1. Field of the Invention
The inventions relates generally to a system and method for hot forming a plurality of parts, such as steel parts for chassis and automotive body applications.
2. Related Art
Hot forming processes typically comprise heating a steel blank in a furnace, followed by stamping the heated blank between a pair of dies to form a shaped part, and quenching the shaped part between the dies. The steel blank is typically heated in the furnace to achieve an austenitic microstructure, and then quenched in the dies to transform the austenitic microstructure to a martensitic microstructure. The hot forming process preferably runs continuously to produce a plurality of the shaped parts at a high rate and low cost. However, when the furnace malfunctions, the entire system must be shut down for a period of time while the furnace is repaired, which increases the cost per part produced by the system.
The invention provides a system for hot forming a plurality of parts, such as steel parts for use as chassis or body components of an automobile. The system comprises a furnace including a plurality of shelves stacked vertically relative to one another. Each shelf includes a plurality of driven rollers for conveying a plurality of blanks through the furnace. The furnace also includes a plurality of heaters for heating the blanks, wherein each heater is disposed adjacent one of the shelves. Each shelf and the adjacent heater is removable from the furnace, for example when the heater is malfunctioning. The system further includes a hot forming apparatus for shaping the heated blanks, and a blank feeder for conveying the heated blanks from the shelves of the furnace to the hot forming apparatus.
The invention also provides a method for hot forming a plurality of parts. The method includes conveying a plurality of blanks along a plurality of shelves of a furnace, and heating the plurality of blanks using a heater disposed adjacent each shelf. The method also includes removing the heater and the adjacent shelf from the furnace when the heater is malfunctioning while continuing to heat the blanks on the other shelves. The method further includes conveying the heated blanks from the furnace to a hot forming apparatus, and shaping the heated blanks in the hot forming apparatus.
Other advantages of the present invention will be readily appreciated, as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:
Referring to the Figures, wherein like numerals indicate corresponding parts 20 throughout the several views, an exemplary system 22 for hot forming a plurality of shaped parts 20 is generally shown in
The blanks 26 used to manufacture the shaped parts 20 are typically formed of metal, but can be formed of other materials. In one exemplary embodiment, the blanks 26 are formed of steel material, such pure steel or a steel alloy. Although the shaped parts 20 are typically designed for use as chassis or automotive body components, the parts 20 can alternatively be used in other applications.
The system 22 includes the furnace 24 for heating a plurality of the blanks 26 prior to shaping the blanks 26 in the hot forming apparatus 30. The furnace 24 includes a plurality of shelves 32 stacked vertically relative to one another and a heater 34 disposed adjacent each shelf 32. Each heater 34 can comprise a single heating element or a plurality of heating elements. For example, each heater 34 could include a plurality of tubes containing burning gas, or a plurality of heated coils. Each shelf 32 extends horizontally from a first side to a second side opposite the first side and presents an area capable of supporting at least one blank 26, but preferably a plurality of the blanks 26. In addition, each shelf 32 is fixable to other shelves 32, and each shelf 32 and the adjacent heater 34 is individually removable from the furnace 24.
Preferably, the furnace 24 includes a plurality of chambers 36 stacked vertically relative to one another and each including one of the shelves 32 and one of the heaters 34, as shown in
The shelves 32 of the furnace 24 include a plurality of first driven rollers 42 extending from the first side to the second side for conveying the blanks 26 through the furnace 24. The first driven rollers 42 can comprise mechanically driven ceramic rollers or rollers of the type used in hearth type furnaces. The first driven rollers 42 of the furnace 24 can rotate continuously, remain stationary for periods of time, or oscillate forward and backward, depending on the amount of heating desired. In addition, the first driven rollers 42 of one shelf 32 can move or rotate at a rate different from the first driven rollers 42 of another shelf 32. For example, the blanks 26 being conveyed along one of the lower shelves 32 can remain in the furnace 24 for a longer period of time than blanks 26 being conveyed along one of the upper shelves 32, to achieve different microstructures in those blanks 26.
As mentioned above, the furnace 24 includes the plurality of heaters 34 for heating the blanks 26 as they continuously move through the furnace 24 or rest in the furnace 24 for a period of time. Each heater 34 is disposed adjacent one of the shelves 32 for heating the blanks 26 disposed on that shelf 32. In the exemplary embodiment of
The furnace 24 of the inventive system is advantageous compared to furnaces of other hot forming systems because it can continue running even if one or more of the heaters 34 malfunctions or fails. Thus, the hot forming system 22 can continuously form the shaped parts 20 with little or no down time. For example, the chamber 36 containing the malfunctioning heater 34 can be removed from the stack of chambers 36 and repaired while the blanks 26 continue moving through the remaining heated chambers 36. Alternatively, if the furnace 24 contains the stack of shelves 32, the malfunctioning heater 34 and the adjacent shelf 32 can be removed from the stack. The reduction in down time provided by the system 22 reduces the overhead costs per shaped part 20 produced. In addition, the furnace 24 with the stacked shelves 32 or chambers 36 requires less floor space than other comparatively sized furnaces.
