CA1089413A - Method of making a metallic structure by combined flow forming and bonding - Google Patents

Abstract

METHOD OF MAKING A METALLIC STRUCTURE
BY COMBINED FLOW FORMING AND BONDING

ABSTRACT

A method for fabricating metallic structures, especially those having intricate shapes, utilizes a combination of flow forming and bonding. A metal preform having flow forming characteristics is positioned relative to a shaping member and a metal workpiece to be joined to the preform. The preform is heated to a temperature range suitable for flow forming. Pressure is applied to cause the preform to flow form against the shaping member and the workpiece. The preform and workpiece are maintained under coordinated temperature-pressure-time duration conditions to produce metallurgical bonding of the preform to the workpiece.

Description

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BACKGRCUND OF THE INVENTION
The present invention relates to a process for fabricating metallic structures utilizing flow forming and i~
bonding. Flow forming is a process where a part is formed by the use of heat and compressive pressure. It is to be distinguished from superplastic forming where parts are drawn under tensile stress. The part to be formed is placed within tooling and heated to the temperature at which the part material becomes plastic. Pressure is then applied to the tooling to flow the part material into the shape dictated by the tooling~ The major object of the flow forming pro-cess is to form a structure to substantially net shape to thereby reduce conventional machining and obviate the need where possible for a plurality of parts which must be joined to form the final structure.
A method of flow forming is described in U. S.
Patent No. 3,519,503 to Moore, et al. In this method, high strength alloys are heated to a temperature placing them in a condition of low strength and high ductility and forged 20 in hot dies to a desired shape. However, with such state -`
of the art flow forming methods, limited hardware configura-tions are available. It is normally quite difficult, if not impossible, to fabricate some hardware designs such as thin webs and stiffeners using state of the art flow forming (also known as hot die forging) processes because of the difficulty in causing the material to flow into narrow cavi-ties or thin sections or other desirable design configurations.
For some parts, it is necessar~ with state of the art methods to produce special preform configurations to assure that the ~ `~
finished part can be readily produced in the final operation.
Such preforms require either machining or preform dies and add cost to the finished part.

-2-~UMMARY OF THE INVENTION
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It is, therefoxe, an object of ~he present inven-tion to efficiently fabricate metallic structures haviny difficult configurations or intricate shapes.
It is another ohject of the present invention to make metallic structuxes in a single operation by a combina-tion of flow forming and bonding.
It is yet another object of the present invention to flow form a metal preform against a shaping member and workpiece such that the metal workpiece is bonded to the pre-form to form the desired structure.
It is still another object of the present invention to make a metallic structure from a preform and metal work-piece by combining flow forming and bonding, thereby reducing the time, raw material usage, cost, structure weight, and fatigue weakness in fabricating and mechanically fastening the multiple components of a structure.
Briefly, in accordance with the invention, there ~-is provided a method for making a metallic structure by com-bining flow forming with bonding. A metal preform having flow forming characteristics, a shaping member, and a metal workpiece to be ~oined to the preform, are positioned rela-tive to one another. The preform is heated to within a temperature range suitable for flow forming of the preform.
Pressure is applied to the preform to cause it to flow form against the shaping member and the workpiece. The preform and workpiece are maintained under coordinated temperature-pressure-time duration conditions suitable for metallurgical ~ -~
bonding of the preform to the workpiece. Optimally, the ~;
metallurgical bonding of the preform to the workpiece is by diffusion bonding.
In a particular embodiment of the invention, the preform and workpiece are heated to within a temperature range .

