This application claims the benefit of Czech Republic Application No. PV2014-455 filed Jun. 30, 2014, the entire disclosure of which is incorporated herein by reference.
This invention relates to a method of manufacturing steel parts of sheet by hot deep drawing.
At present, hot-formed steel parts made by deep drawing and subsequent cooling in the tool are made by heating a sheet metal blank of suitable dimensions in a furnace to the austenite temperature, holding for several minutes, then removing the sheet metal blank from the furnace and transferring it to a tool, in which deep drawing is carried out. This pressed part cools when it comes into contact with the tool, which causes transformation to a microstructure, which is typically or hardening type, i.e. martensite, bainite or mixed-type. This method is used, for instance, in the U.S. Pat. No. 4,619,714. This manufacturing method allows three-dimensional shapes to be made which are limited by the material's plasticity and ductility at the temperature which affects the moment, at which the material fails. The shapes of the three-dimensional portions of the drawn part are often very complex and the shortage of material in the severely-formed zones causes the wall thickness in some locations to decrease disproportionately, which in turn leads to localized deformation, which results in failure. This makes the manufacture of drawn parts with larger depths impossible. A typical failure is a radial crack in the fins, which initiates below the transition area between the flat portion of the pressed part and the wall. In practice, this drawback is eliminated by cold pre-drawing the semi-finished product and by subsequent completion of the final shape by hot drawing. However, as no heating is used in the first cold forming operation, the diffusion, which is necessary for the corrosion-resistant film to adequately bond to the sheet metal, does not take place. Due to its insufficient plasticity at room temperature, the film then suffers damage during deformation and peels off the final drawn part. Aside from that, this multiple drawing process is lengthy, requires more complex logistics and costly multistage forming tools. It also requires longer machine times and higher energy consumption.
The aforementioned drawback of formed parts of sheet metal by a hot process is eliminated by a method of manufacturing characterized in that a steel sheet metal blank heated in a furnace to austenite temperature is locally cooled either while being transferred to a forming tool or before the forming tool closes or at the moment the forming tool closes. This local cooling is applied to areas where problems occur with a shortage of material and with deformation localization and where excessive reduction of area leads to crack initiation in the real-life three-dimensional drawn part. This cooling may be achieved, for instance, by the application of a stream of gas, gas-liquid mixture, liquid, or by contact with another material capable of conducting the heat away, or by other methods. The cooling may be carried out at a pre-defined cooling rate in order to achieve the best possible effect with regard to the required shape of the drawn part. Local cooling of the material in pre-defined areas will increase flow stress, which will prevent deformation localization in this particular location, and the deformation will thus move to other areas or spread across a larger area in order to prevent failure of the material and the resulting crack formation in the drawn part due to high local reduction of area. This cooling may be carried out either to the undercooled austenite region or even to the region of mixed microstructures consisting of austenite, martensite, bainite, ferrite.
A blank of sheet metal of 1.5 mm thickness of the 22MnB5 steel is heated in a furnace to the temperature of 950° C., at which it is kept in the furnace for the period of 3 minutes. This brings it into fully austenitic condition. After that, it is removed from the furnace and transferred to a tool. Before it is placed into the tool, the transfer is interrupted for approximately 1 second, during which nozzles located above the sheet metal blank blow pressurized mixture of air and water in a controlled manner onto selected locations of the sheet metal blank. This local cooling reduces the temperature in the desired locations down to 500° C. By this means, areas with higher flow stress are created. The plasticity of the material distributed differentially across the semi-finished product in this manner leads to the creation of the desired profile of deformation properties in the particular sheet metal blank. After this, the transfer of the sheet metal blank to the tool is completed. In the tool, the blank is formed in a deep-drawing operation. This entire transfer of the sheet metal blank from the furnace to the tool, including the local cooling, takes approximately 10 seconds. After the deformation, the semi-finished product remains enclosed in the tool for additional 15 seconds in order for the desired hardening-type microstructure to form. By this means, the temperature of the drawn part decreases to less than 150° C. At the same time, the microstructure evolution is thus completed. After that, the pressed part is removed from the mold and cools to the ambient temperature on transport equipment.
The invention can find broad use in the field of sheet metal processing in hot deep drawing applications, predominantly in the manufacture of complex-shaped parts with a large depth of the final shape, which are impossible to make using the conventional route in a single draw.
Number | Date | Country | Kind |
---|---|---|---|
2014-455 | Jun 2014 | CZ | national |
Number | Name | Date | Kind |
---|---|---|---|
4054276 | Wilson | Oct 1977 | A |
4122700 | Granzow | Oct 1978 | A |
4619714 | Thomas | Oct 1986 | A |
5966977 | Engel | Oct 1999 | A |
7024897 | Pfaffmann | Apr 2006 | B2 |
8646302 | Lety | Feb 2014 | B2 |
20110239721 | Carter | Oct 2011 | A1 |
20150336151 | Frost | Nov 2015 | A1 |
Number | Date | Country | |
---|---|---|---|
20150375286 A1 | Dec 2015 | US |