The exemplary system 22 also includes a blank loader 48, preferably an indexing blank loader including a plurality of second driven rollers 44 for feeding the unheated blanks 26 to the shelves 32 of the furnace 24. The second driven rollers 44 of the blank loader 48 align with and are timed to move with the first driven rollers 42 of one of the shelves 32. Thus, the first and second driven rollers 42, 44 rotate at approximately the same rate and move one or more of the unheated blanks 26 through the first door 38 and through the chamber 36. The system 22 can also include a robot 50 with a controller for automatically disposing the unheated blanks 26 on the blank loader 48. Alternatively, the system 22 could be fed from a coil of material which is divided to form the plurality of blanks 26 at some point during the process.
In the exemplary system, the blank loader 48 is movable vertically along the first sides of the chambers 36 for feeding the blanks 26 onto each of the shelves 32 of the furnace 24. This blank loader 48 is configured to automatically raise or lower the blanks 26 and feed them into the open chambers 36.
The system 22 also includes the hot forming apparatus 30 for forming the heated blanks 26 into a plurality of the shaped parts 20. The hot forming apparatus 30 is preferably a hot stamping press including an upper die 52 and a lower die 54 facing one another and presenting at least one cavity 56 therebetween for shaping at least one of the heated blanks 26. In the exemplary embodiment, the dies present a plurality of cavities 56 for simultaneously shaping at least one of the heated blanks 26 into a plurality of the shaped parts 20, or a plurality of the heated blanks 26 into a plurality of the shaped parts 20. The cavities 56 could be similarly shaped or differently shaped for simultaneously producing different types of parts 20. In addition, the upper die 52 and the lower die 54 are interchangeable and removable from the hot forming apparatus 30. For example, the upper die 52 and lower die 54 can be exchanged for dies having different designs.
The hot forming apparatus 30 also includes a plurality of cooling ports 58 extending along the cavities 56 for conveying a cooling fluid therethrough, such as water or any other cooling fluid. Thus, the shaped parts 20 can be quenched after the shaping process is complete, and while the shaped parts 20 are still in the cavities 56. The quantity and temperature of water fed through the cooling ports 58, as well as the shapes and locations of the cooling ports 58, can be chosen to achieve a desired quenching rate, and thus achieve the desired microstructure in the metal parts 20. For example, when the blanks 26 are formed of the steel material, the quenching step includes rapidly cooling the shaped parts 20 to transform the austenitic microstructure to a martensitic microstructure. In addition, one or more of the cooling factors could be varied for different cavities 56 to simultaneously produce a plurality of shaped parts 20 having different microstructures. The hot forming apparatus 30 typically includes a controller (not shown) to actuate the dies 52, 54 after one or more heated blanks 26 is properly placed between the dies 52, 54. The controller of the hot forming apparatus 30 can also adjust the amount of time that the parts 20 are quenched between the dies 52, 54.
The exemplary system 22 also includes the blank feeder 28 disposed opposite the blank loader 48 and extending continuously from the furnace 24 to the hot forming apparatus 30 for conveying the heated blanks 26 to the hot forming apparatus 30. The blank feeder 28 is preferably an indexing blank feeder and includes a plurality of third driven rollers 46. The indexing feature of the blank feeder 28 can comprise a plurality of indexing fingers for aligning the heated blanks 26 in a predetermined position prior to entering the hot forming apparatus 30. The blanks 26 are preferably positioned as close together as possible to reduce waste material during the hot forming step. The blank feeder 28 of the exemplary embodiment is movable vertically along the second sides of the shelves 32 for conveying the heated blanks 26 from each of the shelves 32 to the hot forming apparatus 30. The third driven rollers 46 align with and are timed to move with the first driven rollers 42 of the shelves 32 at approximately the same rate. Alternatively, the blank feeder 28 could be removable, and another robot (not shown) could plug the blank feeder 28 into the furnace 24. The blank feeder 28 is preferably insulated from the surrounding environment, or includes a heater (not shown) so that the heated blanks 26 are at a desired temperature when they enter the hot forming apparatus 30. The system 22 can also include another robot (not shown) for lifting the heated blanks 26 off the blank feeder 28 and placing the heated blanks 26 in position relative to the cavities 56 of the hot forming apparatus 30. Alternatively, the system 22 could include another method, such as a mechanical transfer system, for conveying the heated blanks 26 from the furnace 24 to the hot forming apparatus 30.