~ 3~ 13 suitable for the flow forming of t:he preform and sufficient for metallurgical bonding of the preform to the workpiece.
In another particular embodiment of the invention, the temperature range suitable for the flow forming of the preform is also suitable for the flow forming of the work-piece, and the preform and workpiece flow ~orm against the shaping member and one another.
Other objects and advantages of the invention will become apparent upon reading the following detailed descrip-tion and upon reference to the drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure l is a cross-sectional elevational view of ,~
the basic forming and bonding apparatus employed in the present method of making a metallic structure by flow forming with concurrent bonding showing the preform and the workpieces in the initial position;
Figure 2 is a cross-sectional diagramatic illu-straion of the forming and bonding apparatus showing the fully formed and bonded metallic st;ructure which has been fabricated;
Figure 3 is~a cross-sectional diagramatic illustra-tion of a second embodiment of the present invention illustra- ~ `
ting the initial position of two preforms and a workpiece ;
relative to the shaping members of the forming apparatus;
Figure 4 is a cross-sectional diagramatic illustra-tion of the Figure 3 embodiment showing the resulting forming of the preforms and workpiece and the bonding of the component parts to one another of the fabricated metallic structure.
While the invention will be~described in connection with the preferred embodiment, it will be understood that it is not intended to limit the invention to those embodiments.
On the contrary, it is intended to cover all alterna~ives, modifications, and equivalents that may be included within the spirit and scope of the invention as defined by the appended claims.
DETAILED DESCRIPTION OF THE INVENTION
Referring now to Figure 1, there is shown an example of a forming apparatus generally indicated at 10 for carrying out the present invention. A retort 12 is preferably provided as a housing for forming apparatus 10.
Within the retort 12 is optimally provided a baseplate 14 and vertically extending support frames 16 and 17 positioned on opposite sides of baseplate 14. Additional support frames (not shown) could be provided as where there would be four separate support frames, each being positioned on the respec-tive sides of baseplate 14.
Positioned on baseplate 14 between frame members 16 and 17 are preferably a plurality of dies or shaping members 20, 22, and 24. While it is preferred to use a plurality of segmented dies as shown, a single integral die could equivalently be used. However, using a plurality of dies as shown in Figure 1 facilitates set-up and disassembly of the forming apparatus and removal of the fabricated metal-lic structure therefrom.
A primary consideration in selection of a suitable shaping member alloy is reactivity with the metal or metals to be formed at forming temperature. When the metal to be formed is titanium or an alloy thereof, iron based alloys with low nickel content and modest carbon content (as 0.2-0.5~ -carbon) have been successful.
A preform 30 is preferably positioned over dies 20, 22, and 24 between support frames 16 and 17 and below a punch member (also considered a die or shaping member) 32. Shaping members 20 and 22 define a cavity 50 therebetween and shaping members 22 and 24 define a cavity 52 therebetween. Within grooves 50 and 52 there are provided metal workpieces 54 and _5_ -56 respectively (ox a plurality in each groove if so desired) to which the metal preform 30 is to join.
Dies 20, 22, and 24, frame members 16 and 17, and punch 32 are designed and arranged to form a chamber 34 which is su~stantially complementary to the desired final shape of preform 30. While not shown, any of the aforementioned shaping members can have protuberances on its surface contac-ting preform 30 which in forming of preform 30 would act as a male die member. The metal workpieces 54 and 56 act as male die members in the forming of preform 30 and are of such a shape and positioned in such a manner that the desired final structure will result when the preform is flow formed and bonded to workpieces 54 and 56.
Preform 30 can be in a variety of forms such as billet, bar stock, sheet stock, plate stock, rod, pellets, or combinations of these forms. Preform 30 is optimally a wrought material as the flow forming process would normally not affect a working of the preform, i.e., no mechanical property improvement results. In Figure 1 there is shown a plate stock preform 30 whiCh norma:Lly would have a fairly substantial thickness such that superplastic forming utili- ~;
zing a differential gas pressure would not be practical due to the large forming time required or where the desired final shape would be particularly difficult for such a process.
Any metal capable of sufficient plastic deformation under compressive pressure at obtainable economical temperatures, but preferably one that exhibits suitable superplastic pro-perties, can be used for preform 30, but the present invention is particularly concerned with such metals that are subject i~
to contamination at forming temperatures, such as titanium or an alloy thereof such as Ti-6Al-4V. The advantage o a superplastic material :is that the flow stresses are lower at lower strain rates which can thereby often permit reduced ` -`

