1. Field of the Invention
The present invention is related generally to shaping and heat treating parts.
2. Related Art
The manufacture of many metal parts, such as automotive parts, requires both shaping and heat treating operations. Various types of shaping operations include, for example, stamping, extruding, machining, roll forming, hydro forming, etc. Heat treating operations typically include heating the part to a predetermined temperature, such as an austenite transformation temperature, and cooling the part at a predetermined rate. The cooling rate chosen will affect the microstructure of the metal and thus the mechanical properties of the part.
One particular type of shaping operation includes placing a metal blank into a die assembly and closing a pair of dies having patterns around the blank to deform the blank into a workpiece having a predetermined shape. Next, the dies are separated from one another and the workpiece is removed from the die assembly. After removal from the die assembly, the workpiece is heat treated to provide it with a desired microstructure.
One aspect of the present invention includes a method of making a workpiece. The method includes the step of preparing a die assembly including a pair of dies, wherein at least one of the dies has a shoe, a plurality of forming pieces operably coupled with the shoe, and at least one compressible member which is sandwiched between the shoe and at least one of the forming pieces. The method proceeds with the step of positioning a blank in the die assembly between the pair of dies. The method continues with the step of moving at least one of the dies towards the other die. The method proceeds with the step of compressing the at least one compressible member to move at least one of the forming pieces relative to another of the forming piece. The method continues with the step of deforming the blank with the plurality of forming dies. The method proceeds with the step of separating the pair of dies by a predetermined distance such that at least one of the forming pieces disengages from the deformed blank while the at least one compressible member expands to maintain at least one of the forming pieces in engagement with the deformed blank. The method further includes the step of conductively cooling less than the entire surface of the deformed blank with the at least one forming piece in engagement with the deformed blank after separating the pair of dies by the predetermined distance.
The same equipment to be used to both shape and heat treat predetermined portions of the blank. This allows for reduced manufacturing time and improved cost effectiveness in the manufacturing of the part.
According to another aspect of the present invention, the method further includes the steps of moving at least one of the dies towards the other die to engage all of the forming pieces with the deformed workpiece after the step of conductively cooling less than the entire surface of the deformed workpiece and conductively cooling substantially the entire surface of the deformed workpiece. This is advantageous because it allows for heat treating of substantially the entire part within the die assembly. Additionally, closing the die assembly has the effect of compensating for any deformations in the workpiece that may arise from uneven cooling.
Another aspect of the present invention provides for a forming assembly for shaping a blank into a workpiece. The forming assembly includes a pair of dies that are moveable towards and away from one another. At least one of the dies has a shoe and a plurality of forming pieces operably coupled with the shoe and at least one compressible member that is sandwiched between the shoe and at least one of the forming pieces. The at least one compressible member is of a material that is elastically deformable for allowing at least one of the forming pieces to move relative to an adjacent forming piece. The at least one die with the forming piece further includes a cooling system for extracting heat from the workpiece.
These and other features and 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 throughout the several views, an exemplary embodiment of a one-piece, stamped automotive part 20 (or workpiece) made of steel or a steel alloy is generally shown in
The untempered and tempered portions 22, 24 are formed into the one-piece part 20 during and immediately following a stamping process on a die assembly 26, and using the same die assembly 26 as is used for the stamping process. Referring now to
A plurality of compressible members 42, 44 or discs made of an elastically compressible material (such as neoprene) or hydraulic or pneumatic cylinders are sandwiched between the shoes 32, 34 and the respective forming pieces 36, 38 for allowing movement of the forming pieces 36, 38 relative to one another during operation of the die assembly 26, as discussed in further detail below. Referring now to
In the exemplary embodiment, the compressible members 42, 44 are formed of a rubber material with a high thermal conductivity. However, it should be appreciated that the compressible members 42, 44 could alternately be formed of any suitably elastically compressible material. The compressible members 42, 44 could also be formed of different materials.
Referring back to
The process of shaping and heat treating a metal blank to form a part, such as the part 20 shown in
During or immediately following the deformation of the blank 20 in the cavity 40 of the die assembly 26, the part 20 is heat treated between the upper and lower dies 28, 30 to provide the material of the part 20 with predetermined microstructures and mechanical properties. The heat treating process includes separating the upper and lower dies 28, 30 from one another by a predetermined distance such that the thick compressible members 42b, 44b elastically expand by a greater distance than the thin compressible members 42a, 44a to maintain the forming pieces 36, 38 coupled with the thick compressible members 42b, 44b in contact with the part 20 while the other forming pieces 36, 38 separate therefrom.
