entire workpiece after multi-axis forging, as disclosed herein.
• the total strain may comprise equal strains on each orthogonal axis, or the total strain may comprise different strains on one or more orthogonal axes.
• a workpiece may be multi-axis forged at two different temperatures in the alpha-beta phase field. For example, referring to FIG. 3, repeating step (64) of FIG.
• 2 may include repeating one of more of steps (a)-(optional b), (c)-(optional d), and (e)-(optional f) at a first temperature in the alpha-beta phase field until a certain strain is achieved, and then repeating one or more of steps (a)-(optional b), (c)-(optional d), and (e)-(optional f) at a second temperature in the alpha-beta phase field until after a final press forging step (a), (b), or (c) (i.e., (28),(46), (56)) a total strain of at least 1.0, or in the range of at least .0 up to less than 3.5, is achieved in the workpiece.
• the second temperature in the alpha-beta phase field is lower than first temperature in the alpha-beta phase field. It is recognized that conducting the method so as to repeat one or more of steps (a)-(optional b), (c)-(optional d), and (e)-(optional f) at more than two MAF press forging temperatures is within the scope of the present disclosure as long as the temperatures are within the forging temperature range. It is also recognized that, in a non-limiting embodiment, the second temperature in the alpha-beta phase field is higher than the first temperature in the alpha-beta phase field.
• different reductions are used for the A-axis hit, B-axis hit, and C-axis hit to provide equalized strain in all directions.
• Applying high strain rate MAF to introduce equalized strain in all directions results in less cracking of, and a more equiaxed alpha grain structure for, the workpiece.
• non-equalized strain may be introduced into a cubic workpiece by starting with a 4-inch cube that is high strain rate forged on the A- axis to a height of 3.0 inches. This reduction on the A-axis causes the workpiece to swell along the B-axis and the C-axis.
• a second reduction in the B-axis direction reduces the B-axis dimension to 3.0 inches, more strain is introduced in the workpiece on the B-axis than on the A-axis.
• a subsequent hit in the C-axis direction to reduce the C-axis dimension to 3.0 inches would introduce more strain into the workpiece on the C-axis than on the A-axis or B-axis.
• a 4-inch cubic workpiece is forged ("hit") on the A-axis to a height of 3.0 inches, rotated 90 degrees and hit on the B-axis to a height of 3.5 inches, and then rotated 90 degrees and hit on the C-axis to a height of 4.0 inches.
• Equation 1 A general equation for calculating reduction on each orthogonal axis of a cubic workpiece during high strain rate MAF is provided in Equation 1.
• Equation 2 A general equation for calculating the total strain is provided by Equation 2:
• a process (70) for the production of ultra-fine grain titanium alloy includes: beta annealing (71 ) a titanium alloy workpiece; cooling (72) the beta annealed workpiece 24 to a temperature below the beta transus temperature of the titanium alloy of the workpiece; heating (73) the workpiece 24 to a workpiece forging temperature within a workpiece forging temperature range that is within an alpha+beta phase field of the titanium alloy of the workpiece; and high strain rate MAF (74) the workpiece, wherein high strain rate MAF (74) includes press forging reductions to the orthogonal axes of the workpiece to different spacer heights.
• the workpiece 24 is press forged (75) on the first orthogonal axis (A-axis) to a major reduction spacer height.
• press forged ... to major reduction spacer height refers to press forging the workpiece along an orthogonal axis to the desired final dimension of the workpiece along the specific orthogonal axis. Therefore, the term "major reduction spacer height" is defined as the spacer height used to attain the final dimension of the workpiece along each orthogonal axis. All press forging steps to major reduction spacer heights should occur using a strain rate sufficient to
• the process (70) optionally further comprises allowing (step 76, indicated in FIG. 3(b)) an
• Internal region cooling times may range, for example, from 5 seconds to 120 seconds, from 10 seconds to 60 seconds, or from 5 seconds up to 5 minutes, and a person having ordinary skill will recognize that required cooling times will be dependent upon the size, shape, and composition of the workpiece, as well as the characteristics of the environment surrounding the workpiece.
• an aspect of a thermal management system 33 may comprise heating (step 77) an outer surface region 36 of the workpiece 24 to a temperature at or near the workpiece forging temperature.
• the temperature of the workpiece 24 is maintained in a uniform or near uniform and substantially isothermal condition at or near the workpiece forging temperature prior to each high strain rate MAF hit.
• using the thermal management system 33 to heat the outer surface region 36, together with allowing the adiabatically heated internal region to cool for a specified internal region cooling time the temperature of the workpiece returns to a substantially uniform temperature at or near the workpiece forging temperature intermediate each of the A, B, and C forging hits.
• heating (77) an outer surface region 36 of the workpiece 24 may be accomplished using one or more outer surface heating mechanisms 38 of the thermal management system 33.
• Examples of possible outer surface heating mechanisms 38 include, but are not limited to, flame heaters adapted for flame heating; induction heaters adapted for induction heating; and radiant heaters adapted for radiant heating of the workpiece 24.
• an outer surface region heating mechanism 38 may comprise a box furnace (not shown).
• a box furnace may be configured with various heating mechanisms to heat the outer surface region of the workpiece using, for example, one or more of flame heating mechanisms, radiant heating mechanisms, induction heating mechanisms, and/or any other suitable heating mechanism known now or hereafter to a person having ordinary skill in the art.
• the temperature of the outer surface region 36 of the workpiece 24 may be heated (34) and maintained at or near the workpiece forging temperature and within the workpiece forging temperature range using one or more die heaters 40 of a thermal management system 33.
• Die heaters 40 may be used to maintain the dies 42 or the die press forging surfaces 44 of the dies at or near the workpiece forging temperature or at temperatures within the workpiece forging temperature range.
• the dies 42 of the thermal management system are heated to a temperature within a range that includes the workpiece forging temperature down to 100°F (55.6°C) below the workpiece forging temperature.
• Die heaters 40 may heat the dies 42 or the die press forging surface 44 by any suitable heating mechanism known now or hereafter by a person skilled in the art, including, but not limited to, flame heating mechanisms, radiant heating mechanisms, conduction heating mechanisms, and/or induction heating mechanisms.
• a die heater 40 may be a component of a box furnace (not shown). While the thermal management system 33 is shown in place and being used during the cooling steps of the multi-axis forging process, it is recognized that the thermal management system 33 may or may not be in place during the press forging steps.