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pressures to cause flow forming (albeit at lower strain rates).
The extent to which any material selected will exhi-bit superplastic properties is predictable in general terms from a determination of its strength and strain rate sensiti-vity and a design determination of the permissible variation in wall thickness. Strain rate sensitivity can be defined as m where ~7 -- ,, and c is stress in pounds per square inch and ~ is strain rate in reciprocal minutes. Strain rate sensitivity may be deter-mined by a simple and now well recognized torsion test described in the article: "Determination of Strain-Hardening Characteristics by Torsion Testing", by D. S. Fields, Jr. and W. A. Backofen, published in the proceedings of ASTM, 1957, Volume 57, Pages 1259-1279. A strain rate sensitivity of about 0.5 or greater can be expected to produce satisfactory results, with the larger the value (to a maximum of 1) the greater the superplastic properties.
The initial thickness of preform 30 is determined by the dimensions of the part to be formPd. The selection of the material for preform 30 should also take into consideration certain variables which have been ound to affect strain rate sensitivity of the flow stress. Decreasing grain size results in correspondingly higher values for strain rate sensitivity and lower available flow stresses. Additicnally, strain rate and material texture affect the strain rate sensitivity.
Metal workpieces 54 and 56 can be of any desired shape or matexial, provided that it is subject to being metal-lurgically bonded to the metal preform, such as by diffusion bonding or bra2ing. In the Figure 1 embodiment, it is not re~uired that the metal workpieces 54 and 56 to have flow forming characteristics because they are not being formed.

However, as discussed hereinafter with reference to Figures 3 and 4, it may be desirable for the metal workpieces to have such characteristics and optimally be of a superplastic mate-rial. It should also be noted that different materials ~or the metal workpieces 54 and 56 and the preform 30 ~lay be used, although the joint strength would be expected to vary depen-ding on the combination of materials used. In such cases, an interleaf material may be necessary or advisable between dis-similar metals.
Once the preform and forming apparatus have been pro-perly arranged relative to one another within retort 1~ and the lid 60 of retort 12 sealed as by welding it shut, forming `
apparatus 10 is placed in a press between press platens 62 and 6~. In the Figure 1 embodiment, platen 64 acts as a support for the forming apparatus and prevents movement of the forming apparatus while pressure is applied by platen 62 to compress preform 30. Suitable retaining members (not shown) are provi-ded along the lateral sides of the retort 12 to prevent move-ment of the forming apparatus in any of those directions.
Maximum strain rate sensitivity in metals is seen 20 to occur, if at all, as metals are deformed near the phase -~
transformation temperature, which varies with parameters such as grain structure and composition of the preform. According-ly, the temperature immediately below the phase transformation ;~
temperature can be expected to produce the greates~ strain rate sensitivity. For titanium and its alloys, the temperature range which superplasticity and optimal flow forming charac-teristics can be observed is about 1450F to about 1850F
depending upon the specific alloy used. For Ti-6Al-~V, a temperature of about 1700F is normally used.
Various heat:ing methods can be used for heating the ;
preform 30 to the desixed forming temperature (where the metal would be in a plastic state capable of flow forming). One particularly advantageous arrangement is illustrated in Figure 34~L3 1. There platens 62 and 64 are preferably made of a ceramic material and provided with resistance heated wires 70. Heat from the resistance wires 70 is transmitted through the re-tort 12, base-plate 14, dies 20, 22 and 24, and punch 32 to preform 30 and metallic workpieces 54 and 56. As tooling frames 16 and 17, dies 20, 22, and 24, and punch 34 are also by this method heated to the forming temperature, the areas of the preform 30 and workpie~es 54 and 56 contacted by these other members during forming do not have their temperature substantially affected.
Optimally, the temperature used for forming of pre-form 30 would also be within a range where bonding of the metal workpieces 54 and 56 to preform 30 could take place.
Alternatively, the temperature could be varied after the for-ming of the preform 30 such that bonding of workpieces 54 and 56 to preform 30 could take place.
Bonding of the preform 30 to the workpieces 54 and 56 is preferably accomplished by diffusion bonding. Diffusion bonding refers to the metallurgical joining of surfaces of - 20 similar or dissimilar metals by applying heat and pressure for a time duration so as to cause comingling o~ the atoms at the joint interface. Diffusion bonding is accomplished entirely in the solid state at or above one-half the base metal melting point (absolute). Actual times, temperatures, and pressures will vary from metal to metal. ~owever, for Ti-6Al-4V, a temperature of about 1700F is normall~ used. Other forms of metallurgical bonding such as brazing could be used. If bra- -zing was selected to be the joining method, a suitable brazing material would have to overlie the portions of the metallic 30 workpieces 54 and 56 which are to bond the preform 30.
Where the preform 30 or metal workpieces 54 and 56 are made up of a metal or alloy which would be subject to con-tamination at the temperatures required for flow forming or ;

