This invention relates to cold forging apparatus for forming complex articles and more particularly to cold forging apparatus for performing multiple functions at a single station. It also relates to a conveyor or loader/unloader for such apparatus.
Cold forging apparatus and processes are well-known. Such apparatus and processes have been used for many years in the commercial production of relatively simple parts at a single station or more complex parts with a multi station set up. However, for more complex parts, the use of a multi station process requires duplication of equipment, additional set-up time, additional space, multiple dies and additional costs. Such costs are particularly excessive for making a limited numbers of forged parts.
More complex parts may also be forged in a machine such as an automatic forging press or cam operated cold header. In such machines, parts are transferred through a variety of stationary die sets, each of which includes a punch. Such machines are capable of operating at high speeds, but are complex, expensive and require considerable set-up time before each run. Accordingly, the use of such machines is generally limited to high volume items where the length of the run justifies the set-up time. The use of such machines is also generally limited to parts which have sufficient complexity and sufficient market value to justify the costs of the machine, set-up time and other operating costs.
In our earlier application Ser. No. 10/291,361 which was filed on Nov. 12, 2002, we disclosed a cold forming apparatus for forming complex shapes at a single station. As disclosed therein, the apparatus includes a multi-function punch assembly including an inner and outer punch disposed on a common axis and a third punch in a confronting relationship with the first punch assembly. The apparatus also includes a die and a die holder for positioning a mass of metal or slug between the punches. A computer system controls movement of the punches and is programmable to form parts of different shapes at a single station.
It is now believed that there is a commercial market and need for an improved cold forging apparatus in accordance with the present invention. The reason for such demand is that such apparatus offer numerous advantages, for example, such apparatus are capable of forming complex shapes at a single station. Further, the apparatus requires less space and in some cases fewer operators than multiple machines each of which performs a single step in the production of a complex part. The apparatus as disclosed herein also require less set-up time which enables an operator to produce shorter runs at economical costs. This is because fewer stations and less tooling results in lower production costs, particularly in those cases involving smaller volumes of parts. A further advantages resides in a conveyor or loader/unloader for automatically or semi-automatically transferring a metal work piece or metal slug from a supply area to a loading/unloading area between the punches in a cold forging apparatus. The loader/unloader is also adapted to pick up a forged product from a loading/unloading area and unloading the forged product into a storage area or tray. Also, the loader/unloader in accordance with the present invention is adaptable for loading and unloading different apparatus.
A further advantage of the apparatus of the present invention resides in the use of multiple machines which includes conveyors in accordance with the present invention. Such machines may be slower than the aforementioned cam operated cold headers, but provide greater flexibility and backup in the event of a machine failure or down time for a more complex machine. In addition, cold forging apparatus in accordance with the present invention can be produced and sold at a competitive price. For example, it is presently estimated that the cost of a cold forging apparatus in accordance with the present invention is less than 25% of the cost of an automatic cam operated forging press. A still further advantage resides in the use of a computer program in conjunction with multiple sets of punches at a single station. It is also believed that the apparatus in accordance with the present invention will be less complex, less expensive to install, operate and maintain and more reliable than the automatic cam operated cold headers of the prior art. Recognizing, that the prior art automatic cam operated cold headers are capable of relatively fast speeds, it is believed that the use of two, three or more machines in accordance with the present invention will be capable of matching those speeds while providing many of the aforementioned advantages including costs and added flexibility.
In essence, the present invention contemplates a conveyor or loader/unloader for conveying a metal work piece or slug from a supply source to a loading/unloading position between a die and a punch in a forging apparatus. The conveyor or loader/unloader is also adapted to convey a forged or finished product from the loading/unloading position to a storage area or tray. The conveyor or loader/unloader includes a pivot assembly and a moveable robot arm having an end effector fixed to one end thereof and an opposite end attached to the pivot assembly for movement about a first axis. In addition, the loader/unloader includes a servo actuator and a crank arm which is connected at one end thereof to the servo actuator and at an opposite end to the pivot assembly for rotating the robot arm through an arc about the first axis in response to movement of the servo actuator means for controlling movement of the servo actuator are also provided.
