The present invention relates to a stamping system.
Stamping system are known and used in the automotive industry to stamp and form various substrates or blanks into body panels for motor vehicles. In this regard, there are different-sized stamping systems that are used to form different-sized body panels. Some stamping systems, however, are not as efficient (i.e., produce to much blank material) as other stamping systems. This waste in material is not cost effective.
That is, known stamping systems generally produce a large amount of scrap metal. Although this scrap metal may be recycled, the re-sale value of the scrap metal is well below the initial retail cost of the metal blanks. Accordingly, there is a need to improve the efficiency of stamping systems by either reducing or utilizing the amount of scrap metal produced during a stamping operation, as well as increasing productivity of under-utilized stamping systems.
The present teachings provide a stamping system comprising a press system including a plurality of bolsters, and a chute system disposed below the press system. The chute system communicates with the press system via a plurality of through-holes formed in the bolsters. In this manner, parts manufactured using the press system may pass through the bolsters into the chute system.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:
The following description is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
Stamping system 10 is a large manufacturing device typically used in a manufacturing or assembly plant or factory, wherein the press system 12 is located on the main floor of the plant, while the chute system 14 is disposed below the press system 12 in a basement or lower level of the plant. Press system 12 includes transfer mechanisms 16 that are disposed between an upper press 18 and at least one base member or bolster 20. Bolster 20 generally supports a lower die 22 (see
Press system 12 may be any type of press system known to one skilled in the art. In this regard, various types of press systems include a tri-axes press system, a tandem press system, a cross-bar press system, a hand-line system, open-back incline (OBI) system, an in-line stamping system, and a progressive stamping system. These press systems are generally distinguishable by the type of transfer mechanisms 16 used to transfer substrates or blanks from one bolster 20 to another. Regardless, the present teachings are equally applicable to any of these types of press systems.
The press system 12 shown in
The chute system 14 of the present teachings will be described in more detail. As illustrated in
For example, as shown in
After the blank has been formed at the forming station 20a, the blank is transferred to the next station 20b. In
In accordance with the present teachings, at least one of the stations 20 is equipped with a lower die 22 supported thereon that is capable of forming various parts. Specifically, a referring to
More particularly, once the parts are formed and cut by compression of the blank between the upper die 18 and lower die 22, the parts are free to be disposed of through the through-holes 28 formed in the bolster 20 and into the chute system 14. To protect the parts from damage as the parts travel through the chute system 14, the chute system 14 is configured to include a plurality of baffles 40. Baffles 40 are necessary because, as stated above, the chute system 14 is generally disposed beneath the press system 12 in the basement or lower level of the stamping plant. The distance that a part may fall from the press system 12, therefore, can be up to, and sometimes greater than, twenty feet. The baffles 40 slow and cushion the travel of the parts through the chute system 14. Although only a single chute system 14 is shown, it should by understood that each station 20 may be in communication with a chute system 14.
The baffles 40 are angled such that the parts will slide down the baffles 40 in a back-and-forth manner through the chute system 14. The baffles 40 are also spaced from each other at a distance sufficient to prevent damage of the parts as they travel through the chute system 14. In this regard, the baffles 40 should also be spaced at a distance sufficient to allow the parts to travel through the chute system 14 without becoming stuck or lodged in the chute system 14.
Preferably, the baffles 40 are spaced between one and two feet apart. It should be understood, however, that the present teachings are adaptable to produce different parts having different and larger dimensions. Accordingly, the baffles 40 may be spaced apart to accommodate any size desired. Regardless, to further protect against parts becoming stuck in the baffles 40, chute system 14 may be provided with an observation system including various cameras 42 to monitor and make sure the chute system 14 remains clear. Further, various doors (not shown) may be used to access the chute system 14 to remove parts that may become lodged in the chute 14.
Another alternative includes having the baffles 40 linked together to form a purge system. In this regard, the baffles 40 may be linked together or enabled to pivot in a manner such that when the chute system 14 needs to be purged of a part that has become lodged in the chute system 14, the baffles 40 may be rotated to a substantially vertical position that enables the blockage to fall to the bottom of the chute system 14.
