CA1146780A - Forging method and apparatus - Google Patents

Abstract

Forging Method and Apparatus Abstract The present invention provides methods and apparatus improving the dimensional accuracy of forged components.
Uniformity of like component details is sought and a specific object is to provide a die package for forming closely toleranced appendages integrally with a central disk structure from which the appendages extend.
In one effective embodiment incorporating concepts of the present invention, the forging dies include a station-ary die and a movable die comprising at least two separately movable elements which are mounted on a common axis with the stationary die. A plurality of arcuate die segments are adjacently placed in cylindrical array about the stationary and movable dies. The arcuate die segments form cavities of the inverse geometry of the appendages to be formed and in at least one embodiment are interlocked to prevent tilting of the segments in the die package.
The movable die elements are sequenceable to form a billet of material into a workpiece having an intermediate configuration, and subsequently into a workpiece of final configuration. In at least one embodiment, pressure pads are disposed against one of the movable dies to prevent displacement of that die by the billet material as the intermediate configuration is formed.

Description

This application is a divi~ion of Canadian patent application serial no. 36 2, 8g7 filed October 21, 1980.

Technical Field This invention relates to forging methods and appara-tus, and particularly to such methods and apparatus bywhich a billet of high strength, low ductility metal alloy is forged to a desired configuration under temporary conditions of low strength and high ductility.
The concepts were developed in the gas turbine engine field for the production of integrally bladed rotors, but havè very wide applicability in any industry in which complexly configured parts of accurate dimension are desired. -Background Art U. S. Patent 3,519,503 to Moore et al entitled "Fabrication Method for the High Temperature Alloys", of common assignee herewith, describes a forging process developed by Pratt & Whitney Aircraft, Division of United Technologies Corporation, ~artford, Connecticut and known internationally as the GATORIZII~G~ forging process. By the disclosed process, high strength, difficult to forge alloys such as those used in the gas turbine engine indus-' try, are defo~mable from a billet of stock material to a nearly finished shape of relatively complex geometry.
Although, only disk-shaped components were initially forged, the attractiveness of forming integrally bladed rotor disks spurred subseguent developments.
An initial die package and process for forming such integrally bladed rotors is disclosed and illustrated in 30 U. S. patent 4,051,708 ~o Beane et al entitled "Forging Method" and in the divisional case thereof U. S~ patent 4,074,559 to Beane et al also entitled "Forging Methodn.
Both patents are of common assignee herewith. In accor-F-45'7 : -2-dance with these concepts, integral appendages are forged between a plurality of adjacent dies positioned about the circumference of the disk forming dies. Yet further advances include the techniques for separating the appen-daye forming dies from the finished forging. Two suchtechniques are illustrated in U. S. patents 4,041,161 to Kelch entitled "Apparatu.s and Method for Removing a Plurality of Blade Dies" and 4,150,557 to Walker et al entitled "Forging Apparatus Having Means for Radially Moving Blade Die Segmentsn.
Notwithstanding the above stated advances in the forging field, scientists and engineers continue to search for new concepts and techniques which enhànce the manu-facturability of forged components an~ improve the guality -~ 15 of such components.

Disclosure of the Invention According to the present invention a single die set comprises a plurality of automatically sequenceable die elements including a first element for deforming a preform metal billet under conditions of low strength and high ductility to a preferred intermediate shape and a second element for deforming said intermediary piece at retained conditions of low strength and high ductility to a desired finished shape.
According to the method taught a metal billet of high strength, low ductility metal alloy is processed to a condition of low strength, high ductility within a set of sequenceable di~ elements, and is deformed under pressure within the set of sequenceable elements to a first con-figuration and without being removed from the die to a second configuration.
A primary feature of the present invention is the movable die. The movable die is formed of at least two sequenceable elements. In the embodiment illustrated a central disk and outer ring are employed. The dies are driven in sequence to form the billet to a first con-~7~3~