The end effector in accordance with the present invention includes first and second carrier elements or grips with the first element attached to or preferably rigidly fixed to one end of the robot arm. The second carrier element or grip is pivotally connected to the first carrier element for movement or rotation about a second axis. Further, the first and second carrier are adapted to receive a work piece slidably engaged therein when in a normal or closed position.
The second of the carrier elements or grips also includes an upper concave portion or surface which is adapted to receive a forged or final product thereon when in its normal position and an outwardly extending finger. An unloading actuator or pin is provided for engaging the outwardly extending finger as the robot arm rotates about the first axis to tilt the second element and drop a forged product into a storage tray or the like. Means are also provided for returning the second carrier element to its closed or work piece receiving position as the robot arm is returned to a neutral position or work piece loading position.
A preferred embodiment of the invention contemplates a cold forging apparatus for performing multiple functions at a single station to form complex shapes. The apparatus includes a first multiple punch assembly including a first inner punch and a first outer punch which are moveable along a common axis with respect to one another. It also includes a third moveable punch which is moveable along a second axis which intersects with the first common axis or along the first axis. Means are also provided for moving the punches individually along their respective axes. The apparatus in accordance with the preferred embodiment of the invention also includes means such as a die holder or press for positioning a die between the first multiple function punch assembly and the third punch. A programmable logic control, multi axis controller and a feed back device for controlling movement of the punches are also provided. Further, the apparatus includes a loading/unloading position between the first multiple punch assembly and the third punch and a conveyor or loader/unloader for conveying a metal work piece or slug from a supply area to the loading/unloading position and for conveying a forged product from the loading/unloading position to a storage area or tray. In this embodiment of the invention, the movement of the conveyor or loader/unloader is controlled by the feed back device and the work piece is moved into the die by one of the punches. One of the punches is also used to move a forged product out of the die and onto the second carrier element by one of the punches. The invention will now be described in connection with the following figures wherein like reference numerals have been used to designate like parts.
a is a front elevational view of a loader/unloader in accordance with the invention wherein the loader/unloader is positioned for receiving a metal work piece into an end extender;
b is a top view of the loader/unloader shown in
The apparatus also includes a third punch which moves independently of the first inner punch 10 and first outer punch 12 along an axis that intersects the common axis of the first inner punch 10 and first outer punch 12. However, in one preferred embodiment of the invention, the third punch is replaced by a second multiple punch assembly.
The second multiple punch assembly is similar to the first multiple punch assembly and includes a second inner or central punch 20 and a second outer punch 22 disposed on a common axis in a telescoping relationship. The punches 20 and 22 are like the punches 10 and 12 separately controllable and free to move independently along the common axis. The punches 20 and 22 also include enlarged end portions or driving elements 21 and 23, respectively, at one end thereof for applying force to each of the punches. The opposite ends of the punches 20 and 22 are shown within a die 14.
A cold forging apparatus in accordance with one embodiment of the invention is illustrated in
The apparatus in accordance with the invention also includes hydraulic cylinders 30 and 31 which are outside of the press frame at opposite ends thereof and which are held to the bolster plates 32 and 33 by the bolts 34, 34′, 35 and 35′, end caps 36 and 37 and a plurality of nuts in a conventional manner. Each of the hydraulic cylinders 30 and 31 is connected to a source of hydraulic pressure (not shown) by connectors 30′ and 31′.
The cylinders 30 and 31 drive cylinder rods 38 and 38′ along a common axis. The cylinder rods 38 and 38′ are connected to the center or inner punch 10 and 20, respectively, by any suitable connectors 39, 39′. The apparatus also includes a pair of cylinders 45, 45′ which are disposed within the press frame. These cylinder assemblies include forward and rear end caps 40, 41, forward end caps 40′, 41′ and tie rods 42, 42′, 43 and 43′. The cylinders 45 and 45′ are each connected to separate sources of hydraulic pressure (not shown) in a conventional manner. The cylinders 45, 45′ also include a center passageway or hole through which the cylinder rods 38 and 38′ pass.
