The present invention relates to a forging press and system for forming a part by flow forging a metal workpiece under the application of continuous pressure.
Conventional flow forging is currently practiced using a very large forging press, which can be as tall as 50 feet above ground level and rated at upwards of 50,000 tons, in conjunction with a matched male and female die system. One major disadvantage of a conventional forging press is the need, following forging, to further machine the forged part into a finished product. Conventional flow forging results in a substantial amount of flash removal and the requirement for machining following forging typically results in a substantial amount of scrap waste. A second major disadvantage of a conventional forging press is the necessity to construct a deep foundation extending as much as 70 feet underneath the forging press to enable the press to apply the desired pressure.
A part forming apparatus for forging a large part from a workpiece in a precise manner is taught and described in U.S. Pat. Nos. 4,608,848 and 4,770,020, which issued to the inventor of the subject application. The disclosures from both of the aforementioned patents are incorporated herein, in their entirety, by reference. The part forming apparatus taught in the foregoing patents constitutes a pressure transforming apparatus which creates a pressure zone for gradually forging the workpiece under pressure into a finished product. The workpiece is transported from from a die assembly and guided by a roller conveyor through the pressure zone of the part transforming apparatus in a given transport direction with the die assembly being pulled by a hydraulically operated drive mechanism. The roller conveyor is attached to a cable which is secured, in turn, through a pulley attached by brackets to a frame. The frame supports a pressure unit above a base member upon which the drive mechanism transporting the die assembly is mounted. A release station is used to release the die after passing through the pressure zone.
The subject invention constitutes a substantial improvement of the part forming apparatus taught in the aforementioned patents of the subject inventor in the construction of the forging press and in the system of the subject invention. The subject invention controls the build up of pressure generated between a male and female die as the die assembly is passed through the forging press to produce a finished part with no flashing.
The forging press and system of the present invention is less expensive to build, operate and maintain compared to conventional pressure forging presses in current use and compared to the part forming apparatus taught in the earlier aforementioned patents of the inventor of the subject invention. Moreover, the forging press and system of the present invention can be mounted at ground level without the necessity to construct a foundation below ground level to support the forging press. In addition, the forging press of the subject invention can forge metal parts free of voids, flaws and overlaps and without creating flash and/or waste. Accordingly, no machining of the forged part is necessary following the forging operation. Furthermore, the forging press and system of the present invention is able to fabricate a forged part of any desired length and is capable of forging longer parts than heretofore possible using conventional pressure forging systems.
The forging press of the present invention is an integrated unit for flow forging a metal workpiece into a shaped part under the application of continuous pressure comprising: a support frame having a central opening forming an upper frame section, a lower frame section and side sections, an upper platen adapted to be suspended vertically from the upper frame section of the support frame, a lower platen extending from the lower frame section at a location spaced apart from the upper platen, a shoulder extending from each opposite side of the upper platen adjacent each side section of the support frame respectively, a wedge assembly including a first and second wedge member mounted in sliding engagement upon each shoulder of the upper platen at a position disposed between the upper platen and the upper frame section, with the first and second wedge members each having an inclined surface on one side thereof adapted to engage the upper frame section, an end support member interconnecting the first and second wedge members at a location external of the support frame; a first endless roller assembly surrounding the upper platen in a continuous loop; a second endless roller assembly surrounding the lower platen in a continuous loop with the first endless roller assembly facing the second endless roller assembly in substantial parallel alignment; and a motorized worm gear assembly for controllably moving said wedge assembly in or out of the central opening of the support frame to cause the first and second wedge members to slide upon the shoulders of the upper platen for moving the upper platen in a direction relative to the lower platen such that when a metal workpiece is transported in a die assembly between the first and second endless roller assembly during operation of the forging press the workpiece is compressed at a controlled pressure between the upper and lower platens.
The system of the present invention for flow forging a metal workpiece into a shaped part under the application of continuous pressure comprises in combination; a heating station for preheating the metal workpiece, a die assembly, including a male die composed of a plurality of male die segments and a female die, a forging press and a trailing assembly, with the trailing assembly including an hydraulically operated piston drive assembly for transporting the die assembly and heated workpiece from the heating station through the forging press, wherein the forging press comprises: a support frame having an upper frame section, a lower frame section and side sections, an upper platen adapted to be suspended from the upper frame section of the support frame with the upper platen having a tapered inclined surface at least on one end thereof, a lower platen extending from the lower frame section at a location spaced apart and in parallel alignment to the upper platen, a wedge assembly mounted upon the upper platen in sliding engagement between the upper platen and the upper frame section, an endless roller assembly surrounding the upper platen with the endless roller forming a continuous loop about the upper platen; and a motorized worm gear assembly for controllably moving said wedge assembly so that the upper platen moves in a direction relative to the lower platen for controlling the pressure applied to the workpiece as the workpiece is moved with the die assembly in a transport direction between the upper and lower platen such that each of said plurality male die segments is pressed gradually and sequentially against the workpiece into the female die as the die assembly moves through the press.