A coolant is then channeled through the shoes 32, 34 of the upper and lower dies 28, 30, and heat is transferred conductively from the shaped part 20, through the forming pieces 36, 38 that remain in contact therewith, through the thick compressible members 42b, 44b and into the shoe 32, 34 where it is extracted from the die assembly 26 by the coolant. As such, when the upper and lower dies 28, 30 are in the intermediate positions shown in
After the portions that remain in contact with the forming pieces 36, 38 cool to a predetermined temperature (e.g., 300° C.) and after a predetermined duration of time, the upper and lower dies 28, 30 are then moved back towards one another to the positions shown in
It should be appreciated that the upper and lower dies 28, 30 could be selectively moved together and separated at predetermined intervals to selectively cool the shaped part, thereby forming a range of different microstructures other than just tempered and untempered martensite.
Another aspect of the present invention is related to a method of making a part. The method includes the step of preparing a die assembly 26 including a pair of dies 28, 30, wherein at least one (and preferably both) of the dies 28, 30 has a shoe 32, 34; a plurality of forming pieces 36, 38 operably coupled with the shoe 32, 34; and at least one compressible member 42, 44 which is sandwiched between the shoe 32, 34 and at least one of the forming pieces 36, 38. In the exemplary embodiment, each of the dies 28, 30 has a plurality of thin compressible members 42a, 44a with a first thickness t1 and a plurality of thick compressible members 42b, 44b with a second thickness t2 that is greater than the first thickness t1.
The method continues with the step of positioning a blank 20 in the die assembly 26 between the upper and lower dies 28, 30. The method proceeds with the steps of moving at least one of the dies 28, 30 towards the other die 28, 30 and compressing the at least one compressible member 42, 44 to move at least one of the forming pieces 36, 38 relative to another adjacent forming piece 36, 38. The method proceeds with the step of compressing the at least one compressible member 42, 44 to move at least one of the forming pieces 36, 38 relative to another forming piece 36, 38. The method proceeds with the step of deforming the blank 20 with the plurality of forming pieces 36, 38. The method continues with the step of separating the upper and lower dies 28, 30 by a predetermined distance such that at least one of the forming pieces 36, 38 disengages from the deformed blank 20 while the at least one compressible member 42, 44 expands to maintain at least one of the forming pieces 36, 38 in engagement with the deformed blank 20. The method proceeds with the step of cooling the deformed blank 20 with the at least one forming piece 36, 38 in engagement with the deformed blank 20 after separating the pair of dies 28, 30 by the predetermined distance.
In the exemplary method, the at least one compressible member 42, 44 includes at least one thin compressible member 42a, 44a sandwiched between the shoe 32, 34 and at least one thick compressible member 42b, 44b and wherein during the separation of the upper and lower dies 28, 30, the at least one forming piece 36, 38 in connection with the at least one thin compressible member 42a separates from the deformed blank 20 and the at least one forming piece 36, 38 in connection with the at least one thick compressible member 42b, 44b remains in contact with the deformed blank 20.
In the exemplary method, the shoe 32, 34 includes a cooling channel for conveying a cooling fluid to cool the forming pieces 36, 38 after the step of deforming the blank 20.
The compressible members 42, 44 are preferably of a material having a high thermal conductivity.
The exemplary method further includes the step of heating the blank 20 before the step of moving at least one of the dies 28, 30 towards the other die 28, 30.
The exemplary method still further includes the steps of moving at least one of the dies 28, 30 towards the other die 28, 30 to engage all of the forming pieces 36, 38 with the deformed blank 20 after the step of conductively cooling less than the entire surface of the deformed blank 20 and conductively cooling substantially the entire surface of the deformed blank 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. National Stage patent application claims the benefit of PCT International Patent Application Serial No. PCT/US2014/014589 filed Feb. 4, 2014 entitled “Hot Die Forming Assembly And Method Of Making A Heat Treated Part,” which claims the benefit of U.S. Provisional Patent Application Ser. No. 61/761,265 filed Feb. 6, 2013, entitled “Hot Die Forming Assembly And Method Of Making A Heat Treated Part,” the entire disclosures of the applications being considered part of the disclosure of this application and hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US14/14589 | 2/4/2014 | WO | 00 |
Number | Date | Country | |
---|---|---|---|
61761265 | Feb 2013 | US |