Superplastic forming of titanium assemblies
A method of superplastic forming of titanium packs and an associated assembly is provided. The titanium packs can include sheets having different granular structures so that the different sheets are adapted to superplastically form at different temperatures. One or more of the sheets can be formed at a temperature that is below the superplastic forming temperature of another sheet in the pack. In some cases, the occurrence of markoff can be reduced or eliminated.
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1) Field of the Invention
The present invention relates to the forming and bonding of structural members and, more particularly, relates to the use of different grain titanium for superplastic forming and/or diffusion bonding.
2) Description of Related Art
Superplastic forming (SPF) generally refers to a process in which a material is superplastically deformed beyond its normal limits of plastic deformation. Superplastic forming can be performed with certain materials that exhibit superplastic properties within limited ranges of temperature and strain rate. For example, workpieces formed of titanium alloys are typically superplastically formed in a temperature range between about 1450° F. and 1850° F. at a strain rate up to about 3×10−4 per second.
Diffusion bonding (DB) generally refers to a process of joining members using heat and pressure to form a solid-state coalescence between the materials of the joined members. Joining by diffusion bonding occurs at a temperature below the melting point of the materials that are being joined, and the coalescence therebetween is produced with loads below those that would cause macroscopic deformation of the article.
According to one conventional process, superplastic forming is performed by providing one or more superplastically formable metal sheets in a die cavity defined between cooperable dies, heating the sheets to an elevated temperature at which the sheets exhibit superplasticity, and then using a gas to apply differential pressures to the opposite sides of the sheets in order to form the sheets. The pressure is selected to strain the material at a strain rate that is within its superplasticity range at the elevated temperature, stretch the sheet, and cause it to assume the shape of the die surface. In this way, the sheet can be formed to a complex shape defined by the dies.
Further, in some cases, superplastic forming and diffusion bonding are performed in a combined forming/bonding operation. For example, in one typical combined SPF/DB process, three metal sheets are stacked to form a pack. A stop-off material is selectively provided between the sheets to prevent portions of the adjacent surfaces of the sheets from being bonded. The pack is heated and compressed in a die cavity with sufficient gas pressure so that the adjacent portions of the sheets that are not treated with the stop-off material are joined by diffusion bonding. Thereafter, a pressurized gas is injected between the sheets to inflate the pack, and thereby superplastically form the pack to a configuration defined by the surface of the die cavity. This process is described further in U.S. Pat. No. 3,927,817 to Hamilton, et al. Such a combined SPF/DB process can be used, e.g., to produce complex honeycomb sandwich structures that are formed and diffusion bonded to define hollow internal cells. Generally, the simplicity of the superplastic forming and/or diffusion bonding processes can result in lighter and less expensive structures with fewer fasteners and higher potential geometric complexity. Applications of SPF and/or DB include the manufacturing of parts for aircraft, other aerospace structures, non-aerospace vehicles and structures, and the like.
The individual sheets of a pack for forming according to the foregoing conventional process are typically provided as a flat sheets in a stacked relationship.
Such markoff of the outer sheets of a pack during superplastic forming can be reduced by providing a middle sheet that is significantly thinner than the outer sheets, thereby increasing the relative stiffness of the outer sheets and reducing the inward force on the outer sheets during forming. The ratio of the thickness of the middle sheet to the thickness of each outer sheet is typically no more than about 25%. Therefore, if the design requirements for a particular application require a thicker middle sheet, superplastic forming is not typically used. The production of two-sheet assemblies and assemblies having other numbers of sheets can similarly be limited by a desire to avoid markoff.
While the conventional methods for SPF/DB processing have proven effective for manufacturing a variety of structural assemblies, including assemblies formed of titanium, there exists a continued need for improved SPF/DB methods and assemblies. In particular, the method should allow the production of assemblies with a greater range of desired dimensions, including assemblies with sheets of particular dimensions.
BRIEF SUMMARY OF THE INVENTIONEmbodiments of the present invention provide a method of superplastically forming titanium sheets and an assembly that is formed by such a method. Titanium sheets having different granular structures are used in the method so that the different sheets are adapted to superplastically form at different temperatures. In some cases, the sheets can be formed without markoff (or without substantial markoff) occurring, even though one or more of the sheets of substantial thickness is subjected to significant forming.