Referring to the drawings, the forging press 10 of the present invention is shown in
The forging press 10 of the present invention is shown in perspective and in greater detail in
The forging press 10 along with the heating furnace 11 and trailing assembly 13 of the present invention may be mounted on ground level or upon a reinforced concrete slab (not shown) mounted on ground level with the concrete slab providing additional support for the press 10 without the necessity to form a foundation under the forging press 10 below ground level.
The upper platen 27 is held suspended from the upper frame section 22 preferably in a vertical orientation using a plurality of spring members 31, as shown in
The upper platen 27, as is shown in
As shown in
The wedge assembly 40 comprises a first wedge member 44 and a second wedge member 45 with the wedge members 44 and 45 interconnected to one another by an end support member 46 to form a horseshoe configuration. Each of the first and second wedge members 44 and 45 have an inclined surface 47 and 49 on one side thereof opposite the two shoulder sections 36 and 37 upon which the wedge members 44 and 45 are mounted. The inclined surfaces 47 and 49 of the wedge members 44 and 45 are disposed in sliding engagement against opposing surfaces (not shown) of the upper section 22 of the support frame 20 such that as the wedge assembly 40 is linearly moved in or out of the central opening 21 of the support frame 20 the upper platen 27 moves downwardly or upwardly relative to the position of the stationary lower platen 28. The end support member 46 interconnects the first and second wedge members 44 and 45 at a location external of the support frame 12. An elongated lead screw 48 extends through the upper section 22 of the support frame 20. The lead screw 48 is connected to a worm gear assembly 50, driven by a motor 51, preferably a stepping motor, with both the worm gear assembly 50 and the stepping motor 51 mounted on the end support member 46 of the wedge assembly 40. The worm gear assembly 50 is conventional and turns the lead screw 48 in a clockwise or counterclockwise direction upon manual or automatic operation of the stepping motor 51. The stepping motor 51 is operated either independent or in syncronism with the operation of the hydraulically operated piston drive unit 14 for controlling the pressure applied to the workpiece 15 as the workpiece 15 is advanced through the forging press 10.
The lead screw 48 is rotated by operation of the stepping motor 51 to cause the wedge assembly 40 to move laterally in a stepwise fashion through the central opening 21 of the support frame. When the lead screw 48 is rotated clockwise. the upper platen 27 moves downwardly toward the lower platen 28. The workpiece 15 is transported in the die assembly 12 through the forging press 10 between the upper platen 27 and the lower platen 28. When the die assembly 12 is pulled through the forging press 10 to the male die 17 engages the first endless roller chain assembly 3 causing the first endless roller chain assembly 3 to rotate about the upper platen relative to the second endless roller chain assembly 4 which compresses the workpiece 15 as the workpiece 15 passes between the upper platen 27 and the lower platen 28. The pressure applied to the workpiece 15 while the workpiece 15 is pulled through the forging press is controlled by the movement of the wedge assembly 40.
A diagrammatic view in side elevation of the die assembly 12 as it is being pulled by the hydraulically operated piston drive unit 14 between the upper and lower platen of the forging press 10 is shown in
The first endless roller chain assembly 3 engages the upper surface 61 of each of the male segments 18 as it rotates around the upper platen 27 in response to the advancement of the die assembly 12 through the forging press 10 causing each male segment 18 to be pressed sequentially into the female die cavity 60 of the female die 19. The lower surfaces 62 of each of the male segments 18 constitutes a molding surface which actually comes into direct contact with the plate stock 65 for forging the workpiece 15 or contacts the plate stock 65 through a cover plate 66 placed between the plate stock 65 and the lower surfaces 62 of the male segments 18. The die assembly 12 is either being pulled in a transport direction from left to right through the forging press 10 as is shown in
The die assembly 12 may also be pushed in a transport direction through the forging press 10 in the direction opposite the pulling direction shown in
The hydraulically operated piston drive unit 14 in the trailing assembly 13 shown in
Upon withdrawal of the die assembly 12 from the forging press 10 the male die segments 18 may be individually released to lift the male segments 18 out from the female die 19 as taught in U.S. Pat. No. 4,608,848 the disclosure of which has been incorporated by reference before removal of the forged workpiece 15. After the forged workpiece 15 is removed from the female die 19 the male die segments 18 are lowered back into the female die and the die assembly 12 moved back through the forging press 10 to enable the die assembly 12 to be reloaded with new plate stock 65 before or in the heating assembly 11 to begin the forging procedure anew.
Number | Name | Date | Kind |
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3626746 | Pietryka | Dec 1971 | A |
3847004 | Bringewald | Nov 1974 | A |
4608848 | Mele | Sep 1986 | A |
4770020 | Mele | Sep 1988 | A |
8779620 | Mele | Jul 2014 | B1 |
20140090443 | Schmauder | Apr 2014 | A1 |