Once the part reaches the bottom, the parts will be guided to either a crate or some other type of storage receptacle. In this regard, the chute system 14 may include deflector devices 44 that are actuated by an air cylinder 46 or some other type of actuating device. The deflector device 44 actuate a deflector plate 48 between a first position and a second position such that a first passageway 50 or second passageway 52 is opened. In the first position, the parts may be deflected to either a storage receptacle or onto a conveyor system 54 (
Because the chute system 14 includes deflector devices 44, it should be understood that the chute system 14 may be used for purposes other than to safely direct manufactured parts. More specifically, if parts are not being manufactured using the press system 12, the chute system 14 may alternatively be used to dispose of scrap metal pieces that are formed during the stamping process. To enable the chute system 14 to dispose of scrap metal, the deflector devices 44 are actuated to the second position that enables the second passageway 52 to open. In this manner, the scrap metal traveling through the chute system 14 may be directed to a scrap metal storage receptacle or to the conveyor system 56.
Regardless whether the scrap metal is directed to a storage receptacle or to one of the conveyor systems 54 and 56, it should be understood that the present teachings provide for a chute system 14 that is switchable between a mode that directs parts manufactured with press system 12, and a mode that directs scrap metal produced during operation of the press system 12. This may be accomplished by using deflector devices 44 that actuate deflector plates 46 to open and close the first and second passageways 50 and 52. In this manner, both the parts and the scrap metal produced may be either organized or disposed of more efficiently. It should also be understood that the chute system 14 may be adapted to operate in both modes simultaneously. For example, one chute may operate in a “scrape mode” while another chute operates in a “parts mode.”
Now referring to
With respect to conveyor system 54, as the parts exit the chute system 14, the parts may be carried by conveyor system 54 to another conveyor system 58 that carries the parts back up to the main floor of the manufacturing plant. In this manner, the parts may be sorted and stored by workers stationed on the main floor, or automatically through automation. Although a pair of conveyor systems 54 and 58 are shown to direct the parts, it should be understood that only a single conveyor system 54 may be used. Further, although the conveyor systems 54 and 58 carry the parts back to the main floor of the manufacturing plant, it should be understood that the parts may be automatically sorted and dropped into storage receptacles in the lower level or basement of the plant without departing from the spirit and scope of the present teachings.
Conveyor system 56 is also disposed adjacent chute system 14 and carried scrap metal away from the chute system 14 when the chute system 14 has been switched into its scrap metal mode. That is, conveyor system 56 operates after deflector devices 44 actuate deflector plates 48 to open the second passageways 52. By using conveyor system 56, scrap metal may be transferred and disposed of.
It should be understood that although the above described stamping system 10 has been described using a chute system 14 and conveyor systems 54, 56, and 58 that assist in directing or disposing of parts and scrap metal, the present teachings are particularly directed to a method for manufacturing parts using available portions of the blanks that otherwise would be discarded. For example, referring to
By using portions 62 that otherwise would become scrap metal to form free parts 64, an enormous cost savings can be achieved. This is because scrap metal, although recyclable, is sold at a price will below its initial retail value. Moreover, the productivity of the stamping system 10 can be increased from merely forming stamped parts such as doors and body panels by adding the additional function of forming and/or trimming free parts 64.
Accordingly, the present teachings are easily applicable to existing stamping systems that may be present in a manufacturing plant. That is, as described above, each bolster 20 of the stamping system 10 includes a plurality of through-holes 28. As these parts 64 are manufactured, therefore, the free parts 64 may pass through the through-holes 28 and enter the chute system 14 to be automatically/mechanically stored and organized. Accordingly, the only modifications to existing stamping systems to implement the present teachings entails manufacture of the chute system 14 and modification of the lower dies 22 such that the free parts 64 may be manufactured during the stamping process.
In another aspect of the present teachings, stamping systems that are not as productive (i.e., not used as much) as other stamping systems in the manufacturing plant may be modified to be solely used to manufacture various parts 66. For example, referring to
As shown in both
Lastly, it should be understood that the stamping systems 10 described above the beneficial in that the parts manufactured using the stamping system are not required to be made at another manufacturing plant or purchased from another part. In this manner, a significant cost savings may be achieved by eliminating the need for additional manufacturing space to make the parts, and by eliminating the need to purchase these parts from another party.
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.