US 20050070990 A1
Medical devices, such as stents, and methods of the devices are described.
1. A balloon-expandable medical stent, comprising:
a generally tubular body including an alloy having Ti at about 20 weight percent or more and at least one of Zr, Ta, or Mo, the alloy having a yield strength of about 45 ksi or more, a magnetic susceptibility of about +1 or less, and a mass absorption coefficient of about 1.9 cm2/g or more.
2. The stent of
3. The stent of
4. The stent of
5. The stent of
6. The stent of
7. The stent of
8. The stent of
9. The stent of
10. The stent of
11. The stent of
12. The stent of
13. The stent of
14. The stent of
15. The stent of
16. The stent of
17. The stent of
18. The stent of
19. The stent of
20. The stent of
21. A system including a catheter for delivery into a body lumen, the catheter including an expandable member and a stent as described in
22. An implantable medical device, comprising:
an alloy having Ti at about 20 weight percent or more and at least one of Zr, Ta, or Mo, the alloy having a yield strength of about 45 ksi or more, a magnetic susceptibility of about +1 or less, and a mass absorption coefficient of about 1.9 cm2/g or more, the medical device selected from a filter, a guidewire, a catheter, a needle, a biopsy needle, a staple, and a cannula.
23. A method of forming a stent, comprising:
providing an alloy including Ti of about 20 weight percent or more and at least one additive selected from the group consisting of Zr, Ta and Mo by:
contacting solid aliquots of a titanium component selected from Ti or a Ti-containing alloy, and the additive,
heating the aliquot after the contacting,
mechanically working the aliquots after contacting by forging, extrusion, drawing or rolling,
melting the aliquots,
forming a first mass,
forming a tube including the alloy, and
incorporating the tube into a stent.
24. The method of
25. The method of
26. The method of
27. The method of any one of claims 24 and 26 wherein the body is formed of the titanium component.
28. The method of
29. The method of
30. The method of
31. The method of
32. The method of
after forming the first mass, contacting the first mass with further additive, melting the first mass in contact with the further aliquot, and forming a second mass having a greater amount of additive.
33. The method of
34. The method of claims 23 comprising:
melting by vacuum arc remelting, electron beam, plasma or vacuum induction melting.
35. The method of
36. The method of
37. The method of
38. The method of
39. The method of
40. A method of forming a medical device, comprising:
providing a metal alloy of multiple components of elements or alloys, including a first component and a second component having a melting point difference of about 150° C. or more by contacting solid aliquots of the first component and the second component,
heating and/or mechanically working the aliquots after contacting to form a first mass,
melting the first mass,
forming a second mass from the first mass, and
incorporating the alloy into a medical device.
The invention relates to medical devices, such as, for example, stents and stent-grafts, and methods of making the devices.
The body includes various passageways such as arteries, other blood vessels, and other body lumens. These passageways sometimes become occluded or weakened. For example, the passageways can be occluded by a tumor, restricted by plaque, or weakened by an aneurysm. When this occurs, the passageway can be reopened or reinforced, or even replaced, with a medical endoprosthesis. An endoprosthesis is typically a tubular member that is placed in a lumen in the body. Examples of endoprostheses include stents and covered stents, sometimes called “stent-grafts”.
An endoprosthesis can be delivered inside the body by a catheter that supports the endoprosthesis in a compacted or reduced-size form as the endoprosthesis is transported to a desired site. Upon reaching the site, the endoprosthesis is expanded, for example, so that it can contact the walls of the lumen.
When the endoprosthesis is advanced through the body, its progress can be monitored, e.g., tracked, so that the endoprosthesis can be delivered properly to a target site. After the endoprosthesis is delivered to the target site, the endoprosthesis can be monitored to determine whether it has been placed properly and/or is functioning properly.