figuration and thence to a second con~iguration without withdrawing the press from the die package. A plurality of pressure pins extend downwardly from a spider plate to prevent displacement of the outer ring as the central disk is pressed into the billet being formed.
A principal advantage of the present invention is the enhanced ability to form components of complex geometry. Billet material is formed to a first configur-ation during an initial step to provide for improved dis-tribution of material in a subsequent step. Intricateappendages, such as rotor blades of gas turbine engines, are formable to accurate dimension and contour at the per-iphery of a supporting structure. Forming the billet to an intermediate configuration with preferred material distribution, enables the effective subsequent redistrib-ution of material in later steps to appendages of complex shape. Effective sequencing of the die package is enabled by initially restraining the dies to be later pressed into the billet material. The later sequenced dies form a portion of the mold in earlier steps wherein billet material is moved to preferred locations in the inter-mediate configuration.
In accordance with a particular embodiment of the invention there is provided, in forging apparatus of the type adapted for use with a die package having two or more movable die elements mounted on a common axis and in which the elements are operable in sequence to form at least one intermediate workpiece configuration prior to the final workpiece configuration, an improvement.
The improvement includes a die column opposing the movable die elements which has an element opposing surface adapted to sequentially apply a forging pressure against a first of the movable die elements to form the intermediate - 3a -workpiece configu~ation, and thence against a second of the movable die elements to form the final workpiece configuration. Means are provided for preventing dis-placement of the second die element by the workpiece as the first die element is pressed against the work-piece.
From a different aspect, and in accordance with the invention, there is provided a method for forging a component having a central disk region and a plurality of integrally formed appendages extending therefrom. The method includes the steps of disp~sing a cylindrical array of adjacent die segments, having side walls con-toured to the inverse geometry of the appendage to be formed, about a stationary end die. A billet of material from which a workpiece is to be formed is placed upon the stationary die within the cylindrical array, and a movable end die, having a central element and a ring circumscribing the central element, is placed upon the billet within the cylindrical array. The temperature of the billet and the dies is raised to the temperature at which the component is to be forged, and pressure pads are placed against the ring circumscribing the central element of the movable die to prevent displacement of the ring by the billet as the central element is pressed against the billet. The central element of the movable die is pressed at the for-ging temperature into the billet to form a workpiece hav-ing an intermediate configuration. The workpiece and die are maintained at the forging temperature and the ring of the movable die is pressed at the forging temperature into the workpiece to form the workpiece into a final config-uration.

7i~

- 3b -The foregoing, and other features and advantages of the present invention, will become more apparent in the light of the following description and accompany drawing.
Brief Description of the Drawing Fig. 1 is a schematic representation of forging apparatus in which the concepts of the present invention are employable, Fig. 2 is a cross section view through a portion of the Fig. 1 apparatus showing a bil~et containing die package in the press prior to commencement of the forging sequence, Fig. 3 is a cross section view corresponding to Fig. 2 wherein the billet has been forged to a first configura-i'7~

tion by pressing the cen~ral disX into the billet; and Fig. 4 is a cross section view corresponding to Fig.

2 wherein the billet has been forged to a second and final configuration by pressing the outer ring into the billet.

Detailed Description The methods and apparatus of the present invention are known to have high utility in the forging field, and particularly in the forging of components having complex geometries by the techniques described in ~. S. patent

3,519,503 to Moore et al entitled "Fabrication Method for the High Temperature Alloysn. The Moore et al process is well suited to automated manufacture such as that illus-trated in the Fig. 1 simplified representation of auto-mated forging apparatus. Within the apparatus a high strength, low ductility material is processed to a temporary state of low strength, high ductility so as to enable the flow of billet material into die cavities of intricate contours or complex shape during the forging process.
Subsequent to the forging operation, the finished work-piece is heat-treated to restore the material to its former conditions of high strength and low ductility.
The forging process is performed within a containment vessel 10 under a hydraulic press 12. The press has a bed 14 and a head 16 which are spaced apart by a plurality of ( 25 tie rods 18. The containment vessel is supported by structure 20 extending upwardly from the press bed. The upper end of the containment vessel is joined to the press head at a bellows 2~.
A ram plate 24 within the press bed 14 supports a lower die column 26 within the containment vessel 10. The ram plate is movable with respect to the containment vessel and is joined thereto by a bellows 28. A plurality of forging rams 30 position the plate and move the plate upwardly with great force during the forging process. The - 35 forging rams are movable by a hydraulic actuator not shown. A plurality of ram stops 32 extend upwardly from '7~3~