• blocking reduction spacer height otherwise referred to herein as press forging to a first blocking reduction spacer height ((78),(87),(96)) and press forging to a second blocking reduction spacer ((81 ),(90),(99))
• press forging step that is used to reduce or "square-up" the bulging that occurs near the center of any face after press forging to major reduction spacer height. Bulging at or near the center of any face results in a triaxial stress state being
• the steps of press forging to a first reduction spacer height and press forging to a second blocking reduction spacer height are employed to deform the bulged faces, so that the faces of the workpiece are flat or substantially flat before the next press forging to a major reduction spacer height along an orthogonal axis.
• the blocking reductions involve press forging to a spacer height that is greater than the spacer height used in each step of press forging to a major reduction spacer height.
• the strain rate of all of the first and second blocking reductions disclosed herein may be sufficient to adiabatically heat an internal region of the workpiece
• adiabatic heating during the first blocking and second blocking reductions may not occur because the total strain incurred in the first and second blocking reductions may not be sufficient to significantly adiabatically heat the workpiece.
• the blocking reductions are performed to spacer heights that are greater than those used in press forging to a major reduction spacer height, the strain added to the workpiece in a blocking reduction may not be enough to adiabatically heat an internal region of the workpiece.
• incorporation of the first and second blocking reductions in a high strain rate MAF process results in a forging sequence of at least one cycle consisting of: A-B-C-B-C-A-C, wherein A, B, and C comprise press forging to the major reduction spacer height, and wherein B, C, C, and A comprise press forging to first or second blocking reduction spacer heights; or in another non-limiting embodiment at least one cycle consisting of: A-B-C-B-C-A-C-A-B, wherein A, B, and C comprise press forging to the major reduction spacer height, and wherein B, C, C, A, A, and B comprise press forging to first or second blocking reduction spacer heights.
• the workpiece is press forged (78) on the B-axis to a first blocking reduction spacer height.
• the strain rate of the first blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non- limiting embodiment, adiabatic heating during the first blocking reduction may not occur because the strain incurred in the first blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the adiabatically heated internal region of the workpiece is allowed (79) to cool to a temperature at or near the workpiece forging temperature, while the outer surface region of the workpiece is heated (80) to a temperature at or near the workpiece forging temperature.
• All cooling times and heating methods for the A reduction (75) disclosed hereinabove and in other embodiments of the present disclosure are applicable for steps (79) and (80) and to all optional subsequent steps of allowing the internal region of the workpiece to cool and heating the outer surface region of the workpiece.
• the workpiece is next press forged (81 ) on the C-axis to a second blocking reduction spacer height that is greater than the major reduction spacer height.
• the first and second blocking reductions are applied to bring the workpiece back to substantially the pre-forging shape of the workpiece.
• the strain rate of the second blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non-limiting embodiment, adiabatic heating during the second blocking reduction may not occur because the strain incurred in the second blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the adiabatically heated internal region of the workpiece is allowed (82) to cool to a temperature at or near the workpiece forging temperature, while the outer surface region of the workpiece is heated (83) to a temperature at or near the workpiece forging temperature.
• the workpiece is next pressed forged to a major reduction spacer height (84) in the direction of the second orthogonal axis, or B-axis. Press forging to a major reduction spacer height on the B-axis (84) is referred to herein as a B reduction.
• the adiabatically heated internal region of the workpiece is allowed (85) to cool to a temperature at or near the workpiece forging temperature, while the outer surface region of the workpiece is heated (86) to a temperature at or near the workpiece forging temperature.
• the workpiece is next press forged (87) on the C-axis to a first blocking reduction spacer height that is greater than the major reduction spacer height. While the strain rate of the first blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non-limiting embodiment, adiabatic heating during the first blocking reduction may not occur because the strain incurred in the first blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the adiabatically heated internal region of the workpiece is allowed (88) to cool to a temperature at or near the workpiece forging temperature, while the outer surface region of the workpiece is heated (89) to a temperature at or near the workpiece forging temperature.
• the workpiece is next press forged (90) on the A-axis to a second blocking reduction spacer height that is greater than the major reduction spacer height.
• the first and second blocking reductions are applied to bring the workpiece back to substantially the pre-forging shape of the workpiece. While the strain rate of the second blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non-limiting embodiment, adiabatic heating during the second blocking reduction may not occur because the strain incurred in the second blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the adiabatically heated internal region of the workpiece is allowed (91 ) to cool to a temperature at or near the workpiece forging temperature, while the outer surface region of the workpiece is heated (92) to a temperature at or near the workpiece forging temperature.
• the workpiece is next press forged to a major reduction spacer height (93) in the direction of the third orthogonal axis, or C-axis. Press forging to the major reduction spacer height on the C-axis (93) is referred to herein as a C reduction.
• the C reduction (93)
• the adiabatically heated internal region of the workpiece is allowed (94) to cool to a temperature at or near the workpiece forging temperature, while the outer surface region of the workpiece is heated (95) to a temperature at or near the workpiece forging temperature.
• the workpiece is next press forged (96) on the A-axis to a first blocking reduction spacer height that is greater than the major reduction spacer height.
• the strain rate of the first blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non-limiting embodiment, adiabatic heating during the first blocking reduction may not occur because the strain incurred in the first blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the adiabatically heated internal region of the workpiece is allowed (97) to cool to a temperature at or near the workpiece forging temperature, while the outer surface region of the workpiece is heated (98) to a temperature at or near the workpiece forging temperature.
• the workpiece is next press forged (99) on the B-axis to a second blocking reduction spacer height that is greater than the major reduction spacer height.
• the first and second blocking reductions are applied to bring the workpiece back to substantially the pre-forging shape of the workpiece. While the strain rate of the second blocking reduction may be sufficient to adiabatically heat an internal region of the workpiece, in a non-limiting embodiment, adiabatic heating during the second blocking reduction may not occur because the strain incurred in the second blocking reduction may not be sufficient to significantly adiabatically heat the workpiece.
• the adiabatically heated internal region of the workpiece is allowed (100) to cool to a temperature at or near the workpiece forging temperature, while the outer surface region of the workpiece is heated (101 ) to a temperature at or near the workpiece forging temperature.
• one or more of press forging steps (75), (78), (81 ), (84), (87), (90), (93), (96), and (99) are repeated (102) until a total strain of at least 1.0 is achieved the titanium alloy workpiece.