Monitoring of the position of the endoprosthesis during implantation is typically performed by a radiographic technique such as fluoroscopy. The radiographic density of the metal endoprosthesis is different from bone and tissue, and the device is observed in the fluoroscopic image from the visible difference in contrast and grey scale relative to the surrounding biological material. The disadvantage of fluoroscopy is that the physician, staff, and patient are exposed to ionizing radiation which can be harmful in strong or repeated doses.
Another method of monitoring a medical device is magnetic resonance imaging (MRI). MRI uses a magnetic field and radio waves to image the body. In some MRI procedures, the patient is exposed to a magnetic field, which interacts with certain atoms, e.g., hydrogen atoms, in the patient's body. Incident radio waves are then directed at the patient. The incident radio waves interact with atoms in the patient's body, and produce characteristic return radio waves. The return radio waves are detected by a scanner and processed by a computer to generate an image of the body.
In an aspect, the invention features a balloon-expandable medical stent. The stent includes a generally tubular body including an alloy having Ti at about 20 weight percent or more and at least one of Zr, Ta, or Mo. The alloy has a yield strength of about 45 ksi or more, a magnetic susceptibility of about +1 or less, and a mass absorption coefficient of about 1.9 cm2/g or more.
In another aspect, the invention features a system including a catheter for delivery into a body lumen. The catheter includes an expandable member and a stent as described herein disposable over the expandable member. The expandable member is expandable to a maximum diameter of about 1.55 mm to about 14 mm.
In another aspect, the invention features an implantable medical device including an alloy having Ti at about 20 weight percent or more and at least one of Zr, Ta, or Mo, a yield strength of about 45 ksi or more, a magnetic susceptibility of about +1 or less, and a mass absorption coefficient of about 1.9 cm2/g or more. The medical device can be a filter, a guidewire, a catheter, a needle, a biopsy needle, a staple, or a cannula.
In another aspect, the invention features a method of forming a stent. The method includes providing an alloy including Ti of about 20 weight percent or more and at least one of an additive selected from Zr, Ta or Mo. The method includes contacting solid aliquots of a titanium component selected from Ti or a Ti-containing alloy, and the additive heating the aliquot after the contacting, and mechanically working the aliquots after contacting by forging, extrusion, drawing or rolling, melting the aliquots, forming an ingot, forming a tube including the alloy, and incorporating the tube into a stent.
In an aspect, the invention features a method of forming a medical device. The method includes providing a metal alloy of multiple components of elements or alloys, including a first component and a second component having a melting point difference of about 150° C. or more. Solid aliquots of the first component and the second component are contacted, heated and/or mechanically worked, then the worked components are melted. The alloy is incorporated into a medical device.
In another aspect, the invention features a medical device including an alloy that exhibits one or more (e.g., two, three, or four) properties selected from radiopacity, MRI capability, mechanical properties, and/or biocompatibility properties as described herein, in any combination. In other aspects, the invention features particular alloys and techniques for making the alloys.
In yet another aspect, the invention features a medical device including a titanium alloy having at least one of zirconium, tantalum, molybdenum, or niobium. The alloy exhibits radiopacity, MRI capability, mechanical properties, and/or biocompatibility properties, and combinations of the properties as described herein. In other aspects, the invention features particular alloys and techniques for making the alloys.
Embodiments may include one or more of the following advantages. A stent or other medical device is provided that includes desirable magnetic imaging radiopacity, biocompatibility and/or mechanical characteristics. For example, the stent is less susceptible to magnetic resonance image degradation (e.g., less than stainless steel) Implant movement or heating can be reduced. The stent alloy has sufficient radiopacity that the stent is visible by fluoroscopy. The mechanical characteristics of the alloy enable a stent of conventional design that can be delivered into the body in a reduced diameter configuration and then expanded at a treatment site, e.g., by a balloon catheter. The titanium alloys generally can exhibit enhanced strength, stiffness and radiopacity, while maintaining low magnetic susceptibility.
Still further aspects, features, and advantages follow.