The system 22 also typically includes transfer bars (not shown) for removing the shaped parts 20 from the hot forming apparatus 30 and depositing them on a conveyor 60. The conveyor 60 is disposed adjacent the hot forming apparatus 30 opposite the blank feeder 28 for conveying the shaped parts 20 away from the hot forming apparatus 30. Alternatively, the shaped parts 20 could be removed from the hot forming apparatus 30 through another automated or manual process.
The exemplary system 22 also comprises a system controller 62 including a computer, as shown in
The invention also provides a method for hot stamping a plurality of steel parts 20 providing reduced overhead costs per part 20 and requiring less floor space, compared to other hot forming methods. The method first includes feeding the blanks 26 onto the shelves 32 of the furnace 24, typically by moving the unheated blanks 26 along the second driven rollers 44 of the blank loader 48, through the first doors 38 of the chambers 36, and onto the shelves 32. The second driven rollers 44 are aligned with the first driven rollers 42 of one of the shelves 32, and the first and second driven rollers 42, 44 are timed to move together at approximately the same rate. The method also includes moving the blank loader 48 vertically relative to the first sides of the shelves 32 and feeding the unheated blanks 26 onto each of the shelves 32. Alternatively, the method could include plugging the blank loader 48 into the furnace 24.
The method next includes heating the blanks 26 while the blanks 26 are disposed on the shelves 32, and conveying the blanks 26 along the first driven rollers 42 through the furnace 24. The metal blanks 26 remain in the furnace 24 for an amount of time capable of providing a desired microstructure. For example, the blanks 26 can be heated while continuously moving through the furnace 24, or while resting on the shelves 32 while the first driven rollers 42 remain stationary for a period of time. In another embodiment, the first driven rollers 42 oscillate forward and backward with the blanks 26. The oscillating first driven rollers 42 can prevent hot and cold spots along the blanks 26, prevent the blanks 26 from drooping, and can help maintain the integrity of any coating applied to the blanks 26.
If one of the heaters 34 malfunctions, the method includes removing the chamber 36 containing the malfunctioning heater 34, or removing the malfunctioning heater 34 and the adjacent shelf 32, while continuing to heat the blanks 26 disposed on the other shelves 32. The method also includes fixing the malfunctioning heater 34 while continuing to heat and convey the blanks 26 along the remaining shelves 32 of the furnace 24. Further, the method can include bypassing one of the shelves 32 of the furnace 24 when the heater 34 adjacent the shelf 32 is malfunctioning, or bypassing one of the chambers 36 when the heater 34 contained in the chamber 36 is malfunctioning. Thus, the method can continue manufacturing the shaped parts 20 even when one of the heaters 34 of the furnace 24 is down.
The method next includes conveying the heated blanks 26 from the shelves 32 of the furnace 24 to the hot forming apparatus 30. The conveying step includes moving the heated blanks 26 from the first driven rollers 42 of the furnace 24 to the third driven rollers 46 of the blank feeder 28. The third driven rollers 46 align with the first driven roller 42 and are timed to move together with the first driven rollers 42. In the exemplary embodiment, the method includes moving the blank feeder 28 vertically along the stack of shelves 32 and conveying the heated blanks 26 from each of the shelves 32 to the hot forming apparatus 30. In one embodiment, the method includes isolating the heated blanks 26 from the outside environment while conveying them from the furnace 24 to the hot forming apparatus 30, or heating the blanks 26 while conveying them from the furnace 24 to the hot forming apparatus 30.
Once the heated blanks 26 are disposed between the dies 52, 54 of the hot forming apparatus 30, the method includes stamping the heated blanks 26 between the dies 52, 54 to form a plurality of the shaped parts 20. The stamping step can include simultaneously shaping one of the blanks 26 into a plurality of shaped parts 20 using the plurality of cavities 56 in the hot forming apparatus 30. The method then includes cooling each of the shaped parts 20 while the shaped parts 20 are disposed in the cavities 56 of the hot forming apparatus 30. In one embodiment, the cooling step includes cooling at least two of the shaped metal parts 20 in the cavities 56 at different rates to achieve different microstructures in the shaped metal parts 20.
Obviously, many modifications and variations of the present invention are possible in light of the above teachings and may be practiced otherwise than as specifically described while within the scope of the appended claims.
This U.S. patent application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/730,667 filed Nov. 28, 2012, entitled “Hot Stamping System And Method,” the entire disclosure of the application being considered part of the disclosure of this application and hereby incorporated by reference.
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Number | Date | Country | |
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20140144198 A1 | May 2014 | US |
Number | Date | Country | |
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61730667 | Nov 2012 | US |