Hot stamping method

Abstract

Provided is a method for manufacturing vehicle parts having ultra-high strength of 500 Mpa or more by using hot stamping. The method includes: forming a heated blank in a press forming apparatus; and taking out the formed blank from the press forming apparatus and consecutively cutting the blank with a trimming die. A blank temperature at the time of trimming may be 150 C. to 330 C.

Claims

1. A hot stamping method comprising: (a) heating a blank to an austenitization temperature of the blank or more; (b) forming the heated blank in a press forming apparatus, wherein the forming of the blank is started at a temperature of 600 C. to 900 C. and the heated blank is cooled to below a martensite transformation start temperature (Ms) of the blank at a speed of 25 C./sec or more; and (c) taking out the formed blank from the press forming apparatus and consecutively cutting the formed blank with a trimming die, wherein a blank temperature at the time of cutting is 150 C. to 330 C., wherein, in the step (c), the formed blank is taken out from the press forming apparatus at a temperature 250 C. to 350 C.; the formed blank is sequentially cut by using at least two trimming dies; the formed blank is not reheated during the entire process of trimming; and a final trimming is performed at 170 C. or higher.

2. The hot stamping method of claim 1, wherein, the formed blank temperature at the time of cutting is 190 C. to 320 C.

3. The hot stamping method of claim 2, wherein, in the step (c) of sequentially cutting by using at least two trimming dies, the temperature of the formed blank cut in the first trimming die after press forming is 220 C. to 320 C., and the temperature of the formed blank cut in the second trimming die is 190 C. to 300 C.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Embodiments of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings in which:

(2) FIG. 1 is a flowchart of a trimming process according to an embodiment of the present invention;

(3) FIG. 2 is a schematic diagram for describing a configuration of a trimming apparatus according to an embodiment of the present invention;

(4) FIG. 3 is a graph showing a change in shear load for a specimen according to a first trimming temperature according to an embodiment of the present invention; and

(5) FIG. 4 is a graph showing a change in shear load for a specimen according to a second trimming temperature according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(6) Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. For convenience of description, like reference numerals are assigned to refer to like elements throughout the drawings.

(7) A method for trimming hot-stamped parts according to an embodiment will be described with reference to FIGS. 1 and 2.

(8) Blank Heating (S1)

(9) A blank made of 22MnB5 boron steel can be used. As one example, an Al-coated steel sheet of Usibor 1500 proposed by ArcelorMittal can be used.

(10) TABLE-US-00002 TABLE 2 (Rough composition of Usibor, Unit: wt % ) C Mn Si S Cr Al B Ti 0.2~0.25 1.10~1.35 0.15~0.35 0.008 0.15~0.30 0.02~0.06 0.002~0.004 0.02~0.05

(11) For the heating of the blank, an electric heating furnace, a gas heating furnace, or a hybrid heating furnace proposed in U.S. Patent Publication No. 2010/0086002 can be used. Also, various heating methods applicable to hot stamping, such as direct electric resistance heating or high-frequency induction heating can be used.

(12) The blank may be heated to an austenitization temperature (Ac.sub.3), for example, 880 C. to 950 C. As an example, the blank may have a ferritic-pearlitic microstructure at room temperature, and may have a single austenite phase above the austenitization temperature. For reference, the temperature A3 in low carbon steels is a temperature at which the alpha ferrite changes to austenite or the austenite reverts to alpha ferrite. The c is from the French word chauffage, meaning heating.

(13) Press Forming and Cooling (S2)

(14) The heated blank is formed and quenched in a press forming apparatus. A forming start temperature is 600 C. to 900 C., preferably 650 C. to 850 C., above a martensite transformation start temperature (Ms) of the blank.

(15) The forming of the blank is started in the above temperature range, and the blank is cooled at a temperature below Ms. In some cases, the blank may be intended to have a locally softened region during a forming process.

(16) The cooling speed of the blank may be 25 C./sec or more, preferably 27 C./sec or more, and more preferably 30 C./sec or more. The blank may be quenched at a speed of about 200 C./sec in a press forming apparatus having cooling channels.

(17) The quenched blank is taken out from the press forming apparatus at a temperature of 200 C. or higher, and preferably 220 C. to 350 C., and transferred to a trimming die disposed near the press forming apparatus. The blank may be transferred by using a robot at room temperature under atmospheric condition.

(18) Meanwhile, the blank quenched in the press forming apparatus may be taken out at a temperature of below 200 C. When the press-formed blank is trimmed at 170 C., the shear load may be mid-1300 Mpa. The strength of the press-formed blank is slightly high though, the trimming die can be applicable. However, when taking into account the lifespan of the cutting tool of the trimming die, the temperature at which the blank is taken out from the press forming apparatus is preferably 200 C. or higher, and more preferably 250 C. or higher.

(19) When the upper limit of the temperature at which the blank is taken out from the press forming apparatus exceeds 350 C., more critically 360 C., it can be impossible to obtain parts having the targeted tensile strength of 1500 Mpa.

(20) Trimming (S3 and S4)

(21) The trimming is to cut the edges of the formed part along a desired shape line. Although not separately described, piercing or the like can be performed together during the trimming process.