Referring now to
The stent body is formed of a metal alloy that has desirable magnetic resonance, radiopacity, biocompatibility, and/or mechanical characteristics. In embodiments, the alloy is a titanium-containing alloy that includes one or more of Zr, Ta or Mo. In particular embodiments, the alloy is formed from commercially pure (CP) titanium or Ti-6A1-4V ELI, which has been alloyed with one or more of Zr, Ta, or Mo by processes that include mechanical or diffusion alloying followed by melting, as will be described below.
The alloy is formulated to provide desired characteristics. For MRI compatibility, the alloy is formulated to reduce signal distortion, electrical current (e.g., eddy current) generation, heating, movement within the body or nerve simulation, by controlling the magnetic susceptibility and solubility of the alloy constituents. The magnetic susceptibilities of Ti, Zr, Ta, and Mo and other materials are provided in Table I.
In embodiments, the magnetic susceptibility of the alloy is less than the magnetic susceptibility of austenitic stainless steel, e.g. about +1 or less or about 3.5×10−3 or less. Solubility of the constituents can be determined by binary phase diagrams. Suitable solubility is indicated by a single phase (alpha or beta) or by a two phase solution (alpha and beta) at room temperature. Examples of suitable phase diagrams are available in the ASM Handbook, volume 3, ASM International, 1992, the entire contents of which is hereby incorporated by reference.
For radiopacity, the alloy is formulated to a desired mass absorption coefficient. Preferably, the stent is readily visible by fluoroscopy, but does not appear so bright that detail in the fluoroscopic image is distorted. In some embodiments, the alloy or the device has a radiopacity of from about 1.10 to about 3.50 times (e.g., greater than or equal to about 1.1, 1.5, 2.0, 2.5, or 3.0 times; and/or less than or equal to about 3.5, 3.0, 2.5, 2.0, or 1.5 times) that of 316L grade stainless steel, as measured by ASTM F640 (Standard Test Methods for Radiopacity of Plastics for Medical Use). Mass absorption coefficients and densities or Ti, Ta, Zr and Mo are compared to 316L stainless steel in Table II.
In embodiments, the mass absorption coefficient of the alloy is about 1.96 cm2/g (corresponding substantially to the mass absorption coefficient of Fe) to about 2.61 cm2/g (corresponding to about 0.5 the mass absorption coefficient of Ta). Mass absorption coefficient can be calculated from the results of radiopacity tests, as described in The Physics of Radiology, H. E. Johns, J. R. Cunningham, Charles C. Thomas Publisher, 1983, Springfield, Ill., pp. 133-143. A calculation of alloy mass absorption coefficient is provided in the examples, infra.
For desirable mechanical properties, the alloy is formulated based on solubility and phase structure. In particular embodiments, the alloy exhibits certain mechanical properties within about ±20% (e.g., within about ±10%, about ±5%, or about ±1%) of the corresponding value for stainless steel. Mechanical properties for select materials are provided in Table III.
Yield strength (YS) relates to the applied pressure needed to flow the alloy to expand the stent. The percent strain to peak load indicates how far the material can strain before necking occurs. The ultimate tensile strength (UTS) is the stress value that corresponds with strain to peak load. The percent strain to fracture is a measure of how far the material can be stretched prior to break, and includes uniform deformation plus location deformation in the necked down region. This property relates to stent strut fracture from over-expansion of the stent. Suitable test methods for determining these parameters are described in ASTM E8 (Standard Test Methods for Tension Testing of Metallic Materials). In Table III, the 316L SS properties were measured from annealed stent tubing. The other material properties were taken from handbooks, such as American Society for Metals Handbook Desk Edition, H. E. Boyer, T. L. Gall, 1985.