• one or more of press forging steps (75), (78), (81 ), (84), (87), (90), (93), (96), and (99) are repeated (102) until a total strain in a range of at least 1.0 up to less than 3.5 is achieved in the titanium alloy workpiece.
• cooling comprise liquid quenching, such as, for example, water quenching.
• cooling comprises cooling with a cooling rate of air cooling or faster.
• a forging sequence that represents one total MAF cycle as disclosed in the above-described non-limiting embodiment may be represented as A-B-C-B-C-A-C-A-B, wherein the reductions (hits) that are in bold and underlined are press forgings to a major reduction spacer height, and the reductions that are not in bold or underlined are first or second blocking reductions.
• press forging reductions including press forging to major reduction spacer heights and the first and second blocking reductions, of the MAF process according to the present disclosure are conducted with a high strain rate that is sufficient to adiabatically heat the internal region of the workpiece, e.g., and without limitation, a strain rate in the range of 0.2 s "1 to 0.8 s " ⁇ or in the range of 0.2 s "1 to 0.4 s "1 .
• adiabatic heating may not substantially occur during the first and second blocking reductions due to the lower degree of deformation in these reductions, as compared to the major reductions.
• the use of blocking reductions intermediate each press forging to a major reduction spacer height reduces the tendency for crack formation in the workpiece.
• the first blocking reduction spacer height for a first blocking reduction may be to a spacer height that is 40-60% larger than the major reduction spacer height.
• the second blocking reduction spacer height for the second blocking reduction may be to a spacer height that is 15-30% larger than the major reduction spacer height.
• the first blocking reduction spacer height may be substantially equivalent to the second blocking reduction spacer height.
• the workpiece after a total strain of at least 1.0, or in the range of at least 1.0 up to less than 3.5, the workpiece comprises an average alpha particle grain size of 4 ⁇ or less, which is considered to be an ultra-fine grain (UFG) size.
• UFG ultra-fine grain
• applying a total strain of at least 1.0, or in the range of at least 1.0 up to less than 3.5 produces grains that are equiaxed.
• the workpiece-press die interface is lubricated with lubricants known to those of ordinary skill, such as, but not limited to, graphite, glasses, and/or other known solid lubricants.
• the workpiece comprises a titanium alloy selected from a!pha+beta titanium alloys and metastable beta titanium alloys.
• the workpiece comprises an alpha+beta titanium alloy.
• the workpiece comprises a metastable beta titanium alloy.
• a titanium alloy processed by the method according to the present disclosure comprises effective alpha phase precipitation and growth kinetics that are slower than those of Ti-6-4 alloy (UNS R56400), and such kinetics may be referred to herein as "slower alpha kinetics".
• slower alpha kinetics is achieved when the diffusivity of the slowest diffusing alloying species in the titanium alloy is slower than the diffusivity of aluminum in Ti-6-4 alloy at the beta transus temperature ( ⁇ ).
• Ti-6-2-4-2 alloy exhibits slower alpha kinetics than Ti-6-4 alloy as a result of the presence of additional grain pinning elements, such as silicon, in the Ti-6-2-4-2 alloy.
• Ti-6-2-4-6 alloy has slower alpha kinetics than Ti-6-4 alloy as a result of the presence of additional beta stabilizing alloy additions, such as higher molybdenum content than T-6-4 alloy.
• Exemplary titanium alloys that may be processed using embodiments of methods according to the present disclosure include, but are not limited to, Ti-6-2-4-2 alloy, Ti-6-2-4-6 alloy, ATI 425 ® alloy (Ti-4AI-2.5V alloy), Ti-6-6-2 alloy, and Ti-6AI-7Nb alloy.
• beta annealing comprises: heating the workpiece to a beta annealing temperature; holding the workpiece at the beta annealing temperature for an annealing time sufficient to form a 100% titanium beta phase microstructure in the workpiece; and cooling the workpiece directly to a temperature at or near the workpiece forging temperature.
• the beta annealing temperature is in a temperature range of the beta transus temperature of the titanium alloy up to 300°F (111 °C) above the beta transus temperature of the titanium alloy.
• Non-limiting embodiments include a beta annealing time from 5 minutes to 24 hours.
• beta annealing temperatures and beta annealing times are within the scope of embodiments of the present disclosure and that, for example, relatively large workpieces may require relatively higher beta annealing temperatures and/or longer beta annealing times to form a 00% beta phase titanium microstructure.
• the workpiece may also be plastically deformed at a plastic deformation temperature in the beta phase field of the titanium alloy prior to cooling the workpiece to a temperature at or near the workpiece forging temperature or to ambient temperature.
• Plastic deformation of the workpiece may comprise at least one of drawing, upset forging, and high strain rate multi-axis forging the workpiece.
• plastic deformation in the beta phase region comprises upset forging the workpiece to a beta-upset strain in the range of 0.1 to 0.5.
• the plastic deformation temperature is in a temperature range including the beta transus temperature of the titanium alloy up to 300°F (111°C) above the beta transus temperature of the titanium alloy.
• FIG. 6 is a temperature-time thermomechanical process chart for a non- limiting method of plastically deforming the workpiece above the beta transus temperature and directly cooling to the workpiece forging temperature.
• a non- limiting method 200 comprises heating 202 a workpiece comprising a titanium alloy having alpha precipitation and growth kinetics that are slower than those of Ti-6-4 alloy, for example, to a beta annealing temperature 204 above the beta transus temperature 206 of the titanium alloy, and holding or "soaking" 208 the workpiece at the beta annealing temperature 204 to form an all beta titanium phase microstructure in the workpiece.
• the workpiece may be plastically deformed 210.
• plastic deformation 210 comprises upset forging. In a non-limiting embodiment, plastic deformation 210 comprises upset forging to a true strain of 0.3. In a non-limiting embodiment, plastically deforming 210 comprises thermally managed high strain rate multi-axis forging (not shown in FIG. 6) at a beta annealing temperature.
• the workpiece is cooled 212 to a workpiece forging temperature 214 in the alpha+beta phase field of the titanium alloy.
• cooling 212 comprises air cooling or cooling at a rate faster than achieved through air cooling.
• cooling comprises liquid quenching, such as, but not limited to, water quenching.
• the workpiece is high strain rate multi-axis forged 214 according to certain non-limiting embodiments of the present disclosure.