According to one embodiment of the present invention, a structural assembly having a predetermined configuration is produced by superplastically forming a pack having first and second titanium sheets in a stacked configuration. The first sheet has a grain size that is at least about twice a grain size of the second sheet. For example, the first sheet can define a grain size that is greater than about 5 micron and in some cases greater than 8 micron, and the second sheet can define a grain size less than about 2 micron such as between about 0.8 and 1.2 micron. The pack is heated to at least a superplastic forming temperature of the second sheet, and the second sheet is superplastically formed to a predetermined configuration to thereby form the assembly. The second sheet can be superplastically formed at a temperature that is less than the superplastic forming temperature of the first sheet, e.g., at a temperature between about 1400° F. and 1450° F. In some cases, the second sheet is formed without superplastically forming the first sheet, e.g., with the first sheet being only nonsuperplastically formed. The second sheet can be at least 75% as thick as the first sheet. The sheets can be diffusion bonded, and the second sheet can be formed in a direction away from the first sheet. In some cases, the second sheet can also be bonded to a third sheet having a grain size that is less than the grain size of the first sheet so that the third sheet can also be superplastically formed.
According to one aspect of the invention, the first and second sheets form a first structural sub-assembly that is joined to other sub-assemblies, e.g., to form an engine exhaust heat shield. For example, a second sub-assembly can be formed by repeating the providing, heating, and superplastically forming operations used to form the first sub-assembly. The first and second sub-assemblies can be joined to opposite transverse edges of a third sub-assembly, which can also be superplastically formed. The third sub-assembly can define transversely extending channels and each of the first and second sub-assemblies can define transversely extending cells that are offset from the channels of third sub-assembly.
Embodiments of the present invention also provide a superplastically formed structural assembly. The assembly includes a first titanium sheet and a second titanium sheet that is joined to the first sheet in a stacked configuration, e.g., with the sheets joined by diffusion bonds. The second sheet is superplastically formed to a contoured configuration so that the first and second sheets define cells therebetween. Further, the first sheet has a grain size that is at least about twice a grain size of the second sheet so that the first sheet has a superplastic forming temperature that is higher than the superplastic forming temperature of the second sheet. For example, the first sheet can define a grain size of greater than about 5 micron or 8 micron and the second sheet can define a grain size less than about 2 micron such as between about 0.8 and 1.2 micron. The second sheet can be adapted to be superplastically formed at a temperature of between about 1400° F. and 1450° F. The second sheet can have a thickness that is substantial relative to the first sheet, e.g., about 75% of the thickness of the first sheet. Further, the first sheet can define a surface opposite the second sheet, and the surface can have a substantially planar configuration opposite a plurality of joints that connect the first and second sheets, i.e., without markoff or without substantial markoff of the first sheet. In some cases, the assembly can also include a third sheet that is bonded to the second sheet, the third sheet having a grain size less than the grain size of the first sheet.
The first and second sheets can define a first structural sub-assembly of an engine exhaust shield, which can also include second and third sub-assemblies. Similar to the first sub-assembly, the second sub-assembly can include first and second titanium sheets that are joined in a stacked configuration, with the second sheet superplastically formed to a contoured configuration to define cells, and with the first sheet of the second sub-assembly having a grain size that is at least about twice a grain size of the second sheet of the second sub-assembly and a correspondingly higher superplastic forming temperature. The first and second sub-assemblies can be joined to opposite transverse edges of the third sub-assembly, and each of the first and second sub-assemblies can define transversely extending cells that are longitudinally offset from transversely extending channels defined by the third sub-assembly.
Thus, the present invention provides an improved assembly and method for superplastic forming and/or diffusion bonding, in which titanium sheets having different granular structures can be used to produce the assembly. The superplastic forming can be performed at particular temperatures, such as temperatures that are below the superplastic forming temperatures of some or all of the sheets, and the formation of markoff can potentially be reduced or eliminated.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGSHaving thus described the invention in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein:
The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the invention are shown. Indeed, this invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout.