The solubility of the constituents and phase structure of the alloy is indicated by phase diagrams. Suitable solubilities are indicated by alpha and/or beta microstructures without substantial amounts of more brittle phases such as alpha prime, alpha double prime or omega phases. Active rapid cooling after melting can be utilized to reduce precipitation of these phases. In embodiments, the presence of brittle phases is less than about 10% (e.g., less than about 7%, 5%, or 3%) as measured by X-ray diffraction analysis. The presence of two phases is preferably equal to or less than the amount in commercially available Ti-6A1-4V (available from Allegheny Technologies Allvac (Monroe, N.C.) or Metalmen Sales (Long Island City, N.Y.). Alloying Ti with Ta and Mo increases modulus of elasticity. Alloying Ti with Ta, Mo, and/or Zr increases tensile strength. In embodiments, tensile properties are balanced by annealing the alloy. For example, annealing time and temperature can be selected to produce a maximum level of ductility while meeting minimum design requirements for yield strength and grain size. Alternatively or in addition, the stent design can be modified to accommodate less favorable mechanical properties. For example, for a lower tensile elongation (% strain to fracture) the stent is designed to lower the strain on the struts during expansion, such as by increasing the number of deformation “hinge” points in the stent so that the total stent deformation is distributed in smaller amounts to the areas where deformation occurs.
Biocompatibility of the stent is provided by alloying biocompatible constituents or coating the sent with a biocompatible material. Biocompatibility can be tested by using industry standard ISO 10992 in-vitro and in vivo test methods, which can provide a qualitative pass or fail indication. In embodiments, the stent has a biocompatibility similar to or equivalent to pure titanium or pure tantalum, as measured by ISO 10992 test methods.
In embodiments, the alloy constituents are provided in combinations and amounts recited in the Summary and Examples. In particular embodiments, the alloy is Ti-Ta, Ti-Mo, Ti-Zr, Ti-Ta-Mo, Ti-Ta-Zr, Ti-Ta-Zr-Mo, Ti-Zr-Mo or Ti 6A1-4V-Ta, Ti 6A1-4V-Mo, Ti 6A1-4V-Zr, Ti 6A1-4V-Ta-Mo, Ti 6A1-4V-Ta-Zr, Ti 6A1-4V-Ta-Zr-Mo, or Ti 6A1-4V-Zr-Mo alloy. In other embodiments, Ti-13Nb-13Zr, Ti-8A1-1Mo-1V, Ti-6A1-2Nb-1 Ta-0.8Mo and Ti-7A1-4Mo one alloyed with Ta, Mo, and/or Zr. In particular embodiments, the alloy is annealed. In particular embodiments, the alloy is formed by alloying CP titanium or Ti-6A1-4V ELI with Ta, Zr and/or Mo. In embodiments, the alloy includes 40 to 70 weight percent tantalum or 25 to 50 weight percent zirconium with CP titanium or Ti-6A1-4V ELI. In embodiments, 5 to 20 weight percent molybdenum is added in place of some of the titanium for added tensile strength without sacrificing MRI compatibility. Suitable alloys include the following:
The alloying process is particularly advantageous for alloying constituents with large melting temperature differences. In Table IV, the melting temperatures of Ti, Ta, Zr, and Mo are provided.
The melting temperature difference between Ti and Zr, and Ta and Mo is over 500° C. The difference between Ti and Zr is over 150° C. In the method of
In the prealloying step, heating is performed in an inert gas or vacuum, or the outer surfaces of the billet could be coated or canned with a protective metal, such as iron, that could later be chemically dissolved. After drilling and filling or after the diffusion heat treatment, the billet can also be extruded, drawn, or rolled to further consolidate the assembly. The heat treatment or working serves to hold additive material in place within the billet during melting. Also, constituents with high melting points can be essentially encapsulated within, e.g. titanium, minimizing the exposure to any residual air in the casting furnace. For diffusion heating, the assembly can be heated near the melting temperature of the lowest melting temperature constituent and/or the melting temperature of the material of the base rod. For example, for a Ti base rod, the temperature is about 1600° C. or less.