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bonding, an environmental control system can be provided.
Such a system would expose the preform 30 and metal workpieces 54 and 56 only ~o inert gas, such as argon, or a vacuum while heating and forming. Preform 30 and workpieces 54 and 56 will not react with the inert gas due to the nature of the inert gas, even at elevated forming and bonding temperatures. In a high vacuum, there are substantially no elements for the pre-form 30 or workpieces 54 and 56 to react with. Thus, in either environment, contamination of the metal pxeform 30 or work-pieces 54 and 56 will be prevented.
To a~complish environmental control, a line 72 is -connected through retort 12 to an aligned lateral conduit 74 in tooling frame 17. A lateral conduit 76 extending through die me~ber 24 connects with conduit 74. Lateral conduit 78 which extends through die member 22 is aligned with conduit 76 but spaced therefrom due to cavity 52.
Line 72 can be connected to a source (not shown) of vacuum and/or inert gas such that during hèating,-forming, and -~joining, air could be withdrawn from chamber 34 (which inclu-20 des cavities 50 and 52) to provide ~ substantially contamina- -tion free vacuum environment around preform 30 and metal work-pieces 54 and 56. Additionally, if desired, after such with-drawal of air, inert gas could be provided to the aforementio- ~ -ned conduits to flow to chamber 34 so that there would be an inert gas environment around the preform 30 and workpieces 54 and 56 during heating, forming, and bonding.
When such a contamination prevention or controlled environment system is utilized, it is desirable to seal the forming apparatus to prevent entrance into chamber 34 of any contaminating air. This is accomplished in a preferred manner illustrated in Figure 1 by the use of retort 12, ~hich is a completely sealed enclosure around the forming apparatus 10.
Thus, by providing forming apparatus 10 with a housing made ... , . : .
. ., - . . .

up of retort 12, a seal is effected when the lid 60 of retort ; 12 is suitably jcined, as by welding, to the body of retort 12.
After the tempexature of preform 30 is raised to the desired formi~g temperature, which optimally would also be suitable for the bonding of preform 34 to metallic workpieces 54 and 56, pressure is applied to preform 30 by the action of the press (not shown) through platens 62 and 64. Platen 64, which acts on the bottom of retort 12, and other suitable pressure appl~ing mechanisms (not shown), which act on the lateral sides of retort 12, apply sufficient pressure to pre-vent movement of tooling members 16 and 17, and dies 20, 22, and 24 while platen 62 acts on the lid of retort 12 forcing punch 32 downward against preform 30, which is in a plastic state due to the elevated temperature. Such pressure acts to deform retort 12, so care should be taken to make sure that the seal is not lost due to such deformation (some sealing techniques, such as a sliding seal, may obviate this)~
As shown in Figures 1 and 2, the pressure applied indicated by arrows 80 acts to compress preform 30 against die membars 20, 22, and 24 while tooling frame members 16 and 17 prevent lateral deformation of preform 30 due to the pras-sure 80. Pressure 80 can vary and itdepends upon many para-meters such as the particular metal or alloy used or preform 30 and how formable and superplastic it is at the forming temperature, thickness of the preform 30, amount of deforma-tion re~uired for the preform 30, and desired time of proces-sing, etc. Applicants have found that for titanium and its allo~s, and particularly the Ti~6Al-4V alloy, the range of pressure that can be used is 1500-3500 psi, with the prefer-red range being 2000-3000 psi, with the lower end of the range producing better results~ Depending upon the configuration, this pressure is normally applied for four to five hours, but could be as low as one-hal~ hour when simple shapes are to be fabricat~d.
~ ue to the compressive pressure 80, preform 30 de-forms against dies 20, 22, and 24 with material flow into cavities or grooves 50 and 52. As the material flow of pre-form 30 proceeds further into cavities 50 and 52, it contacts workpieces 54 and 56 which act as male die members. As seen in Figure 2, the preform 30 flows around those portions of workpieces 54 and 56 which protrude into cavities 50 and 52D
By virtue of the intimate contact between the preform 30 and workpieces 54 and 56 and coordinated temperature-pressure-time duration conditions, bonding of the preform 30 to the work-pieces 54 and 56 results (either directly as by diffusion bonding or indirectly as by brazing). Normally, the tempera-ture at which the preform 30 is flow formed is suitable for bonding. However, the temperature could be varied after the "
flow forming of preform 30 if necessary for bonding. Similar-ly, the pressure for flow forming of the preform 30 is normal-ly suitable for bonding of the preform 30 to workpieces 54 and 56, but can be varied if necessary after flow forming to 20 effectuate the bonding. The pressure is maintained for a time ~ `~
duration sufficient to produce ade~uate bonding. This time will vary depending upon the metals being bonded, temperature, -~
and pressure. Longer times, however, insure more complete bonding. Normally though, adequate bonding can be obtained in one to five hours when diffusion bonding Ti-6Al-4V at `~
1700F and 2000 psi.
Inert gas which may be in cavities 50 and 52 is vented through conduits 78, 76 and 74 to line 72 by deforma-tion of the preform 30. The final formed structure is shown ;~
in Figure 2. As can be seen, the final formed structure hasa complex shape which with present state of tha art methods would be quite difficu:Lt if not impossible to fabricate. The -structure is unitary rather than a plurality of parts - ~