Referring now to the figures and in particular to
The structural assembly 10 is typically manufactured from a pack, i.e., a blank or preform that includes two or more sheets, which are provided in a stacked configuration, and which can be formed to various configurations. For example,
As noted above, the sheets 14, 16 are typically formed of titanium. By the term “formed of titanium,” it is meant that the sheets 14, 16 include titanium and, optionally, other materials. Typically, each of the sheets 14, 16 is formed of a titanium alloy. The various sheets 14, 16 of each single assembly 10 can be formed of the same or different alloys of titanium. For example, one or more of the sheets 14, 16 of each assembly 10 can be formed of Ti-6Al-4V (or “Ti 6-4”), which includes approximately 6% by weight aluminum, 4% by weight vanadium, and the remainder titanium, a titanium alloy that is often used for superplastic forming with or without diffusion bonding. Alternatively, one or more of the sheets 14, 16 can be formed of Ti-6Al-2Sn-4V-2Mo or other alloys.
Further, the various sheets 14, 16 of each assembly 10 can define different properties, e.g., as a result of variations in the forming or processing operations performed on the sheets 14, 16. In particular, the sheets 14, 16 can define different granular structures. For example, the first sheet 14 of the pack 12 illustrated in
The difference in the grain sizes of the materials of the first and second sheets 14, 16 can be significant. In some embodiments, the grain size of the first sheet 14 can be at least twice the grain size of the second sheet 16. For example, the grain size of the first sheet 14 can be over 5 microns, and in some cases, over 8 microns, e.g., between about 8 and 10 microns. The grain size of the second sheet 16 can be less than 5 microns, such as less than 3 microns or less than 2 microns. In particular, the grain size of the second sheet 16 can be between about 0.8 and 1.2 micron and, more particularly, about 1 micron.
The term “grain size” as used herein generally refers to a nominal grain size of the material of the sheets 14, 16 and is not representative of all of the grains thereof. In fact, each sheet 14, 16 typically includes grains of various sizes, some larger and some smaller than the nominal grain size. The nominal grain size for each sheet 14, 16 typically refers to the median grain size of the material of the sheet 14, 16. The term “micron” refers to a length of one micrometer.
It has been discovered that a variation in the grain size affects the forming characteristics of titanium. In particular, titanium having refined or reduced grain sizes can typically be superplastically formed at temperatures less than the superplastic forming temperatures of titanium having larger grain sizes. Thus, the second sheet 16 can be superplastically formed at temperatures lower than the first sheet 14. For example, Ti-6Al-4V with a grain size of about 8-10 microns can typically be superplastically formed at a minimum temperature of about 1650° F. On the other hand, Ti-6Al-4V with a grain size of 1 micron can be superplastically formed at a temperature of less than about 1500° F. and typically less than about 1450° F., such as between about 1400° F. and 1425° F.
Thus, in some cases, the second sheet 16 can be superplastically formed at a temperature that is significantly less than the minimum superplastic forming temperature of the first sheet 14. Typically, the sheets 14, 16 are provided with sufficient variation in grain size and/or composition so that the superplastic forming temperature of the second sheet 16 is between about 25° F. and 300° F. less, and more typically between about 100° F. and 250° F. less, than the superplastic forming temperature of the first sheet 14. That is, if the superplastic forming temperature of the first sheet 14 is about 1650° F., the superplastic forming temperature of the second sheet 16 can be between about 1350° F. and 1625° F. or between about 1400° F. and 1550° F., such as about 1425° F. By virtue of this difference in the superplastic forming temperatures of the various sheets 14, 16 of the pack 12, one or more of the sheets can be superplastically formed while one or more of the other sheets are not superplastically formed. In particular, the second sheet 16 of the pack 12 illustrated in
For example,
As illustrated in
As shown in
It has also been discovered that the granular structure of the sheets 14, 16 can affect the operational parameters required for diffusion bonding. In particular, sheets of the fine grain titanium materials described in the present invention can generally be diffusion bonded to conventional materials at temperatures less than those typically required for diffusion bonding the same conventional materials. For example, the fine grain second sheet 16 or the resulting assembly 10 that is described above can be diffusion bonded to a conventional member formed of a titanium alloy such as Ti-6Al-4V with a grain size of more than 1 micron at a temperature of less than about 1500° F. In some embodiments of the present invention, this diffusion bonding operation can be performed at a temperature of between about 1400° F. and 1450° F. or between about 1400° F. and 1425° F. In one particular embodiment, the diffusion bonding operation is performed by subjecting the sheets 14, 16 of Ti-6Al-4V to a temperature that is about equal to the superplastic forming temperature of the second sheet 16, e.g., less than 1500° F. such as between about 1400° F. and 1450° F. or between about 1400° F. and 1425° F. While subjected to the heating, the sheets 14, 16 are heated for about 4 hours while urging the sheets 14, 16 together with a pressure of about 300 psi, e.g., in a configuration similar to that of
It is appreciated that the diffusion bonding operation can be performed while the sheets 14, 16 are in the apparatus 20 or outside the apparatus, e.g., in another device for supporting the sheets 14, 16 during the bonding operation. Further, the sheets 14, 16 can alternatively be joined by methods other than diffusion bonding. For example, in some cases, the sheets 14, 16 can be friction stir welded or otherwise welded. Friction stir welding is generally described in U.S. Pat. No. 5,460,317 to Thomas, et al., and friction stir welding for the formation of preforms that can then be superplastically formed is further described in U.S. patent application Ser. No. 10/781,419, titled “Friction Welded Structural Assembly and Preform and Method for Same,” filed Feb. 18, 2004, each of which is incorporated in its entirety herein by reference.