In embodiments, additives to the base are made in incremental steps in each of multiple melting and ingot casting operations. For example, to alloy Ti 6A1-4V with 43 weight percent tantalum, in the first melting operation the Ti-6A1 -4V bar holes may be filled with 22 weight percent tantalum. After the first ingot is cast, holes are drilled again and filled with another 22 weight percent tantalum and the melting is repeated. Other sequences and magnitudes of Ta adds are made to reach the final alloy with 43 weight percent Ta. This approach is Ta elemental segregation in the ingot if it is added in smaller amounts in multiple melting and ingot casting steps. In addition, homogenization heat treatments between melts can reduce the amount of elemental diffusion needed. Other difficult to melt alloys can be produced by this method such as Ta-Nb, Nb-Zr, Ti-Nb, and Fe-Pt alloy systems. In other embodiments, the additive can be provided in the form of powder or chips rather than a solid wire or rod. The alloying that occurs in the melting and ingot casting process can be further improved by performing a homogenization (elemental diffusion) heat treatment to the ingots between melting operations. Mechanical alloying melting, casting, and heat treating operations can be performed at commercial sources such as Pittsburgh Materials Technology Inc. (Pittsburgh, Pa.), Applegate Group (Woodcliff Lake, N.J.) or Albany Research Center (Albany, Ore.).
The alloy tubing is formed into stent. For example, selected portions can be removed to define bands and struts. The portions can be removed by laser cutting, as described, for example, in U.S. Pat. No. 5,780,807. In certain embodiments, during laser cutting, a liquid carrier, such as a solvent, gas, or an oil, is flowed through the tube. The carrier can prevent drops formed on one portion from re-depositing on another portion, and/or reduce formation of recast material on the tubular member. Other methods of removing portions of tubular member include mechanical machining (e.g., micro-machining), electrical discharge machining (EDM), photoetching (e.g., acid photoetching), and/or chemical etching.
The stent can further be finished, e.g., electropolished to a smooth finish, according to conventional methods. In some embodiments, about 0.0001 inch of material can be removed from the interior and/or exterior surfaces by chemical milling and/or electropolishing. The stent can be annealed to refine the mechanical and physical properties of the stent.
In use, the stent can be used, e.g., delivered and expanded, using a catheter. Suitable catheter systems are described in, for example, Wang U.S. Pat. No. 5,195,969, and Hamlin U.S. Pat. No. 5,270,086. Suitable stents and stent delivery are also exemplified by the Express, Radius® or Symbio® systems, available from Boston Scientific Scimed, Maple Grove, Minn.
The stent can be of any desired shape and size (e.g., coronary stents, aortic stents, peripheral vascular stents, gastrointestinal stents, urology stents, and neurology stents). Depending on the application, the stent can have a diameter of between, for example, 1 mm to 46 mm. In certain embodiments, a coronary stent can have an expanded diameter of from about 2 mm to about 6 mm. In some embodiments, a peripheral stent can have an expanded diameter of from about 5 mm to about 24 mm. In certain embodiments, a gastrointestinal and/or urology stent can have an expanded diameter of from about 6 mm to about 30 mm. In some embodiments, a neurology stent can have an expanded diameter of from about 1 mm to about 12 mm. An abdominal aortic aneurysm (AAA) stent and a thoracic aortic aneurysm (TAA) stent can have a diameter from about 20 mm to about 46 mm. Stent 100 can be balloon-expandable, self-expandable, or a combination of both (e.g., U.S. Pat. No. 5,366,504).
The stent can also be a part of a stent-graft. In other embodiments, the stent includes and/or be attached to a biocompatible, non-porous or semi-porous polymer matrix made of polytetrafluoroethylene (PTFE), expanded PTFE, polyethylene, urethane, or polypropylene. The endoprosthesis can include a releasable therapeutic agent, drug, or a pharmaceutically active compound, such as described in U.S. Pat. No. 5,674,242, U.S. Ser. No. 09/895,415, filed Jul. 2, 2001 and U.S. Ser. No. 10/232,265, filed Aug. 30, 2002. The therapeutic agents, drugs, or pharmaceutically active compounds can include, for example, anti-thrombogenic agents, antioxidants, anti-inflammatory agents, anesthetic agents, anti-coagulants, and antibiotics.