the ram plate to limit upward travel of the plate during the forging process. An upper die column 34 extends down-wardly from the press bed into the containment vessel.
Both the upper die column 34 and the lower die column 26 are made up of a plurality of flat plates 36. The top plate 38 of the lower die column and the bottom plate 40 of the upper die column are manu~acture of a low thermal conductivity material, such as molybdenum. A bull ring 42 also of low thermal conductivity material, such as molyb-denum, rests atop the plate 38 of the lower die. A diepackage 44 is positionable within the bull ring. The bottom plate of the upper die column rests atop the die package with a die opposing sur~acè facing the movable elements of the die package. A breakout ram 45 extends upwardly through the lower die column and the bull ring ~ from an actuator 48.
The containment vessel 10 is divided into three (3) isolatable chambers: a preheat chamber 50, a forging chamber 52, and a cool-down chamber 54. An entry door 56 separates the forging chamber from the preheat chamber and an exit dovr 58 separates the forging chamber from the cool-down chamber.
The preheat chamber 50 has a valve 60 through which the pressure and the atmosphere in the preheat chamber is controllable. A loading door 62 provides access to the ( preheat chamber for the placement of die packases 44 into the containment vessel. A preheater table 64 at the end of a preheater arm 66 supports each die package in the preheater section. A heating element 68 is provided at a preheating station 70 within the chamber. The preheater table and arm are adapted for vertical travel through the preheater chamber for raising each die package to and through the heating element. In a typical embodiment the preheater arm extends upwardly from a hydraulic actuator which is not shown in the drawing. Above the heating element a loading tray 72 at the end of a loading arm 74 is adapted for horizontal movement across the preheater chamber. With the preheater table in a raised position, the loading tray is capable of receiving the die package from the preheater table. With the preheater tray in a retracted position the loading tray and loading arm are capable of shuttling the die package into the forging chamber. Horizontal movement of the loading tray and loading arm in a typical embodiment is provided by a hydraulic actuator which is not shown in the drawing.
The forging chamber 52 has a valve 76 through which the pressure and the atmosphere in the forging chamber is controllable. A heating element 78 is provided at a forging station 80 within the chamber. The heating ele-ment is split into an upper heating element 82 and a lower heating element 84. The two heating elements are vertically separable to allow access to the bull ring 42 atop the lower die column 26. With the heating elements separated and the lower die column retracted with the ram plate 24, the breakout ram is capable of lifting the die package 44 from the extended loading tray 72 and lowering the die package into the bull ring for forging. In a like manner with the forging operation complete, the ram plate is retractable and the breakout ram is extendable to raise the die package out of the bull ring.
The cool-down chamber 54 has a valve 86 through which the pressure and the atmosphere in the cool-down chamber ( ~ is controllable. An unloading tray 88 at the end of an unloading arm 90 is adapted for horizontal movement across the cool-down chamber. The unloading tray and arm are extendable into the forging-chamber 52 for receiving a die package 44 from the breakout ram 46. The cool-down cham-ber has a die expansion station 92 and a cooldown station 94. The die expansion station has an upper expansion ring 96 and a lower expansion ring 98. An expander arm 100 extending upwardly from a hydraulic actuator 102 raises the lower expansion ring upwardly to lift a die package off of the unloading tray. The actuator further urges the rings together to cause the elements of the die package to break away from the forged workpiece. An unloading door 104 provides access to the cool-down chamber for the removal of die packages.
A die package 44 constructed in accordance with the concepts of the present invention is illustrated by Fig.
2. The di~ package includes a stationary die 106 of generally cylindrical geometry having an outer surface 108 and at least two movable dies, such as the first movable die, or central disk 110 and the second movable die, or ring 112. The first and second movable dies are mounted on a common axis with the stationary die 106. The second movable die has a generally cylindrical geometry with an outer surface 114. The second movable die is contained within the first movable die. The movable dies have end surfaces 116 which in composite are contoured to the inverse geometry of one side of the component to be formed.
The stationary die has an end surface 118 contoured to the inverse geometry of the other side of the component to be formed.
A circumferentially extending collar 120 is raised outwardly from the cylindrical outer surface of the sta-tionary die~ A billet of material 122 from which the workpiece is to be forged is contained between the station-ary and movable dies. A plurality of arcuate die segments 124 are adjacently placed in cylindrical array about the ( stationary and movable dies, and form in conjunction therewith a cavity having the inverse geometry of the desired component including appendages where appropriate.
Each of the die segments 124 has a pair of circum-ferential side walls 126 which are contoured to form, in conjunction with the side walls o~ the adjacent segments, a plurality of circumferentially spaced cavities having the inverse geometry of the appendages to be formed. Each segment has an inner arcuate sur~ace 128 including a channel 130 extending thereacross ~hich interlocks with the collar 120 of the stationary die to prevent tilting of each segment with respect to the stationary die. The 7~