After the bonds 42 are formed by diffusion bonding or otherwise, the pressurized fluid in the die cavity 26 is released. The pack 12 and/or the dies 22, 24 are heated to a superplastic forming temperature, i.e., a temperature within the superplastic forming temperature range of the second sheet 16. The pressurized fluid is injected between the sheets 14, 16 from source 34 to inflate the pack 12 and thereby superplastically form at least one of the sheets 14, 16. In the embodiment of
The heating for forming and bonding can be provided using various heaters, such as an oven that receives the pack 12 or a heater 50 that is integrated into the dies 22, 24. In some embodiments, the dies 22, 24 can remain relatively unheated while the pack 12 is heated to the superplastic forming temperature by a susceptor in which an electrical current is induced by an induction coil, as described in U.S. Pat. No. 5,683,607 to Gillespie, et al, the entirety of which is incorporated herein by reference.
If the second sheet 16 is superplastically formed at a temperature that is less than the superplastic forming temperature of the first sheet 14, and the first sheet 16 is therefore not heated to its own superplastic forming temperature during the forming operation of the second sheet 16, the deformation of the first sheet 14 can be limited or otherwise controlled. That is, while the first sheet 14 can be slightly formed to conform to the contour of the first die 22, the first sheet 14 typically does not become superplastic and therefore maintains sufficient stiffness during forming to resist being deformed by the formation of the second sheet 16. In particular, even though uneven forces may be exerted on the first sheet 14, e.g., with the first sheet 14 being pulled by the second sheet 16 at the locations of the diffusion bonds 42 therebetween, the first sheet 14 can resist deformation thereby. Thus, after forming to the desired shape of the structural assembly 10 as shown in
Each of the sheets 14, 16 can be provided with various thicknesses and other dimensions. Thus, while the superplastic formation of relatively thick sheets according to conventional forming techniques would typically result in markoff on the sheets connected thereto, the methods of the present invention can be used to superplastically form sheets that are relatively thick compared to the sheets connected thereto without the formation of any markoff or without the formation of significant markoff. In particular, in some embodiments of the present invention, a superplastically formed sheet (such as the second sheet 16) can have a thickness that is at least 25% of the thickness of the sheet(s) that are bonded thereto (such as the first sheet 14). In fact, the superplastically formed sheets can be greater than 50% or 75% of the thickness of the sheets connected thereto and, in some cases, the formed sheets can be as thick as, or thicker than, the sheets connected thereto. For example, as illustrated in
In addition, it is appreciated that the superplastic forming and/or diffusion bonding operation of the present invention can generally be performed at reduced temperatures, i.e., at temperatures lower than those required for superplastically forming the coarsest grain materials of the pack 12. For example, if the second sheet 16 is formed of titanium with a refined grain structure, the second sheet 16 can generally be superplastically formed and/or diffusion bonded at temperatures lower than those of conventional superplastic forming and/or diffusion bonding operations. This reduction in processing temperature can reduce the thermal stresses exerted on the dies 22, 24 or other tooling used during the operation, thereby reducing pitting or other degradation of the dies 22, 24 and potentially extending the useful life of the dies 22, 24 and other tooling and reducing cleaning, dressing, or other maintenance. In addition, the lower forming/bonding temperatures generally put less demand on the heater 50 that is used for heating the pack 12 to the forming/bonding temperature, and also require less energy. In fact, the reduction in heating can reduce the initial cost of the heaters, reduce the cost of operating heaters used to heat the packs during forming and/or bonding, and/or extend the useful life of the heaters. Further, in some cases, the use of sheets with refined granular structures can also reduce the necessary forming stress for superplastically forming the materials, and/or increase the strain rates that can be achieved during forming so that the forming operation can be completed more quickly. In addition, the reduction in the forming temperature and time required for forming can reduce both the formation of oxides and a layer of alpha case on the sheets during forming. Methods of superplastically forming refined grain materials, and features of such methods, are further described in U.S. patent application Ser. No. 10/813,892, titled “Superplastic forming and diffusion bonding of fine grain titanium,” filed Mar. 31, 2004, the entirety of which is incorporated herein by reference.