The methods and the embodiments described above can be used to form medical devices other than stents and stent-grafts. For example, the methods and/or materials can be used to form filters, such as removable thrombus filters described in Kim et al., U.S. Pat. No. 6,146,404; in intravascular filters such as those described in Daniel et al., U.S. Pat. No. 6,171,327; and in vena cava filters such as those described in Soon et al., U.S. Pat. No. 6,342,062. The methods and/or materials can be used to form guidewires, such as a Meier steerable guidewire. The methods and/or materials can be used to form vaso-occlusive devices, e.g., coils, used to treat intravascular aneurysms, as described, e.g., in Bashiri et al., U.S. Pat. No. 6,468,266, and Wallace et al., U.S. Pat, No. 6,280,457. The methods and/or materials can be used to form wire to make catheter reinforcement braid. The methods and/or materials can also be used in surgical instruments, such as forceps, needles, clamps, and scalpels.
Further embodiments are provided in the following examples.
A titanium-tantalum alloy with a mass absorption coefficient of at least 1.96 cm2/g (iron) and as high as 2.86 cm2/g (half of tantalum) is formulated as follows. The atomic mass coefficient for titanium is 1.21 and for tantalum is 5.72.
The following equation is used to provide desired radiopacity.
Conversion of atomic percent to weight percent for the 17 Ta-83 Ti alloy is as follows:
An alloy of 83 atomic percent Ti and 17 atomic percent Ta (57 weight percent Ti and 43 weight percent Ta) has a calculated mass absorption coefficient equivalent to iron and a radiopacity similar to 316L stainless steel. An alloy of 63 atomic percent Ti and 37 atomic percent Ta (31 weight percent Ti and 69 weight percent Ta) has a calculated mass absorption coefficient equivalent to one-half of tantalum. The alloy constituents have magnetic susceptibility less than 3.5×10−3 and are soluble in each other. The tantalum-titanium binary phase diagram (ASM Handbook, Volume 3 Alloy Phase Diagrams, ASM International, 1992, p. 2.374) indicates a 43 to 69 weight percent tantalum to be soluble in titanium as a solid solution two-phase (alpha and beta) material at room temperature. The tantalum-titanium binary phase diagram also indicates that the alloys with 43 to 69 percent tantalum concentration have alpha and beta phase microstructures. No brittle phases are evident in the phase diagram.
A titanium-molybdenum alloy with a mass absorption coefficient of at least 1.96 cm2/g (iron) and as high as 2.86 cm2/g (halfoftantalum) is formulated as follows.
The following equation is used to determine desired radiopacity.
Conversion of atomic percent to weight percent for the 13 Mo-87 Ti alloy:
An alloy of 87 atomic percent Ti and 13 atomic percent mo (77 weight percent Ti and 23 weight percent Mo) has a calculated mass absorption coefficient equivalent to iron and a radiopacity similar to 316L stainless steel. An alloy of 72 atomic percent Ti and 28 atomic percent Mo (56 weight percent Ti and 44 weight percent Mo) has a calculated mass absorption coefficient equivalent to one-half of tantalum and therefore has half the radiopacity of tantalum. The alloy constituents have magnetic susceptibility less than 3.5×10−3 and that are soluble in each other. The molybdenum titanium binary phase diagram indicates (ASM Handbook, Volume 3 Alloy Phase Diagrams, ASM International, 1992, p.2.296) 23 to 44 weight percent molybdenum to be soluble in titanium as a solid solution single (beta) or two-phase (alpha and beta) material at room temperature. The molybdenum-titanium binary phase diagram also indicates that alloys with 23 to 44 percent molybdenum concentration will have beta or beta plus alpha phase microstructures which are common in commercialized titanium engineering alloys such as Ti-6A1-4V. Cooling through the temperature range of about 850 to 695° C. can be performed rapidly (e.g., by argon gas, air cool, or liquid quenchant) to avoid precipitation of significant amounts of alpha-prime, alpha-double prime, or omega phases.
