The present disclosure relates generally to metal forming processes.
Automotive body panels and other similar articles of manufacture are often made by forming a sheet metal blank using a forming press. During the forming process, the sheet metal blank is pressed against the surface of at least one die in the forming press. After a predetermined amount of forming time, the sheet metal blank assumes the shape of the die surface, and is thereafter removed from the forming press. In some instances, a lubricant may be applied to the die and/or the sheet metal blank to reduce adhesion between the two during the forming process, as well as to facilitate removal of the formed part from the forming press.
As disclosed herein, a metal forming process includes applying a lubricant to at least one surface of a sheet metal blank, where the lubricant is formed from a vitreous enamel mixed with particles of boron nitride. The method further includes, without pre-heating the sheet metal blank, placing the sheet metal blank having the lubricant applied thereto into a pre-heated forming tool, and via the pre-heated forming tool, forming the sheet metal blank into a desired part shape. During the forming of the sheet metal blank into the desired part shape, a lubricant layer is formed on the surface as the lubricant is heated from the pre-heated forming tool, the lubricant layer adhering to the surface of the sheet metal blank.
Features and advantages of the present disclosure will become apparent by reference to the following detailed description and drawings, in which like reference numerals correspond to similar, though perhaps not identical, components. For the sake of brevity, reference numerals or features having a previously described function may or may not be described in connection with other drawings in which they appear.
Example(s) of the metal forming process as disclosed herein include a forming process that uses a lubricant that, when applied to a surface of a sheet metal blank, advantageously reduces or even prevents adhesion of the blank to the forming tool. In an example, the adhesion (in terms of its coefficient of friction) is reduced by at least 40% compared with other lubricants containing enamels without boron nitride. The lubricant utilized in the process may be formed from a composite of boron nitride and a vitreous enamel, and is configured to adhere to the sheet metal blank throughout the forming process. The lubricant is further configured to automatically break apart upon cooling after the blank, which has been formed into an article or part, is removed from the forming tool. The breaking apart of the lubricant advantageously obviates a need for post-forming washing or other cleaning process(es) that are typically used to remove lubricant from the formed part. The eliminating of such post-forming processes may, in some instances, render the forming method disclosed herein as efficient at least in terms of time, maintenance, and/or material/equipment costs.
The example(s) of the metal forming process disclosed herein are generally used to form a part having a desired part shape from a sheet metal blank, where the forming is accomplished via hot forming using a forming press or tool. As used herein, “hot forming” refers to the superplastic deformation of the sheet metal blank when the blank is pressed against one or more surfaces of the forming tool under temperatures ranging from about 400° C. to about 1200° C. It is to be understood that a temperature falling within this range may be referred to herein as a “hot temperature”.
Further, the example(s) of the metal forming process may be used to form sheet metal composed of any sheet metal material known in the art, some non-limiting examples of which include steel, iron, magnesium, aluminum, alloys of magnesium or aluminum, and/or the like, and/or combinations thereof. It is to be understood that the metal forming process of the instant disclosure is particularly useful for sheet metals that are composed of a material that tends to readily adhere to the tool during forming. When such materials are used, the adherence of the material to the tool often leads to the formation of surface defects of the formed part, which may, in some cases, be undesirable. Some non-limiting examples of sheet metal materials exhibiting this adhesive property include, but are not limited to, aluminum, magnesium, titanium, and alloys of each.
The adherence of the sheet metal blank to one or more contacting surfaces of the forming tool may be reduced, for example, by applying the lubricant to the contacting surfaces of the forming tool or to the sheet metal blank itself. In many cases, the lubricant is applied to the sheet metal blank prior to placing the blank inside the forming tool. Several lubricants are commercially available and may suitably be used to reduce the adhesion issue between the sheet metal blank and the forming tool, non-limiting examples of which include mixtures of graphite and boron nitride. The lubricant films obtained from these mixtures, however, have a tendency to break down or otherwise lose their lubricity in certain high stress areas of the sheet metal blank (e.g., at corners, bends, etc.), which causes the sheet metal to stick to the forming tool at/around those high stress areas. In many cases, the quality of the formed part or article is greatly reduced, at least in those high stress areas, and the breaking down of the lubricant during the forming may affect or otherwise compromise the working life of the forming tool itself. Yet further, the cost of pure graphite or of pure boron nitride may be such that it may be economically disadvantageous to use mixtures of these materials in quantities necessary to effectively reduce the adhesion.