In other embodiments of the present invention, any number of sheets can be bonded and formed. For example, a pack can include three or more sheets, and one or more of the sheets can be superplastically formed, e.g., against multiple contour surfaces. Devices and methods for forming single sheets and multiple-sheet packs are further described in U.S. patent application Ser. No. 10/813,892, titled “Superplastic forming and diffusion bonding of fine grain titanium,” incorporated above. In this regard,
Thereafter, the diffusion bonded pack 12a is heated in the apparatus 20a to a superplastic forming temperature of at least one of the sheets 14a, 16a, 18a. For example, the second and third sheets 16a, 18a can be formed of a material with a refined grain structure with a lower superplastic forming temperature than the first sheet 14a, and the pack 12a can be heated to a temperature that is greater than the superplastic temperature of the second and third sheets 16a, 18a but less than the superplastic forming temperature of the first sheet 14a. With the pack 12a so heated, pressurized fluid is injected from fluid source 34a between the sheets 14a, 16a, 18a to superplastically form the second and third sheets 16a, 18a by inflating the cells 48a defined between the sheets 14a, 16a, 18a, such that the third sheet 18a is disposed against the contoured surface 30a of the second die 24. The first sheet 14a can also be formed during this operation, e.g., to form a slightly curved contour corresponding to surface 28a, but the first sheet 14a is typically not superplastically formed. In this embodiment, the formation of markoff or other undesired deformation of the first sheet 14a can be avoided at regions 44a, even though the thicknesses of the second and third sheets 16a, 18a can be about equal to the thickness of the first sheet 14a or otherwise relatively great compared to the thickness of the first sheet 14a.
The heat shield 10b illustrated in
Each of the structural sub-assemblies 64, 66, 68, 70, 72, 74 can be formed by joining multiple sheets and superplastically forming at least one of the joined sheets according to the methods set forth above. For example, each of the first and second sub-assemblies 64, 66, 70, 72 of the two portions 60, 62 includes an outer sheet 78 and an inner sheet 80. Each inner sheet 80 is diffusion bonded or otherwise joined to the outer sheet 78 of the respective sub-assembly 64, 66, 70, 72. The inner sheet 80 is formed of a material that is characterized by a superplastic forming temperature that is less than the minimum superplastic forming temperature of the respective outer sheet 78. Thus, the inner sheets 80 can be superplastically formed at a temperature that is insufficient for superplastically forming the respective outer sheet 78, e.g., to avoid deforming the outer sheet 78 so as to cause markoff as described above. In particular, the inner sheet 80 of each sub-assembly 64, 66, 70, 72 can be formed of titanium with a grain size of less than 5 microns, e.g., about 1 micron, and the outer sheet 78 of each sub-assembly can be formed of titanium with a grain size that is greater than 5 microns, e.g., greater than about 8 microns.