• the workpiece is hit or press forged 12 times, i.e., the three orthogonal axes of the
• the cycle including steps (a)-(optional b), (c)-(optional d), and (e)-(optional f) is performed 4 times.
• the total strain may be equal to, for example, at least 1.0, or may be in the range of at least 1.0 up to less than 3.5.
• the workpiece is cooled 216 to ambient temperature.
• cooling 216 comprises air cooling or cooling at a rate faster than achieved through air cooling, but other forms of cooling, such as, but not limited to, fluid or liquid quenching are within the scope of embodiments disclosed herein.
• a non-limiting aspect of the present disclosure includes high strain rate multi-axis forging at two temperatures in the alpha+beta phase field.
• FIG. 7 is a temperature-time thermomechanical process chart for a non-limiting method according to the present disclosure that comprises multi-axis forging the titanium alloy workpiece at a first workpiece forging temperature; optionally utilizing a non-limiting embodiment of the thermal management feature disclosed hereinabove; cooling to a second workpiece forging temperature in the alpha+beta phase; multi-axis forging the titanium alloy workpiece at the second workpiece forging temperature; and optionally utilizing a non- limiting embodiment of the thermal management feature disclosed herein. [0118] In FIG.
• a non-limiting method 230 comprises heating 232 the workpiece to a beta annealing temperature 234 above the beta transus temperature 236 of the alloy and holding or soaking 238 the workpiece at the beta annealing temperature 234 to form an all beta phase microstructure in the titanium alloy workpiece.
• the workpiece may be plastically deformed 240.
• plastic deformation 240 comprises upset forging.
• plastic deformation 240 comprises upset forging to a strain of 0.3.
• plastically deforming 240 the workpiece comprises high strain multi-axis forging (not shown in FIG. 7) at a beta annealing temperature.
• the workpiece is cooled 242 to a first workpiece forging temperature 244 in the alpha+beta phase field of the titanium alloy.
• cooling 242 comprises one of air cooling and liquid quenching.
• the workpiece is high strain rate multi-axis forged 246 at the first workpiece forging temperature, and optionally a thermal management system according to non-limiting embodiments disclosed herein is employed.
• the workpiece is hit or press forged at the first workpiece forging temperature 12 times with 90° rotation between each hit, i.e., the three orthogonal axes of the workpiece are press forged 4 times each.
• the cycle including steps (a)-(optional b), (c)-(optional d), and (e)-(optional f) is performed 4 times.
• the titanium alloy workpiece is cooled 248 to a second workpiece forging temperature 250 in the alpha+beta phase field.
• the workpiece is high strain rate multi-axis forged 250 at the second workpiece forging temperature, and optionally a thermal management system according to non- limiting embodiments disclosed herein is employed.
• the workpiece is hit or press forged at the second workpiece forging temperature a total of 12 times.
• the number of hits applied to the titanium alloy workpiece at the first and second workpiece forging temperatures can vary depending upon the desired true strain and desired final grain size, and that the number of hits that is appropriate can be determined without undue experimentation upon considering the present disclosure.
• the workpiece is cooled 252 to ambient temperature.
• cooling 252 comprises one of air cooling and liquid quenching to ambient temperature.
• the first workpiece forging temperature is in a first workpiece forging temperature range of more than 100°F (55.6°C) below the beta transus temperature of the titanium alloy to 500°F (277.8°C) below the beta transus temperature of the titanium alloy, i.e., the first workpiece forging temperature Ti is in the range of ⁇ ⁇ - 100°F > ⁇ > ⁇ ⁇ - 500°F.
• the second workpiece forging temperature is in a second workpiece forging temperature range of more than 200°F (277.8°C) below the beta transus temperature of the titanium alloy to 700°F (388.9°C) below the beta transus temperature, i.e., the second workpiece forging temperature T 2 is in the range of Tp - 200°F > T 2 ⁇ ⁇ ⁇ - 700°F.
• the titanium alloy workpiece comprises Ti-6-2-4-2 alloy; the first workpiece temperature is 1650°F (898.9°C); and the second workpiece forging temperature is 1500°F (8 5.6°C).
• FIG. 8 is a temperature-time thermomechanical process chart of a non- limiting method embodiment according to the present disclosure for plastically deforming a workpiece comprising a titanium alloy above the beta transus temperature and cooling the workpiece to the workpiece forging temperature, while simultaneously employing thermally managed high strain rate multi-axis forging on the workpiece according to non-limiting embodiments herein.
• FIG. 8 is a temperature-time thermomechanical process chart of a non- limiting method embodiment according to the present disclosure for plastically deforming a workpiece comprising a titanium alloy above the beta transus temperature and cooling the workpiece to the workpiece forging temperature, while simultaneously employing thermally managed high strain rate multi-axis forging on the workpiece according to non-limiting embodiments herein.
• a non-limiting method 260 of using thermally managed high strain rate multi-axis forging for grain refining of a titanium alloy comprises heating 262 the workpiece to a beta annealing temperature 264 above the beta transus temperature 266 of the titanium alloy and holding or soaking 268 the workpiece at the beta annealing temperature 264 to form an all beta phase microstructure in the workpiece. After soaking 268 the workpiece at the beta annealing temperature, the workpiece is plastically deformed 270.
• plastic deformation 270 may comprise thermally managed high strain rate multi-axis forging.
• the workpiece is repetitively high strain rate multi-axis forged 272 using the optional thermal management system as disclosed herein as the workpiece cools through the beta transus temperature.
• FIG. 8 shows three intermediate high strain rate multi-axis forging 272 steps, but it will be understood that there can be more or fewer intermediate high strain rate multi-axis forging 272 steps, as desired.
• the intermediate high strain rate multi-axis forging 272 steps are intermediate to the initial high strain rate multi-axis forging step 270 at the soaking temperature and the final high strain rate multi-axis forging step in the alpha+beta phase field 274 of the titanium alloy. While FIG. 8 shows one final high strain rate multi-axis forging step wherein the temperature of the workpiece remains entirely in the
• At least one final high strain rate multi-axis forging step takes place entirely at temperatures in the alpha+beta phase field of the titanium alloy workpiece.
• the thermal management system (33 of FIG. 3) is used in through beta transus multi-axis forging to maintain the temperature of the workpiece at a uniform or substantially uniform temperature prior to each hit at each through beta transus forging temperature and, optionally, to slow the cooling rate.
• the workpiece forging temperature in the alpha+beta phase field the workpiece is cooled 276 to ambient temperature.