(22) After the press forming, the blank is cut or trimmed in the trimming die. The temperature of the blank to be trimmed can be broadly 150 C. to 330 C., preferably 170 C. to 320 C., more preferably 190 C. to 320 C., and still more preferably 195 C. to 310 C. When the shear load of 1180 Mpa or less is targeted, it may be safe to perform the trimming process in the range of 200 C. to 310 C.

(23) When the blank temperature at the time of trimming process is lower than 190 C., for example, about 170 C., the shear load for the blank increases to mid and late 1300 Mpa. Considering the transferring time of the blank, if the blank temperature when trimming exceeds 350 C., the tensile strength of 1500 Mpa may not be obtained. In addition, when the trimming temperature rises, the thermal load may cause a damage to the trimming tool. Therefore, the preferable blank temperature at the time of trimming is 320 C. or lower, more preferably 310 C. or lower, and still more preferably 300 C. or lower.

(24) The trimming using dies may be completed at one time even it will be very rare cases and may be performed twice or more times so as to separate chips or not to complicate the design of the cutting line of the blank. As illustrated in FIG. 2, two trimming dies 30 and 40 may be sequentially disposed near the press forming apparatus 20.

(25) As illustrated in FIG. 1, the blank temperature at the time of first trimming may be 220 C. to 320 C., and the blank temperature at the time of second trimming may be 190 C. to 300 C. The lower limit of the second trimming temperature may be 170 C., or more extremely down to 150 C. However, for stable operation in a commercial production line, the final trimming is preferably performed at 190 C. or higher, and more preferably 195 C. or higher.

(26) The above temperature conditions are derived as the optimal condition by taking into account the transfer time between the press forming apparatus 20 and the first trimming die 30 and between the first trimming die 30 and the second trimming die 40, the cutting time in each trimming die, various possible time delays, the quality of the hot-stamped parts, and the like. A means for keeping the temperature of the blank within the trimming temperature range have not been considered in the embodiments.

(27) Each of the trimming dies 30 and 40 may be equipped with a temperature sensor for checking the above temperature condition. A heater for keeping the blank temperature in the above condition may be mounted, but the heater need not be mounted according to results of many experiments. In order to mount the heater, a design change for a commercial trimming die is required. This causes an increase in manufacturing costs and maintenance costs, and thus is not preferred.

(28) The trimming temperature condition according to the embodiment will be described in more detail with reference to FIGS. 3 and 4. It should be understood that only a part of a plurality of experimental examples are extracted for the sake of explanation. In the experiment, Al coated steel sheet that is made of 22MnB5 boron and designed to have a tensile strength of 1500 Mpa grade was used.

(29) FIG. 3 is a graph showing a change in shear load according to a blank temperature at the time of first trimming. In FIG. 3, a vertical axis represents shear load, but is replaced by a maximum tensile load of the specimen for convenience. It should be understood that tensile load is used instead of shear load for convenience.

(30) As illustrated in FIG. 3, the shear loads of the specimens shows a level of 1180 Mpa or less in the temperature range of 240 C. to 310 C. In other words, the shear loads of the specimens in the temperature range of 240 C. to 310 C. after hot forming correspond to those of steel sheets with tensile strength of 1180 Mpa or less. There will be a slight difference based on the composition though, the specimens at 320 C., and further at 330 C., after the press forming show shear load of 1180 Mpa or less, and show the targeted tensile strength of 1500 Mpa when completely cooled to room temperature.

(31) FIG. 4 is a graph showing a change in shear load according to a blank temperature at the time of second trimming. In FIG. 4, a vertical axis represents shear load, but is replaced by a maximum tensile load of the specimen for convenience.

(32) As illustrated in FIG. 4, the shear loads of the specimens show a level of 1180 Mpa or less in the temperature range of 195 C. to 290 C. The specimens air-cooled to room temperature after trimming show the targeted tensile strength of 1500 Mpa.

(33) As can be seen from the above results, the blank after hot forming reduces the shear load to 1180 Mpa in the temperature range of 190 C. to 310 C., and further 190 C. to 330 C. Since the blank temperature drop of about 120 C. to 140 C. can be allowed during the trimming process, it is not necessary to heat the blank in the course of the process.

(34) The parts that are air-cooled or cooled in a atmospheric conditions after the first and second trimmings have the targeted tensile strength of 1500 Mpa grade, more specifically ultra-high strength of 1480 Mpa or more, and exhibit elongation of 6% or more. This result shows that the hot-stamped parts have a martensite phase close to 100% according to embodiments.

(35) Meanwhile, once the hot-stamped parts that are cooled to room temperature after press forming, even if the parts are reheated to the trimming temperature range according to the embodiment of the present invention, the shear loads of the parts are in mid to late 1400 Mpa and not reduced to the level of 1180 Mpa.

(36) According to the present invention described above, it is possible to trim the hot-stamped parts having ultra-high strength of 1500 Mpa or more at low costs. The trimming die has excellent productivity because of a short stroke time of a few seconds and is inexpensive.

(37) Further, according to the present invention, a commercially available trimming die used for cutting automobile steel sheets or parts can be used without any design modification, and expensive laser trimming can be replaced by trimming using a die.

(38) While specific embodiments of the present invention have been illustrated and described, it will be understood by those skilled in the art that changes may be made to those embodiments without departing from the spirit and scope of the invention that is defined by the following claims.