Each inner sheet 80 is superplastically formed to define a number of transversely extending cells 82. For example, as described above, the outer and inner sheets 78, 80 of each sub-assembly 64, 66, 70, 72 can be provided in a substantially planar configuration, with a stop-off material provided between the sheets 78, 80 coincident with the desired location of the cells 82. In this way, the sheets 78, 80 of each sub-assembly 64, 66, 70, 72 can be diffusion bonded without bonding the sheets 78, 80 at the desired location of the cells 82. Thereafter, the sheets 78, 80 can be heated to a superplastic forming temperature of the inner sheet 80, and gas can be injected between the sheets 78, 80 to inflate the cells 82. The cells 82 of each sub-assembly 64, 66, 70, 72 can be fluidly joined by one or more longitudinally extending tubes 86 or bead-like passages, e.g., by applying the stop-off material at the location of the tubes 86 to prevent diffusion bonding. Thus, the cells 82 can be inflated during the superplastic forming of the inner sheet 80 by injected the gas into the tubes 86 so that the gas flows therefrom into each of the cells 82. The cells 82 are normally defined as inwardly extending channels in the inner sheet 80 as shown in
Each of the third sub-assemblies 68, 74 can similarly be formed from a stack or pack of sheets. Alternatively, as illustrated in
The frame members 76 disposed in the heat shield 10b can also be formed of titanium and can be superplastically formed. As shown in
In some embodiments, the sub-assemblies 64, 66, 68, 70, 72, 74 are large members, i.e., larger than conventional sub-assemblies that can be formed of members that are formed by casting or other non-superplastic forming methods. The use of superplastic forming in the manufacture of large members is further described in U.S. patent application Ser. No. 10/970,151, titled “Formed Structural Assembly and Associated Preform and Method,” filed Oct. 21, 2004. Further, the heat shield 10b can be formed and assembled in a configuration that reduces drag and the potential paths for leaking of hot gases into the cavity defined by the heat shield 10b. In addition, the use of superplastic forming and/or diffusion bonding can reduce the weight of the heat shield 10b and reduce the manufacturing cost.
It is also appreciated that each of the various sub-assemblies 64, 66, 68, 70, 72, 74 of the heat shield 10b can be formed of any number of sheets, one or more of which can be superplastically formed and one or more of which can be non-superplastically formed or unformed. In this regard,
Many modifications and other embodiments of the invention set forth herein will come to mind to one skilled in the art to which this invention pertains having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the invention is not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
Claims
1. A method for superplastically forming a pack to produce a structural assembly having a predetermined configuration, the method comprising:
- providing the pack comprising first and second titanium sheets in a stacked configuration, the first sheet having a grain size that is at least about twice a grain size of the second sheet;
- heating the pack to at least a superplastic forming temperature of the second sheet; and
- superplastically forming the second sheet of the pack to a predetermined configuration and thereby forming the assembly.
2. A method according to claim 1 wherein said providing step comprises providing the first sheet defining a grain size of greater than about 5 micron and the second sheet defining a grain size less than about 2 micron.
3. A method according to claim 1 wherein said providing step comprises providing the first sheet defining a grain size of greater than about 8 micron and the second sheet defining a grain size of between about 0.8 and 1.2 micron.
4. A method according to claim 1 wherein said providing step comprises providing a third sheet bonded to the second sheet, the third sheet having a grain size less than the grain size of the first sheet such that the third sheet is superplastically formed during the superplastic forming step.
5. A method according to claim 1 wherein said providing step comprises providing the second sheet having a thickness that is at least 75% of a thickness of the first sheet.
6. A method according to claim 1, further comprising diffusion bonding the sheets, and wherein said superplastically forming step comprises forming the second sheet in a direction away from the first sheet.
7. A method according to claim 1 wherein said superplastically forming step comprises superplastically forming the second sheet at a temperature less than a superplastic forming temperature of the first sheet.
8. A method according to claim 1 wherein said superplastically forming step comprises superplastically forming the second sheet at a temperature of between about 1400° F. and 1450° F.
9. A method according to claim 1 wherein said superplastically forming step comprises forming the second sheet of the pack without superplastically forming the first sheet.
10. A method according to claim 9, further comprising nonsuperplastically forming the first sheet during said superplastically forming step.