• cooling 276 comprises air cooling.
• Non-limiting embodiments of multi-axis forging using a thermal management system can be used to process titanium alloy workpieces having cross sections greater than 4 square inches using conventional forging press equipment, and the size of cube-shaped workpieces can be scaled to match the capabilities of an individual press. It has been determined that alpha lamellae or laths from the ⁇ -annealed structure break down easily to fine uniform alpha grains at workpiece forging temperatures disclosed in non-limiting embodiments herein. It has also been determined that decreasing the workpiece forging temperature decreases the alpha particle size (grain size).
• grain refinement that occurs in non-limiting embodiments of thermally managed, high strain rate multi-axis forging according to the present disclosure occurs via meta- dynamic recrystallization.
• dynamic recrystallization occurs instantaneously during the application of strain to the material.
• meta-dynamic recrystallization occurs at the end of each deformation or forging hit, while at least the internal region of the workpiece is hot from adiabatic heating. Residual adiabatic heat, internal region cooling times, and external surface region heating influence the extent of grain refinement in non-limiting methods of thermally managed, high strain rate multi-axis forging according to the present disclosure.
• the present inventors have further developed alternate methods according to the present disclosure providing certain advantages relative to a process as described above including multi-axis forging and using a thermal management system and a cube-shaped workpiece comprising a titanium alloy. It is believed that one or more of (1 ) the cubical workpiece geometry used in certain embodiments of thermally managed multi-axis forging disclosed herein, (2) die chill (i.e., allowing the temperature of the dies to dip significantly below the workpiece forging temperature), and (3) use of high strain rates may disadvantageously concentrate strain within a core region of the workpiece.
• the alternate methods according to the present disclosure can achieve generally uniform fine grain, very fine grain, or ultrafine grain size throughout a billet size titanium alloy workpiece.
• a workpiece processed by such alternate methods may include the desired grain size, such as an ultrafine grain microstructure, throughout the workpiece, and not only in a central region of the workpiece.
• Non- limiting embodiments of such alternate methods comprise "multiple upset and draw” steps performed on billets having cross-sections greater than 4 square inches.
• the multiple upset and draw steps are intended to impart uniform fine grain, very fine grain, or ultrafine grain microstructure throughout the workpiece, while preserving substantially the original dimensions of the workpiece. Because these alternate methods include Multiple Upset and Draw steps, they are referred to herein as embodiments of the "MUD" method.
• the MUD method includes severe plastic deformation and can produce uniform ultrafine grains in billet-size (e.g., 30 inch (76.2 cm) in length) titanium alloy workpieces.
• strain rates used for the upset forging and draw forging steps are in the range of 0.001 s " to 0.02 s ⁇ 1 .
• strain rates typically used for conventional open die upset and draw forging are in the range of 0.03 s "1 to 0.1 s ⁇ 1 .
• the strain rate for MUD is slow enough to prevent adiabatic heating in the workpiece in order to keep the forging temperature in control, yet the strain rate is acceptable for commercial practices.
• a non-limiting method 300 for refining grains in a workpiece comprising a titanium alloy using multiple upset and draw forging steps comprises heating an elongate titanium alloy workpiece 302 to a workpiece forging temperature in the alpha+beta phase field of the titanium alloy.
• the shape of the elongate workpiece is a cylinder or a cylinder-like shape.
• the shape of the workpiece is an octagonal cylinder or a right octagon.
• the elongate workpiece has a starting cross-sectional dimension.
• the starting cross-sectional dimension is the diameter of the cylinder.
• the starting cross-sectional dimension is the diameter of the circumscribed circle of the octagonal cross-section, i.e., the diameter of the circle that passes through all the vertices of the octagonal cross-section.
• the workpiece is upset forged 304. After upset forging 304, in a non-limiting
• the workpiece is rotated 90 degrees to the orientation 306 and then is subjected to multiple pass draw forging 312. Actual rotation of the workpiece is optional, and the objective of the step is to dispose the workpiece into the correct orientation (refer to FIG. 9) relative to a forging device for subsequent multiple pass draw forging 312 steps.
• Multiple pass draw forging comprises incrementally rotating (depicted by arrow 310) the workpiece in a rotational direction (indicated by the direction of arrow 310), followed by draw forging 312 the workpiece after each increment of rotation.
• incrementally rotating 310 and draw forging 312 is repeated until the workpiece comprises the starting cross-sectional dimension.
• the upset forging and multiple pass draw forging steps are repeated until a total strain of at least 1.0 is achieved in the workpiece.
• the embodiment comprises repeating the heating, upset forging, and multiple pass draw forging steps until a total strain in the range of at least 1.0 up to less than 3.5 is achieved in the workpiece.
• the heating, upset forging, and multiple pass draw forging steps are repeated until a total strain of at least 10 is achieved in the workpiece. It is anticipated that when a total strain of 10 is imparted to the MUD forging, an ultrafine grain alpha microstructure is produced, and that increasing the total strain imparted to the workpiece results in smaller average grain sizes.
• An aspect of the present disclosure is to employ a strain rate during the upset and multiple pass drawing steps that is sufficient to result in severe plastic deformation of the titanium alloy workpiece, which, in non-limiting embodiments, further results in ultrafine grain size.
• a strain rate used in upset forging is in the range of 0.001 s " to 0.003 s '
• a strain rate used in the multiple pass draw forging steps is the range of 0.01 s "1 to 0.02 s ' It was disclosed in the '538 Application that strain rates in these ranges do not result in adiabatic heating of the workpiece, which enables workpiece temperature control, and were found sufficient for an economically acceptable commercial practice.
• the workpiece after completion of the MUD method, has substantially the original dimensions of the starting elongate article, such as, for example, cylinder 314 or octagonal cylinder 316.
• the workpiece after completion of the MUD method, has substantially the same cross-section as the starting workpiece.
• a single upset requires numerous draw hits and intermediate rotations to return the workpiece to a shape including the starting cross-section of the workpiece.
• incrementally rotating and draw forging further comprises multiple steps of rotating the cylindrical workpiece in 15° increments and subsequently draw forging, until the cylindrical workpiece is rotated through 360° and is draw forged at each increment.
• twenty-four draw forging steps with intermediate incremental rotation between successive draw forging steps are employed to bring the workpiece to substantially its starting cross-sectional dimension.