An example of a lubricant that may effectively be used in the examples of the method disclosed herein includes one formed from particles of boron nitride and a vitreous enamel. Without being bound to any theory, it is believed that the boron nitride contributes to decreasing the coefficient of friction between the sheet metal blank and the forming tool in the presence of hot temperatures. This allows the metal to flow into surfaces of the tool so that a part may be formed without, or with minimal surface defects. Further, the vitreous enamel melts at working temperatures, and thus the lubricant film may be transformed into a plastic layer that covers substantially the entire working surface of the sheet metal blank. For at least this reason, there is minimal contact, if any, between the tool and the sheet metal surface.
In an example, the boron nitride particles have an average particle size (measured in terms of, e.g., the particles' effective diameter) ranging from about 7 microns to about 10 microns, and at least 90% of the boron nitride particles have a particle size that is smaller than 15 microns. For instance, if about 90% of the boron nitride particles have a particle size of less than 10 microns, then i) about 50% of the boron nitride particles are smaller than 5 microns, and ii) about 10% of the boron nitride particles are smaller than 1.5 microns. The boron nitride particles may be commercially available from, e.g., Atlantic Equipment Engineers, Bergenfield, N.J.; Kadco Ceramics, Easton, Pa.; Goodfellow Corp., Oakdale, Pa.; and AC Technologies, Yonkers, N.Y., to name a few.
In an example, the vitreous enamel is a porcelain enamel formed from a borosilicate glass prepared from a combination of some or all of the following materials: quartz (SiO2), borax (anhydrous formula Na2B4O7), boric acid (H3BO3), potassium nitrate (KNO3), sodium silicofluoride (Na2SiF6), and manganese dioxide (MnO2). The enamel may further include titanium dioxide (TiO2), antimony oxide (Sb2O3), cobalt oxide (such as, e.g., cobaltous oxide (CoO), cobalto-cobaltic oxide (CO3O4), cobaltic oxide (CO2O3), barium oxide (BaO), sodium oxide (Na2O), potassium oxide (K2O), lead (II) oxide (PbO), boron trioxide (B2O3), and/or combinations thereof. The proportions of the materials used in a mixture of selected materials from the foregoing examples to form the enamel may be adjusted depending, at least in part, on the temperature at which the part is formed and the performance characteristics needed from the lubricant. One specific example of the vitreous enamel includes a dry mix of about 33 wt % Na2O, about 22 wt % K2O, about 3 wt % of PbO, about 10 wt % of B2O3, about 12 wt % TiO2, and about 20 wt % SiO2, and water was added to the dry mix at a ratio of about 2:1 to make a slip of the enamel.
The lubricant includes about 10 wt % to about 20 wt % of the boron nitride, and about 80 wt % to about 90 wt % of the vitreous enamel. In an example, the lubricant has a melting temperature ranging from about 800° F. to about 1000° F., which falls within the hot forming temperature range.
In an example, the lubricant is generally made by mixing the boron nitride particles with the vitreous enamel and water to form a water-based slurry. Details of this process may be found in U.S. Pat. No. 6,745,604, owned by the Assignee of the instant application, the contents of which is incorporated herein by reference in its entirety.
Details of the metal forming process will now be described herein in conjunction with the figures. It is to be understood that the metal forming method is referred to herein as a continuous metal forming process (i.e., the sheet metal blank is not cooled or otherwise exposed to a temperature sufficient to cool the blank until after the part is formed). This is in contrast to discontinuous processes, whereby the sheet metal blank is cooled or exposed to a temperature sufficient to cool the blank more than once before the part is actually formed. For instance, the sheet metal blank may be placed inside a preheating oven or furnace so that the lubricant adheres to the blank surface. The blank is then removed from the preheating oven and placed into the forming tool. Due, at least in part, to the thinness of the blank and its thermal expansion coefficient (which is higher than that of the lubricant) the blank cools relatively quickly during the time defined between the removing of the blank from the oven and the placing of the blank into the forming tool. In many cases, the enamel portion of the lubricant becomes brittle upon cooling when the blank is removed from the preheating oven. Accordingly, when the blank is placed into the forming tool and exposed to the hot forming temperature, the lubricant (now in a brittle state due at least in part to the brittleness of the enamel) detaches from the blank during the hot forming inside the forming tool.