collar has at least one tapered side surface 132 which enables withdrawal of the die segments from the collar along a desired line of pull (L) from the appendages.
In a more detailed die package also illustrated in Fig. 2, the inner arcuate surface 128 of each segment 124 includes a second channel 134 in the region of the movable die 110. Each channel 134 interlocks with a ring 136 of closely dimensioned tolerance therewith to provide addi-tional resistance to segment tilting. As is the case with the collar the ring has a tapered side surface 138 which enables withdrawal of the segments from the ring along the desired line of pull ~L). The collar and ring concepts may be used independently or in combination.
Each die segment 124 further has an outer arcuate surface 140 having a groove 142 extending thereacross to form in composite with the grooves of the adjacent seg-ments, an outer channel which extends fully around the cylindrical array. A wire 144 extends within the outer channel about the die segments to hold the elements of the die package in a unitized assem~ly.
Also illustrated in Fig. 2 is apparatus contained within the upper die column 34 for preventing displacement of the first die element by the workpiece as said second die element is pressed against the workpiece. The appara~
tus incl~ldes a plurality of pressure pads 146 extending ~ downwardly from a spider plate 148 onto the first die element. A common rod, or ram 150 positions the spider plate. The ram is moved by a hy~raulic actuator at the top of the press which is not shown.
The forging method claimed herein is illustrated by the related Figs. 2-4. In Fig. 2 the array of die seg-ments 124 is first disposed about the stationary die 106.
The wire 144 is placed in the groove 142 and tightened to hold the segments 124 in place. The billet 122 of material from which the workpiece is to be formed is placed upon the stationary die within the cylindrical array and the movable die containing the central element 112 and the 7~3~
. ~
g ring 110 is placed upon the billet within the cylindrical array to complete the die package.
The die package is placed in a forging chamber such as that illustrated by Fig. l and raised in temperature to place the billet material in a temporary condition of low strength, high ductility. Pressure pads 146 are placed against the first movable die or ring 110.
As illustrated by Fig. 3, the second movable die or central die element 112 is pressed into the billet 122 to form a workpiece to an intermediate configuration. The pressure pads prevent displacement of the ring 110 by the flowing billet material. In the configuration the work-piece has billet material distributed to a preferred region for subsequent forging. For example, in the region CJ 15 R material is collected for subsequent pressing into the airfoil cavities between adjacent die segments.
In the Fig. 4 illustration, the pressure on the pads 146 has been relieved or overridden by the force of the rising ram plate 24. The first movable die or ring 110 - 20 and the second movable die 112 are pressed simultaneously into the billet. The pocket of ~aterial in the xegion R
is ~orced fully to the ends of the appendage forming cavi-ties between adjacent segments thus forming the workpiece to the second, or final configuration~
Although the invention has been shown and described with respect to detailed embodiments thereof, it should be understood by those skilled in the art that various changes and omissions in form and detail may be made therein without departing from the spirit and the scope of the invention.

Claims (4)

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:-

1. In forging apparatus of the type adapted for use with a die package having two or more movable die elements mounted on a common axis and in which said elements are operable in sequence to form at least one intermediate workpiece configuration prior to a final work-piece configuration, the improvement comprising:
a die column opposing said movable die elements which has an element opposing surface adapted to sequen-tially apply a forging pressure against a first of said movable die elements to form the intermediate workpiece configuration, and thence against a second of said movable die elements to form the final workpiece configuration, and means for preventing displacement of said second die element by the workpiece as said first die element is pressed against the workpiece.

2. The invention according to claim 1 wherein said means for preventing displacement of the second die ele-ment comprises a plurality of pressure pads operatively dis-posable against the second die element as the first ele-ment is pressed against the workpiece.

3. The invention according to claim 2 wherein said means for preventing displacement of the second die ele-ment further comprises a pressure plate to which said pressure pads are attached and connector rod which is hydraulically operable to bring said pads against the second die element.

4. A method for forging a component having a central disk region and a plurality of integrally formed appen-dages extending therefrom, comprising the steps of:
disposing a cylindrical array of adjacent die segments, having side walls contoured to the inverse geo-metry of the appendages to be formed, about a stationary end die;
placing a billet of material from which a work-piece is to be formed upon the stationary die within the cylindrical array;
placing a movable end die having a central ele-ment and a ring circumscribing the central element upon the billet within the cylindrical array;
raising the temperature of the billet and of the dies to the temperature at which the component is to be forged;
placing pressure pads against the ring circum-scribing the central element of the movable die to prevent displacement of the ring by the billet as the central element is pressed against the billet;
pressing the central element of the movable die at the forging temperature into the billet to form a workpiece having an intermediate configuration;
maintaining the workpiece and die at the forging temperature; and pressing the ring of the movable die at the for-ging temperature into the workpiece to form the workpiece into a final configuration.