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mechanically fastened. Further, by accomplishing both flow forming and bondiny in one process and in one apparatus, a great deal of time and expense is saved.
Referring now to Figures 3 and 4, another embodi-ment of the present invention is illustrated in diagramatic form. In this embodiment, a clevis-type joint is fabricated.
Using applicants' process, the machining of deep slots normal-ly required for this type of part is no longer necessary.
Forming dies 100, 102, and 104 are machined to the shape desired. As shown, die 100 has a laterally extending protru-ding portion 106 of variable thickness which provides for the complex shaped deep slot having stepped ~oints. Protruding portion 106 of die 100 is positioned midway between dies 102 and 104. Within a chamber 108 defined by dies 100, 102, and 104 are positioned preform 110, preform 112, and workpiece 114. Preforms 110 and 112 and workpiece 114 are arranged rela- ~`
tive to each other and shaping members 100, 102 and 104 such that the unitary part to be flow formed and joined will have the desired final shape.
As best seen in Figure 4, the structure to be fabri-cated is achieved by the flow forming of preforms 110 and 112 and workpiece 114. Accordingly, workpiece 114 could be con-sidered a "preform" (or vice versa for preforms 110 and 112), but is for convenience referred to as a workpiece. Workpiece 114 should be of an alloy suitable for flow forming in addi-tion to being suitable for bonding to preforms 110 and 112.
Optimally, the preforms 110 and 112 and workpiece 114 would ~`
be heated to a temperature range at which they all are capable i of being flow formed. Pressure indicated by arrows 120 com-presses preforms 110 and 112 and workpiece 114 against each other and dies 100, 102, and 104. This results in the flow forming of the preforms 110 and 112 and workpiece 114 to the desired shape and the metallurgical bonding shown along bond lines 122 and 124 when the pressure is maintained for the necessar~ time duration. Pressures and temperatures could of course be varied during the process to accomplish the desired reult, i.e. where pressure 120 or the temperature must be varied to effect the bonding or for flow forming of either the preforms 110 and 112 or workpiece 114. ~-The final fabricated structure is shown in Figure 4. As can be seen, this is a clevis-type structure having parallel legs 126 and 128 which define a deep stepped slot connected at a joint 130 which continues into a single oppo-sitely extending leg 132.
While the illustrated embodiments of the invention utilize at least some flow forming prior to bonding, some structures may be fabricated using an opposite approach, i.e., where at least some (if not all) of the bonding would take "
place prior to flow forming of the preform (and workpieces where applicable). ~ -Thus, it is apparent that there has been provided;~
in accordance with the invention, a method of flow forming with combined bonding to make a metallic structure that fully satisfies the objectives, aims, and advantages set forth above. -While the invention has been described in conjunction with specific embodimentsthereof, it is evident that many alterna- ~
tives, modifications, and variations will be apparent to those ~ `
skilled in the art in light of the foregoing description.~ `
Accordingly, it is intended to embrace all such alternatives, modifications, and variations as fall within the spirit and scope of the appended claims.