• incrementally rotating and draw forging further comprises multiple steps of rotating the cylindrical workpiece in 45° increments and subsequently draw forging, until the cylindrical workpiece is rotated through 360° and is draw forged at each increment.
• MUD method wherein the workpiece is in the shape of an octagonal cylinder
• eight forging steps separated by incremental rotation of the workpiece are employed to bring the workpiece substantially to its starting cross-sectional dimension. It was observed in non-limiting embodiments of the MUD method that manipulation of an octagonal cylinder by handling equipment was more precise than manipulation of a cylinder by handling equipment.
• a workpiece forging temperature comprises a temperature within a workpiece forging temperature range.
• the workpiece forging temperature is in a workpiece forging temperature range of 100°F (55.6°C) below the beta transus temperature (T p ) of the titanium alloy to 700°F (388.9°C) below the beta transus temperature of the titanium alloy.
• T p beta transus temperature
• the workpiece forging temperature is in a temperature range of 300°F (166.7°C) below the beta transus temperature of the titanium alloy to 625°F (347°C) below the beta transus temperature of the titanium alloy.
• the low end of a workpiece forging temperature range is a temperature in the
• alpha+beta phase field at which substantial damage does not occur to the surface of the workpiece during the forging hit as may be determined without undue experimentation by a person having ordinary skill in the art.
• the workpiece forging temperature range for a Ti-6-2-4-2 alloy which has a beta transus temperature (T p ) of about 1820°F (993.3°C)
• T p beta transus temperature
• the workpiece forging temperature range for a Ti-6-2-4-2 alloy which has a beta transus temperature (T p ) of about 1820°F (993.3°C)
• Non-limiting embodiments of the MUD method comprise multiple reheating steps.
• the titanium alloy workpiece is heated to the workpiece forging temperature after upset forging the titanium alloy workpiece.
• the titanium alloy workpiece is heated to the workpiece forging temperature prior to a draw forging step of the multiple pass draw forging.
• the workpiece is heated as needed to bring the actual workpiece temperature back to or near the workpiece forging
• embodiments of the MUD method impart redundant work or extreme deformation, also referred to as severe plastic deformation, which is aimed at creating ultrafine grains in a workpiece comprising a titanium alloy.
• severe plastic deformation also referred to as severe plastic deformation
• the round or octagonal cross sectional shape of cylindrical and octagonal cylindrical workpieces respectively, distribute strain more evenly than workpieces of square or rectangular cross sectional shape across the cross-sectional area of the workpiece during a MUD method.
• the deleterious effect of friction between the workpiece and the forging die is also reduced by reducing the area of the workpiece in contact with the die.
• the temperature of the workpiece may be cooled 416 to a second workpiece forging temperature.
• the workpiece is upset forged at the second workpiece forging
• the workpiece is rotated 420 or otherwise oriented relative to the forging press for subsequent draw forging steps.
• the workpiece is multiple-step draw forged at the second workpiece forging temperature 422.
• Multiple-step draw forging at the second workpiece forging temperature 422 comprises incrementally rotating 424 the workpiece in a rotational direction (refer to FIG. 9) and draw forging at the second workpiece forging temperature 426 after each increment of rotation.
• the steps of upset, incrementally rotating 424, and draw forging are repeated 426 until the workpiece comprises the starting cross-sectional dimension.
• the steps of upset forging at the second workpiece temperature 418, rotating 420, and multiple step draw forging 422 are repeated until a total strain of at least 1.0, or in the range of 1.0 up to less than 3.5, or up to 10 or greater is achieved in the workpiece. It is recognized that the MUD method can be continued until any desired total strain is imparted to the titanium alloy workpiece.
• the workpiece forging temperature or a first workpiece forging temperature
• the second workpiece forging temperature is about 1500°F (815.6°C).
• Subsequent workpiece forging temperatures that are lower than the first and second workpiece forging temperatures such as a third workpiece forging temperature, a fourth workpiece forging temperature, and so forth, are within the scope of non-limiting embodiments of the present disclosure.
• a total strain of at least 1.0, in a range of at least 1.0 up to less than 3.5, or up to 10 results in a uniform equiaxed alpha ultrafine grain microstructure in titanium alloy workpieces, and that the lower temperature of a two- temperature (or multi-temperature) MUD method can be determinative of the final grain size after a total strain of up to 10 is imparted to the MUD forging.
• An aspect of the present disclosure includes the possibility that after processing a workpiece by the MUD method, subsequent deformation steps are performed without coarsening the refined grain size, as long as the temperature of the workpiece is not subsequently heated above the beta transus temperature of the titanium alloy.
• a subsequent deformation practice after the MUD method may include draw forging, multiple draw forging, upset forging, or any combination of two or more of these forging techniques at temperatures in the alpha+beta phase field of the titanium alloy.
• subsequent deformation or forging steps include a combination of multiple pass draw forging, upset forging, and draw forging to reduce the starting cross-sectional dimension of the cylinder-like or other elongate workpiece to a fraction of the cross-sectional dimension, such as, for example, but not limited to, one-half of the cross-sectional dimension, one-quarter of the cross-sectional dimension, and so forth, while still maintaining a uniform fine grain, very fine grain, or ultrafine grain structure in the titanium alloy workpiece.
• the workpiece comprises a titanium alloy selected from the group consisting of an alpha+beta titanium alloy and a metastable beta titanium alloy.
• the workpiece comprises an alpha+beta titanium alloy.
• the workpiece comprises a metastable beta titanium alloy.
• the workpiece is a titanium alloy selected from a Ti-6-2-4-2 alloy, a Ti-6- 2-4-6 alloy, ATI 425 ® titanium alloy (Ti-4AI-2.5V), and a Ti-6-6-2 alloy.
• the workpiece Prior to heating the workpiece to the workpiece forging temperature in the alpha+beta phase field according to MUD embodiments of the present disclosure, in a non-limiting embodiment the workpiece may be heated to a beta annealing
• the beta annealing temperature is in a beta annealing temperature range that includes the beta transus temperature of the titanium alloy up to 300°F (111°C) above the beta transus temperature of the titanium alloy.
• the beta annealing time is from 5 minutes to 24 hours.
• the workpiece is a billet that is coated on all or certain surfaces with a lubricating coating that reduces friction between the workpiece and the forging dies.
• the lubricating coating is a solid lubricant such as, but not limited to, one of graphite and a glass lubricant.
• Other lubricating coatings known now or hereafter to a person having ordinary skill in the art are within the scope of the present disclosure.