11. A method according to claim 1 wherein said superplastically forming step comprises forming a first structural sub-assembly and further comprising:
- repeating said providing, heating, and superplastically forming steps to form a second structural sub-assembly; and
- joining the first and second sub-assemblies to opposite transverse edges of a third sub-assembly defining transversely extending channels to form an engine exhaust heat shield,
- wherein each of the first and second sub-assemblies defines transversely extending cells, the cells of the first and second sub-assemblies being offset from the channels of third sub-assembly.
12. A superplastically formed structural assembly comprising: a first titanium sheet;
- a second titanium sheet joined to the first sheet in a stacked configuration, the second sheet being superplastically formed to a contoured configuration such that the first and second sheets define cells therebetween,
- wherein the first sheet has a grain size that is at least about twice a grain size of the second sheet, such that the first sheet has a superplastic forming temperature that is higher than the superplastic forming temperature of the second sheet.
13. A structural assembly according to claim 12 wherein the first sheet defines a grain size of greater than about 5 micron and the second sheet defines a grain size less than about 2 micron.
14. A structural assembly according to claim 12 wherein the first sheet defines a grain size of greater than about 8 micron and the second sheet defines a grain size of between about 0.8 and 1.2 micron.
15. A structural assembly according to claim 12, further comprising a third sheet bonded to the second sheet, the third sheet having a grain size less than the grain size of the first sheet.
16. A structural assembly according to claim 12 wherein the sheets are joined by diffusion bonds.
17. A structural assembly according to claim 12 wherein second sheet is adapted to be superplastically formed at a temperature of between about 1400° F. and 1450° F.
18. A structural assembly according to claim 12 wherein the first and second sheets define a first structural sub-assembly of an engine exhaust shield and further comprising:
- a second structural sub-assembly of the engine exhaust shield, the second structural sub-assemblies comprising first and second titanium sheets joined in a stacked configuration, the second sheet of the second structural sub-assembly being superplastically formed to a contoured configuration such that the first and second sheets of the second structural sub-assembly define cells therebetween, the first sheet of the second structural sub-assembly having a grain size that is at least about twice a grain size of the second sheet of the second structural sub-assembly such that the first sheet of the second structural sub-assembly has a superplastic forming temperature that is higher than the superplastic forming temperature of the second sheet of the second structural sub-assembly; and
- a third structural sub-assembly formed of titanium and defining transversely extending channels,
- wherein the first and second sub-assemblies are joined to opposite transverse edges of the third sub-assembly, and each of the first and second sub-assemblies defines transversely extending cells, the cells of the first and second sub-assemblies being offset from the channels of the third sub-assembly.
19. A structural assembly according to claim 12, wherein the second sheet has a thickness that is at least 75% of a thickness of the first sheet.
20. A structural assembly according to claim 12, wherein the first sheet defines a surface opposite the second sheet, the surface defining a substantially planar configuration opposite a plurality of joints connecting the first and second sheets.
21. A structural assembly according to claim 12 wherein the structural assembly is an aircraft component.
22. A method of manufacturing an aircraft structure, the method comprising:
- heating a first titanium sheet having a grain size and a second titanium sheet having a grain size that is at least about half the size of that of the first sheet, to at least a superplastic forming temperature of the second sheet; and
- superplastically forming the second sheet into an aircraft component.
23. The method of claim 22 wherein the forming step comprises forming the second sheet into a component of an airframe.
24. The method of claim 22, further comprising mounting the aircraft component on an airframe.
25. An airframe comprising an aircraft structure including:
- a first titanium sheet having a superplastic forming temperature; and
- a second titanium sheet having superplastic forming temperature that is less than that of the first sheet;
- the second sheet being superplastically formed in a contoured configuration and joined to the first sheet in a stacked configuration such that cells are disposed between the sheets.
26. The airframe of claim 25 wherein the aircraft structure is an engine exhaust heat shield.
27. The airframe of claim 25 wherein the aircraft structure is an access door.
Type: Application
Filed: Nov 10, 2005
Publication Date: Jan 29, 2009
Patent Grant number: 7850058
Applicant:
Inventors: Thomas Connelly (Bellevue, WA), Kent Dunstan (Federal Way, WA), William Williams (Federal Way, WA), Peter Comley (Sumner, WA), Larry Hefti (Auburn, WA)
Application Number: 11/272,244
International Classification: B23K 31/02 (20060101); B21D 39/00 (20060101); B23K 20/00 (20060101);