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Claims (19)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A method of making a metallic structure by combined flow-forming and bonding comprising the steps of:
providing a metal preform having flow-forming characteristics;
providing a shaping member;
providing a metal workpiece to be joined to the preform;
positioning the preform relative to the shaping member and the workpiece;
heating the preform to within a temperature range suitable for flow-forming of the preform;
applying pressure to the preform sufficient to cause the preform to flow-form against the shaping member and the workpiece;
maintaining the preform and the workpiece under coordinate temperature-pressure-time duration conditions suitable for metallurgical bonding of the preform to the workpiece.

2. The method of Claim 1, wherein the metallurgi-cal bonding of the preform to the workpiece is diffusion bonding.

3. The method of Claim 1, wherein the temperature range suitable for flow-forming of the preform is also suit-able for metallurgical bonding of the preform to the workpiece.

4. The method of Claim 3, wherein the metallurgical bonding of the preform to the workpiece is diffusion bonding.

5. The method of Claim 1, wherein the pressure ap-plied to the preform sufficient to cause the preform to flow-form is also suitable for metallurgical bonding of the preform to the workpiece.

6. The method of Claim 2, wherein the pressure ap-plied to the preform sufficient to cause the preform to flow-form is also suitable for diffusion bonding of the preform to the workpiece.

7. The method of Claim 3, wherein the pressure ap-plied to the preform sufficient to cause the preform to flow-form is also suitable for metallurgical bonding of the preform to the workpiece.

8. The method of Claim 4, wherein the pressure ap-plied to the preform sufficient to cause the preform to flow-form is also suitable for diffusion bonding of the preform to the workpiece.

9. The method of Claim 1, also including the step of bringing the preform and the workpiece to within a tempera-ture range suitable for metallurgical bonding of the preform to the workpiece.

10. The method of Claim 1, also including the step of adjusting the pressure to a magnitude sufficient for metal-lurgical bonding of the preform to the workpiece.

11. The method of Claim 9, also including the step of adjusting the pressure to a magnitude sufficient for metal-lurgical bonding of the preform to the workpiece.

12. The method of Claim 1, wherein the shaping mem-ber has a groove therein, the workpiece is positioned in the groove, and the preform flow-forms into the groove when flow-formed against the shaping member, whereby the preform forms against the workpiece within the groove.

13. The method of Claim 1, wherein said heating is of the preform and the workpiece to within a temperature range suitable for flow-forming of the preform and the workpiece and wherein said applying pressure is to the preform and the work-piece and is sufficient to cause the preform and the workpiece to flow-form against the shaping member and one another.

14. The method of Claim 4, wherein said heating is of the preform and the workpiece to within a temperature range suitable for flow-forming of the preform and the workpiece and wherein said applying pressure is to the preform and the work-piece and is sufficient to cause the preform and the workpiece to flow-form against the shaping member and one another.

15. The method of Claim 8, wherein said heating is of the preform and the workpiece to within a temperature range suitable for flow-forming of the preform and the workpiece and wherein said applying pressure is to the preform and the work-piece and is sufficient to cause the preform and the workpiece to flow-form against the shaping member and one another.

16. The method of Claim 11, wherein said heating is of the preform and the workpiece to within a temperature range suitable for flow-forming of the preform and the workpiece and wherein said applying pressure is to the preform and the work-piece and is sufficient to cause the preform and the workpiece to flow-form against the shaping member and one another.

17. The method of making a metallic structure by combined flow-forming and bonding comprising the following steps in the order named:
providing a metal preform having flow-forming characteristics, a shaping member, and a metal workpiece to be joined to the preform;
positioning the preform relative to the workpiece;
maintaining the preform and the workpiece under coordinated temperature-pressure-time duration conditions suitable for metallurgical bonding of the preform to the work-piece; and applying pressure to the preform sufficient to cause the preform to flow-form against the shaping member.

18. The method of Claim 17, wherein the preform also flow-forms against the workpiece and the metallurgical bonding of the preform to the workpiece is diffusion bonding.

19. The method of Claim 18, also including the step of heating the preform to within a temperature range suitable for flow-forming of the preform.