• the contact area between the workpiece and the forging dies is small relative to the contact area in multi-axis forging of a cube-shaped workpiece. For example, with a 4 inch cube, two of the entire 4 inch by 4 inch faces of the cube is in contact with the die. With a 5 foot long billet, the billet length is larger than a typical 14 inch long die, and the reduced contact area results in reduced die friction and a more uniform titanium alloy workpiece microstructure and macrostructure.
• the workpiece Prior to heating the workpiece comprising a titanium alloy to the workpiece forging temperature in the alpha+beta phase field according to MUD embodiments of the present disclosure, in a non-limiting embodiment the workpiece is plastically deformed at a plastic deformation temperature in the beta phase field of the titanium alloy after being held at a beta annealing time sufficient to form 100% beta phase in the titanium alloy and prior to cooling the alloy to ambient temperature.
• the plastic deformation temperature is equivalent to the beta annealing temperature.
• the plastic deformation temperature is in a plastic deformation temperature range that includes the beta transus temperature of the titanium alloy up to 300°F (111°C) above the beta transus
• plastically deforming the workpiece in the beta phase field of the titanium alloy comprises at least one of drawing, upset forging, and high strain rate multi-axis forging the titanium alloy workpiece.
• plastically deforming the workpiece in the beta phase field of the titanium alloy comprises multiple upset and draw forging according to non-limiting embodiments of the present disclosure, and wherein cooling the workpiece to a temperature at or near the workpiece forging temperature comprises air cooling.
• plastically deforming the workpiece in the beta phase field of the titanium alloy comprises upset forging the workpiece to a 30-35% reduction in height or another dimension, such as length.
• Another aspect of the MUD method of the present disclosure may include heating the forging dies during forging.
• a non-limiting embodiment comprises heating dies of a forge used to forge the workpiece to temperature in a temperature range bounded by the workpiece forging temperature down to 100°F (55.6°C) below the workpiece forging temperature.
• a method for production of ultra-fine grained titanium alloys includes: choosing a titanium alloy having slower alpha precipitation and growth kinetics than Ti-6-4 alloy; beta annealing the alloy to provide a fine and stable alpha lath structure; and high strain rate multi-axis forging the alloy, according to the present disclosure, to a total strain of at least 1.0, or in a range of at least .0 up to less than 3.5.
• the titanium alloy may be chosen from alpha+beta titanium alloys and metastable beta titanium alloys that provide a fine and stable alpha lath structure after beta annealing.
• a non-limiting embodiment of the method comprises heating a workpiece comprising a metal or a metal alloy to a workpiece forging temperature. After heating, the workpiece is forged at the workpiece forging temperature at a strain rate sufficient to adiabatically heat an internal region of the workpiece. After forging, a waiting period is employed before the next forging step.
• the temperature of the adiabatically heated internal region of the metal alloy workpiece is allowed to cool to the workpiece forging temperature, while at least a one surface region of the workpiece is heated to the workpiece forging temperature.
• the steps of forging the workpiece and then allowing the adiabatically heated internal region of the workpiece to equilibrate to the workpiece forging temperature while heating at least one surface region of the metal alloy workpiece to the workpiece forging temperature are repeated until a desired characteristic is obtained.
• forging comprises one or more of press forging, upset forging, draw forging, and roll forging.
• the metal alloy is selected from the group consisting of titanium alloys, zirconium and zirconium alloys, aluminum alloys, ferrous alloys, and superalloys.
• the desired characteristic is one or more of an imparted strain, an average grain size, a shape, and a mechanical property.
• Mechanical properties include, but are not limited to, strength, ductility, fracture toughness, and hardness
• a bar of Ti-6-2-4-2 alloy was processed according to a commercial forging process, identified in the industry by specification number AMS 4976, which is typically used to process Ti-6-2-4-2 alloy.
• AMS 4976 specification number
• those having ordinary skill understand the specifics of the process to achieve the mechanical properties and microstructure set out in that the specification.
• the alloy was metallographically prepared and the microstructure was evaluated microscopically. As shown in the micrograph of the prepared alloy included as FIG. 11(a), the
• microstructure includes alpha grains (the lighter colored regions in the image) that are on the order of 20 pm or larger.
• a 4.0 inch cube-shaped workpiece of Ti-6-2-4-2 alloy was beta annealed at 1950°F (1066°C) for 1 hour and then air cooled to ambient temperature. After cooling, the beta annealed cube-shaped workpiece was heated to a workpiece forging temperature of 1600°F
• the hits were to the following orthogonal axes, in the following sequence: A-B-C-A.
• the hits were to a spacer height of 3.25 inches, and the ram speed was 1 inch per second. There was no strain rate control on the press, but for the 4.0 inch cubes, this ram speed results in a minimum strain rate during pressing of 0.25 s "1 .
• the time between successive orthogonal hits was about 15 seconds.
• the total strain applied to the workpiece was 1.37.
• the microstructure of the Ti- 6-2-4-2 alloy processed in this manner is depicted in the micrograph of FIG. 11(b).
• the majority of alpha particles (lighter colored areas) are on the order of 4 pm or less, which is substantially finer than the alpha grains produced by the commercial forging process discussed above and represented by the micrograph of FIG. 11(a).
• a bar of Ti-6-2-4-6 alloy was processed according to a commercial forging process typically used for T-6-2-4-6 alloy, i.e., according to specification AMS 4981.
• AMS 4981 specification, those having ordinary skill understand the specifics of the process to achieve the mechanical properties and microstructure set out in that the specification.
• the alloy was metallographically prepared and the microstructure was evaluated microscopically. As shown in the micrograph of the prepared alloy shown in FIG. 2(a), the microstructure exhibits alpha grains (the lighter colored regions) that are on the order of 10 pm or larger.
• a 4.0 inch cube-shaped workpiece of Ti-6-2-4-6 alloy was beta annealed at 870°F ( 066°C) for 1 hour and then air cooled. After cooling, the beta annealed cube-shaped workpiece was heated to a workpiece forging temperature of 1500°F (815.6°C) and forged using four hits of high strain rate MAF. The hits were to the following orthogonal axes and followed the following sequence: A-B-C-A. The hits were to a spacer height of 3.25 inches, and the ram speed was 1 inch per second.