A method for making an alloy of Ti-6A1-4V ELI with 43 weight percent Ta follows.
Procure a 3″ diameter round bar of Ti-6A1-4V ELI (such as form Titanium Industries, Inc. in Morristown, N.J.) and cut to 5.5 inches long. Procure 0.5″ diameter tantalum rod (such as from Rembar, Dobbs Ferry, N.Y.) and cut into lengths of 3.25″. Drill eight holes into the titanium bar that are 0.55/0.6″ diameter and 4.5″ deep. Put the eight 3.25″ long pieces of 0.5″ diameter tantalum rod into the holes. Heat the assembly in a vacuum furnace at 1400° C. for 8 hours and vacuum cool. Gas tungsten arc weld (GTAW or TIG) the assembly with the hole-end up to the vacuum arc remelt (VAR) electrode holder. Vacuum arc remelt the assembly and cast an ingot. Heat the ingot in a vacuum furnace at 1400° C. for 8 hours and vacuum cool. Repeat the VAR and heat treatment once ore or multiple times. Machine the ingot into a 2.5″ diameter×4″ long billet. Convert billet to annealed seamless tent tubing.
Arc melted Ti-Ta alloy button ingots were prepared. Two ingots were melted from a 50-50 mixture (by weight) of Ti-6A1-4V and tantalum rods. One ingot was melted from a 50-50 mixture (by weight) of pure titanium and tantalum rods. Cold rolling and annealing of the ingots were used to form strips for mechanical and physical property testing.
The ingots were prepared from the following rods and charge materials procured from Goodfellow Corporation, Berwyn, Pa.
The rods were cut into lengths of 1-2″, cleaned in acetone, and weighed on a digital scale. The rods were divided up by weight into two groups for melting. The raw materials were melted in an arc melter (Model MRF ABJ-900, Materials Research Furnaces, Inc., Suncook, N.H.). The arc melter was operated at 350-400 amps. Three melt cycles were performed for each alloy.
Three 0.20-0.25″ thick bars were used as a starting stock for cold rolling. The machined dimensions of the rolling blanks are listed in the following table.
The machined bars were cold rolled to a total reduction in thickness of 50%. The dimensions after cold rolling are listed in the following table.
The cold rolled strips were annealed in the a vacuum heat treat furnace at 1200° C. for 60 minutes in vacuum followed by a vacuum cool. The purpose of this heat treatment was to continue to homogenize the alloy, recrystallize the cold worked microstructure, and soften the material to allow for further cold rolling. Referring to
The three strips were cold rolled to a total reduction in thickness of −50%. The dimensions of the rolled strips are listed in Table IX.
The cold rolled strips were annealed in the vacuum heat treat furnace at 1000° C. for 30 minutes in vacuum followed by a vacuum cool. The purpose of this heat treatment was to recrystallize the cold worked microstructure and soften the material to allow further cold rolling. The strips were cold rolled to 0.025″ thickness. The dimensions are given in Table X.
The strips were beta solution treated in a vacuum heat treat furnace at 850° C. for 30 minutes and cooled in vacuum. The strips were submitted for metallography. The strips were subjected to tensile specimen machining and testing (Metcut Research Associates, Inc. (Cincinnati, Ohio)). The tensile results were 85-115 ksi UTS, 65-105 YS, and 5-25% elongation.
Ti-6A1-4V, pure titanium, and tantalum materials had been melted in powder metal form. Sometimes the ingots did not have sufficient formability to allow cold rolling to a final reduction in thickness of 50%. The large surface area of fine powder metal may allow for significant contamination to be carried into the ingot thereby reducing the ductility of the alloy. In this experiment, solid rods were used instead of powder metal for the furnace charges. The smaller surface area of the rods (relative to the powder) should result in better ingot ductility.
All publications, applications, references, patents referred to in this application are herein incorporated by reference in their entirety.
Other embodiments are within the claims.