Referring now to
The sheet metal blank 12 having the lubricant 14 applied on the surface 13 thereof, and which is not preheated, may then be placed into a preheated forming tool (such as the forming tool 16 shown in
In an example, the forming tool 16 is preheated to a temperature ranging from about 800° F. to about 1200° F., which is i) within the hot forming temperature range, and ii) the melting temperature of the lubricant. It is to be understood that the blank may otherwise be placed into a non-preheated tool, and then the tool may be heated to the hot forming temperature range disclosed above. Thus, upon being placed inside the forming tool 16 and being exposed to the heat (either when the tool is preheated or heated after the blank is placed therein), the lubricant 14 melts and forms a lubricant 14 layer on the surface 13 of the blank 12. As mentioned above, this lubricant 14 layer covers the entire surface 13 of the blank 12 such that the blank 12 does not stick or adhere to the forming tool when in contact therewith. More specifically, the lubricant 14 acts like a separation layer between a forming tool 16 (such as a surface 20 of a die 18) and the surface 13 of the sheet metal blank 12. As will be described in further detail below, once the lubricant 14 layer is formed, the layer does not break. As such, the die surface 20 and the sheet metal surface 13 remain separate throughout the forming process.
Referring now to
As shown in
During hot forming, the temperature of the preheated forming tool 16 remains within the 800° F. to 1200° F. range (i.e., the temperature range at or above the melting temperature of the lubricant), and at least one of the upper die 18 or the lower die 22 is drawn toward the other of the dies 18, 22. This movement presses the supported sheet metal blank 12 against the surfaces 20, 24 of the dies 18, 22, respectively, in the presence of the heat.
After a predetermined period of pressing time, the sheet metal blank 12 assumes the shape of the die surfaces 20, 24 and forms the blank 12 into the desired part shape or article 10 (shown in
Upon removing the formed part 10 from the forming tool 16, the part 10 substantially immediately begins to cool down from the hot forming temperature of 800° F. to 1200° F. to (ultimately) ambient temperature. It is to be understood that the rate of cooling depends, at least in part, on the thickness of the part, as well as the heat conductivity of the material used to form the part (i.e., the material of the sheet metal blank 12). For those parts formed from aluminum or alloys thereof having a thickness of about 1 mm, cooling may be accomplished relatively quickly (e.g., in a matter of seconds such as about 30 to 40 seconds). Cooling may be accomplished simply by exposing the part 10 to the ambient environment. In some instances, cooling may also be accomplished by placing or otherwise exposing the part 10 to a cooling fixture 28 (shown schematically in phantom line in
In response to the cooling of the part 10, the enamel portion of the lubricant 14 layer becomes brittle and breaks off of the part 10. Without being bound to any theory, it is believed that the brittleness of the enamel portion of the lubricant 14 occurs upon cooling, at least in part because the thermal expansion coefficient is significantly lower than that of the sheet metal used to form the part 10. More specifically, the higher thermal expansion coefficient of the sheet metal (such as for aluminum) causes the material to contract more than the enamel portion of the lubricant during cooling. This allows the sheet metal upon which the lubricant is applied to change shape more quickly than the enamel, and thus the enamel portion of the lubricant breaks apart. It is to be understood that this may also occur if the lubricant is applied, e.g., to the die surface 20 in instances where the die 18 is formed from a material (such as a ferrous material) that renders the difference between the thermal expansion coefficients of the lubricant and the die as being high. In some instances, the broken off pieces of the lubricant (which are identified by 14′ in
While several examples have been described in detail, it will be apparent to those skilled in the art that the disclosed examples may be modified. Therefore, the foregoing description is to be considered non-limiting.
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Number | Date | Country | |
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20120111078 A1 | May 2012 | US |