• a 4.0 inch cube-shaped workpiece of Ti-6-2-4-6 alloy was beta annealed at 1870°F (1066°C) for 1 hour and then air cooled. After cooling, the beta annealed cube-shaped workpiece was heated to a workpiece forging temperature of 1500°F (815.6°C) and forged using three hits of high strain rate MAF, one each on the A, the B, and the C axes (i.e., the hits were to the following orthogonal axes and in the following sequence: A-B-C). The hits were to a spacer height of 3.25 inches, and the ram speed was 1 inch per second.
• the workpiece was reheated to 1500°F (815.6°C) for 30 minutes.
• the cube was then high strain rate MAF with one hit at each of the A, the B, and the C axes, i.e., an A-B-C sequence.
• the hits were to the same spacer heights and used the same ram speed and time in between hits as in the first sequence of A-B-C hits.
• This embodiment of a high strain rate multi-axis forging process imparted a strain of 3.46.
• the microstructure of the alloy processed in this manner is depicted in the micrograph of FIG.13. It is seen that the majority of alpha particles (lighter colored areas) are on the order of 4 pm or less. It is believed likely that the alpha particles are comprised of individual alpha grains and that each of the alpha grains has a grain size of 4 pm or less and is equiaxed in shape.
• a 4.0 inch cube-shaped workpiece of Ti-6-2-4-2 alloy was beta annealed at 1950°F (1066°C) for 1 hour and then air cooled. After cooling, the beta annealed cube-shaped workpiece was heated to a workpiece forging temperature of 1700°F (926.7°C) and held for 1 hour. Two high strain rate MAF cycles (2 sequences of three A-B-C hits, for a total of 6 hits) were employed at 1700°F (926.7°C). The time between successive hits was about 15 seconds. The forging sequence was: an A hit to a 3 inch stop; a B hit to a 3.5 inch stop; and a C hit to a 4.0 inch stop.
• This forging sequence provides an equal strain to all three orthogonal axes every three-hit MAF sequence.
• the ram speed was 1 inch per second. There was no strain rate control on the press, but for the 4.0 inch cubes, this ram speed results in a minimum strain rate during pressing of 0.25 s "1 . The total strain per cycle is less than forging to a 3.25 inch reduction in each direction, as in previous examples. [0157]
• the workpiece was heated to 1650°F (898.9°C) and subjected to high strength MAF for three additional hits (i.e., one additional A-B-C high strain rate MAF cycle).
• the forging sequence was: an A hit to a 3 inch stop; a B hit to a 3.5 inch stop; and a C hit to a 4.0 inch stop. After forging, the total strain imparted to the workpiece was 2.59.
• the microstructure of the forged workpiece of Example 4 is depicted in the micrograph of FIG. 14. It is seen that the majority of alpha particles (lighter colored regions) are in a networked structure. It is believed likely that the alpha particles are comprised of individual alpha grains and that each of the alpha grains has a grain size of 4 im or less and is equiaxed in shape.
• a 4.0 inch cube-shaped workpiece of Ti-6-2-4-2 alloy was beta annealed at 1950°F ( 066°C) for 1 hour and then air cooled. After cooling, the beta annealed, cube-shaped workpiece was heated to a workpiece forging temperature of 1700°F (926.7°C) and held for 1 hour.
• MAF according to the present disclosure was employed to apply 6 press forgings to a major reduction spacer height (A, B, C, A, B, C) to the cube-shaped workpiece.
• first and second blocking reductions were conducted on the other axes to "square up" the workpiece.
• the overall forging sequence used is as follows, wherein the bold and underlined hits are press forgings to the major reduction spacer height: A-B-C-B-C-A-C- A-B-A-B-C-B-C-A-C.
• the forging sequence including major, first blocking, and second blocking spacer heights (in inches) that were utilized are outlined in the table below.
• the ram speed was 1 inch per second. There was no strain rate control on the press, but for the 4.0 inch cubes, this ram speed results in a minimum strain rate during pressing of 0.25 s "1 .
• the time elapsed between hits was about 15 seconds.
• the total strain after thermally managed MAF according to this non-limiting embodiment was 2.37.
• micro-structure of the workpiece forged by the process described in this Example 5 is depicted in the micrograph of FIG. 15. It is seen that the majority of alpha particles (lighter colored regions) are elongated. It is believed likely that the alpha particles are comprised of individual alpha grains and that each of the alpha grains has a grain size of 4 pm or less and is equiaxed in shape.
• a 4.0 inch cube-shaped workpiece of Ti-6-2-4-2 alloy was beta annealed at 1950°F (1066°C) for 1 hour and then air cooled.
• Thermally managed high strain rate MAF according to embodiments of the present disclosure, was performed on the workpiece, including 6 hits (2 A-B-C MAF cycles) at 1900°C, with 30 second holds between each hit. The ram speed was 1 inch per second.
• MAF according to embodiments of the present disclosure was applied to the workpiece, including 6 hits (two A-B-C MAF cycles) with about 15 seconds between hits.
• the first three hits (the hits in the first A-B-C MAF cycle) were performed with a 3.5 inch spacer height
• the second 3 hits (the hits in the second A- B-C MAF cycle) were performed with a 3.25 inch spacer height.
• the workpiece was heated to 1650°F and held for 30 minutes between the hits with the 3.5 inch spacer and the hits with the 3.25 inch spacer.
• the smaller reduction (i.e., larger spacer height) used for the first 3 hits was designed to inhibit cracking as the smaller reduction breaks up boundary structures that may lead to cracking.
• the workpiece was reheated to 1500°F (815.6°C) for 1 hour.
• MAF according to embodiments of the present disclosure was then applied using 3 A-B-C hits (one MAF cycle) to 3.25 inch reductions with 15 seconds in between each hit. This sequence of heavier reductions is designed to put additional work into the non-boundary structures.
• the ram speed for all hits described in Example 6 was 1 inch per second.
• FIG. 16(a) A representative micrograph from the center of the thermally managed MAF workpiece of Example 6 is shown in FIG. 16(a).
• FIG.16(b) A representative micrograph of the surface of the thermally managed MAF workpiece of Example 6 is presented in FIG.16(b).
• the surface microstructure (FIG. 16(b)) is substantially refined and the majority of the particles and/or grains have a size of about 4 pm or less, which is an ultrafine grain microstructure.
• the center microstructure shown in FIG. 16(a) shows highly refined grains, and it is believed likely that the alpha particles are comprised of individual alpha grains and each of the alpha grains has a grain size of 4 pm or less and is equiaxed in shape.

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