The cylinders 45, 45′ each comprise a multi-ended cylinder assembly preferably a double ended rod assembly with a seal at each end and a hole or passageway drilled through the center of the rod. This hole or passageway allows the extension or rods 38 and 38′ to pass through the center of the rods. It is also contemplated that a second and third multi-ended cylinder rod could be used to allow for 3 or more axially nested punches for performing synchronous forming steps inside of a die.
The cylinders 30 shown in
As shown in
As illustrated in
The operation of the cold forging apparatus disclosed herein is illustrated in
The multi access controller 104 which is operatively connected to a hydraulic servo 105 to control movement of a pair of parallel die platen pistons in die platen cylinders 110 and 112. A second Tempasonic position feedback output device 114 is operably connected to the multi access controller 104 to convey feedback data to the controller 104.
The movement of the four punches 10, 12, 20 and 22 (
The data from the Tempasonic feedback devices 132, 134, 136 and 138, and pressure transducers 133, 135, 137, 139, 133′, 135′, 137′ and 139′ is transmitted to the programmable logic controller 102 by means of the LAN 101. The Tempasonic feedback devices and pressure transducers are conventional in design and are available from Miller Fluid Power of Bensenville, Ill.
Programming the movement of each of the punches is effective in producing complex shapes within a single die and also for changing the shapes of the forged parts to be formed. Such programs are well within the skill of a programmer with experience in forging parts based on the diagram as shown in
An improved conveyor or loader/unloader 200 in accordance with a preferred embodiment of the invention will now be described in connection with
An opposite end 216 of the J-shaped moveable robot arm 212 includes an end extender 220 having first and second carrier elements 222 and 224 or gripping members. The first carrier element is fixed to the end of the J-shaped robot arm 212 while the second carrier element 224 is pivotally connected to the first carrier element 222 for rotation about a second axis. The end connector 220 is constructed and arranged to receive the work piece 204 between the carrier elements 222 and 224.
The conveyor 200 also includes a servo actuator 230 which may be of conventional design and a crank arm 232 connected at one end thereof to the servo actuator 230. An opposite end of the crank arm is fixed to the end 214 of the J-shaped robot arm 212 through the pivot assembly for rotating the J-shaped robot arm 212 about the pivot assembly 210 in response to the movement of a piston (not shown) and a rod 211 of servo actuator 230. As illustrated, the servo actuator is mounted on the top of a central platen or die carrier 24 as for example, by a mounting bracket 233.
As shown in
In the operation of the loader/unloader, the J-shaped robot arm 212 is positioned for receiving a work piece 202 in a generally circular opening defined by the first and second carrier elements 222 and 224 as more clearly illustrated in
The robot arm 212 is then rotated about the pivot assembly 210 by means of the actuator 230 acting in response to a signal from a feed back device 231. The actuator 230 rotates the crank arm 232 to thereby rotate the robot arm 212 to move the end extender 220 along an arc shaped pathway (not shown) toward the loading/unloading position 204 as shown in
As illustrated, the pivot assembly 210 is mounted on the die carrier 24 above a rod or bar 26. The J-shape in the robot arm 212 allows the arm to move through its intended pathway without interference from the bar 26.
Following the deliver of a forged product 215 to the storage tray 238, the servo actuator 230 returns the robot arm 212 and end extender 220 to the loading/unloading position as shown in
While the invention has been described in connection with its preferred embodiment, it should be recognized that changes and modifications may be made therein without departing from the scope of the claims.
Number | Name | Date | Kind |
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2424075 | Brauchler | Jul 1947 | A |
2513710 | Brauchler | Jul 1950 | A |
3628368 | Cvacho et al. | Dec 1971 | A |
3824833 | Bachmann | Jul 1974 | A |
4644775 | Fuchs, Jr. | Feb 1987 | A |
6125683 | Toeniskoetter | Oct 2000 | A |
6192285 | Takayama | Feb 2001 | B1 |
Number | Date | Country |
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5-177291 | Jul 1993 | JP |
Number | Date | Country | |
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20050092052 A1 | May 2005 | US |